saint-gobain and glass wool
Transcription
saint-gobain and glass wool
9:35 Page 1 SAINT-GOBAIN AND GLASS WOOL THE STORY OF AN INTERNATIONAL SUCCESS From the pre-war pioneers to today’s world leader, this book traces the glass wool epic at Saint-Gobain. An industrial adventure made up of technological successes and conquests of international markets, but also of periods of doubt and corrected errors. A story of passionate men and women: engineers, salesmen and women, industrialists, logisticians… This book also shows how much every industrial chronicle necessarily comes face to face with ‘History’, as proved here by the outbreak of World Wars, crises in the Near and Middle East, or the fall of the Iron Curtain. Today again, it is the overall context of global warming which fixes new priority stakes for building insulation. SAINT-GOBAIN AND GLASS WOOL 2/09/08 THE STORY OF AN INTERNATIONAL SUCCESS DOCOUV-gb-def:Docouv2 SAINT-GOBAIN AND GLASS WOOL THE STORY OF AN INTERNATIONAL SUCCESS GB 001-013-STG-7-05 2/09/08 9:41 Page 4 SAINT-GOBAIN AND GLASS WOOL THE STORY OF AN INTERNATIONAL SUCCESS GB 001-013-STG-7-05 2/09/08 9:41 Page 6 SAINT-GOBAIN AND GLASS WOOL THE STORY OF AN INTERNATIONAL SUCCESS Saint-Gobain Insulation 18 avenue d’Alsace Les Miroirs 92096 La Défense Editing and rewriting Editorial follow-up Pascale Alix 48 rue Vivienne F-75002 Paris www.editionstextuel.com Design and implementation Éditions Textuel Graphics Caroline Pauchant Editing and rewriting Patrick Philipon GB 001-013-STG-7-05 2/09/08 9:41 Page 8 FOREWORD 11 CHAPTER 1 THE PIONEERING ERA 15 The inventors 20 Saint-Gobain observes The birth of the Pool Creating the means of production The War: a turning point Post-war: hopes and disappointments 36 41 43 47 50 CHAPTER 2 THE GOLDEN AGE OF THE ENGINEERS A technological epic ‘TEL‘ conquers the world The new license game ‘Everything is fine’ CHAPTER 3 A TIME OF TURBULENCE AND ADAPTATION Far from the needs of the market The reaction Renewed profitability The model's limit Another test CHAPTER 4 RECOVERY AND NEW CHALLENGES A world opens up Pursuit of a customer-based policy Birth of a worldwide brand The TEL pushes back its limits again New frontiers Answering a planetary problem CONCLUSION 55 58 78 86 93 99 102 111 120 129 133 139 142 148 158 160 166 170 185 GB 001-013-STG-7-05 2/09/08 9:41 Page 10 FOREWORD This book recounts an adventure lived by passionate men and women. Saint-Gobain became involved in the production of glass wool for insulation just prior to the Second World War, but the adventure really took off fifty years ago, when the Group launched a revolutionary fiber production process: the TEL. This innovation, which proved to be the basis of a great industrial success, was not invented overnight by a genius. Intuition certainly played a part, but the process, that arose from the work of teams of engineers and technicians, was developed gradually thanks to a genuine experimental approach. The pre-war pioneering adventure gave way to the golden age of the enthusiastic engineers who developed the TEL. They found themselves the industrialists ready to take the risk of exploiting the process, thus turning a technological innovation into an industrial success. By granting licenses, they federated a group of independent companies spread over the world's main industrial countries. Progressively, this group consolidated its position to form the present world leader in insulation. This technological and industrial epic was first and foremost a human adventure. The process could be created because the pioneers lent their enthusiasm and vision to its technological development. Its deployment was a success because the industrialists had patiently gathered numerous skills. Certain errors were avoided because technicians and salesmen listened to the customers. The TEL was able to conquer the world because Sodefive's 'ambassadors' and their foreign partners created a 'licensee's club' 11 GB 001-013-STG-7-05 2/09/08 9:41 Page 12 The story is far from over. Insulation has become the best answer to the current environmental crisis. Today, new teams face new challenges, including meeting the heavy world demand for insulation. May this book help them continuing the adventure, and convince them that a company is above all a community of men and women brought together around a project. Claude Imauven, Senior Vice-President of Saint-Gobain, Director of Construction Products Sector. 12 GB 014-053-STG-7-05 2/09/08 9:43 Page 14 CHAPTER 1 The inventors Saint-Gobain observes The birth of the Pool Creation of an industrial tool The War: a turning point Post-war: hopes and disappointments THE PIONEERING ERA The glass industry has lived through a technical and industrial revolution since the beginning of the XX th century. It is a period where big glass makers, groups which mastered all glass making activities, rule the industry. Bringing ideas and technologies from the United States, Eugène Gentil launches Saint-Gobain into a diversification policy. The adventure in fiberglass begins in the 1930's and rapidly reaches a considerable scale. The war brings a halt to this operation and convinces Saint-Gobain to develop its own process. Glass wool manufacture at the Lucens factory in Switzerland, around 1945. 15 GB 014-053-STG-7-05 2/09/08 9:43 Page 16 1936-1938 1926 Creation of the ‘Société d’Etudes Verrières Appliquées’, or SEVA, at Chalon-sur-Saône. The SEVA was responsible for designing and maintaining the machines in Saint-Gobain’s brand new bottle manufacturing factory, and quickly became the ‘mechanic’ for the whole group. It also supplied the spinners for glass wool. In two years, the group built a glass wool factory. It bought ‘Glasswatte’ in Germany and the ‘Soie de Verre’ at Soissons, in France, one after the other. At that moment, Isover was created. This new company then bought a factory at Rantigny to produce the ‘textile’ fiber there. 1930 1937 The agreement between Saint-Gobain and OwensCorning was definitely sealed in New York. The signatories gained access to the Gossler, Owens and Hager processes for insulation, as well as Owens and Corning for textiles. Technical improvements were immediately diffused. The « Pool » was born. The ‘Maatschappij Tot Beheer en Exploitatie van Octrooien’, a Dutch company jointly owned by Saint-Gobain and the Bicheroux family, acquired the rights to the Hager process and held the patent in Germany. This was the group’s first step in the glass fiber industry. 1932 The American glass maker Owens-Illinois invented an industrial fiber production process by blowing onto a drum. This new method surpassed anything that existed in Europe, both in terms of fiber quality and productivity. Saint-Gobain soon acquired the rights to it, and launched itself into insulation. 16 1948-1950 Creation of the ‘Société d’Etudes pour le Développement de la Fibre de Verre’, or Sodefive. This entity was to bring technical and commercial support to all of the Hager licensees. It soon filled this role for the TEL licensees, leading a real ‘club’, until it was wound up in 1997. 17 GB 014-053-STG-7-05 2/09/08 9:43 Page 18 View of the workshop. Glass wool manufacture at Lucens, in Switzerland. Fitting a glass wool pipe covering. 2/09/08 9:43 Page 20 THE INVENTORS SLAG, THE FIRST FIBROUS INDUSTRIAL INSULATION At the end of the 19 th century, the increasing prevalence of steam ships and the arrival of electricity increased the need for light, flexible insulating materials. The first real industrial glass wool production processes were soon to be created in Austria and Germany, from the fertile imaginations of their inventors. At the beginning of the twentieth century, the glass industry experienced a revolution. New manufacturing processes were appearing, for windows as well as for container glass (bottles and flasks). Production units were being automated, and knowledge of the physics and chemistry of glass was improving. Moreover, a new function was appearing in the glass companies' organization: research.The future belonged to the 'combined glass-makers', groups big enough to be present in all branches of the industry and to master all its aspects. Saint-Gobain was aware of this and embarked on a huge diversification policy. From a flat glass maker came a manufacturer of window glass, container glass and specialty glass, including the famous Securit, used in car windshields, which appeared in 1929. At the beginning of the 1930s, the Group With the industrial revolutions of the 19th century, there was an increasing number of steam-powered machines. To avoid the precious fluid cooling in the pipes, they had to be thermally insulated. A need had just been created. The first answer came from the iron and steel industry, at about the same time, on both sides of the Atlantic. Cast iron is obtained by heating a mixture of iron ore and coke, plus various additives, in a blast furnace. The molten metal, which is heavy, runs out of the bottom. Above remains a non-ferrous liquid mixture: slag. This is drained off, and stored in tanks. However, the tanks sometimes leak, and must be immediately cooled with water. During such an incident, someone noticed that fibers were formed.Various fiber production processes were thus created in the immediate vicinity of blast furnaces, all based on the same principle: blasting a strand of slag with a steam jet. No doubt because slag and steam were both readily available… The first intentional production was reported around 1840 in Wales; the first patents were filed simultaneously in Germany and the United States circa 1870. Slag wool is dense, non-inflammable, very heat resistant, and suitable for insulation of hightemperature installations, such as steam tubes. The fibers are never theless too short to be woven and do not withstand vibration very well. These limitations were to glass wool's advantage. decorative uses, glass fiber owes its success above all to its thermal insulating qualities. The industrial revolution in the mid-19 th century, with its steam driven machines, needed insulating materials. Stone wool, manufactured right next to blast furnaces, dominated at first (see p.21 “Slag, the first fibrous industrial insulation”).At the end of the century, with the development of the merchant and military fleets, there was a need for a material which was more flexible and lighter and which could withstand the vibration of the ships' engines. At the same time, blossoming industries such as electricity (wire insulation) and the cinema (screens) were looking for insulating and non-inflammable 'textiles'. All that remained was the change from the small-scale production prevalent at the time, to real industrial processes. embarked on a new adventure: fiberglass. For several years, this strange material had been increasing in popularity. “Glass wool (cotton, glass padding) looks like silk and conducts heat so badly, thanks to the air trapped between the fibers, that it produces a feeling of warmth to the touch. We make fabric for gout sufferers and rheumatics. With the waste, we make heat-insulating jackets for steam pipes. With the long strands, we weave lamp wicks, in Germany… These same strands are also sometimes used as insulators for electrical installations, or gaskets for steam joints…” This article from the 'Revue des Sciences et de leurs applications', which appeared in 1908, says it all. If we leave aside the rather anecdotal 20 CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 Cast iron flow. 21 2/09/08 9:43 Page 22 Insulation of a naval boiler with removable batts. CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 1 1. The liner 'Liberté', insulated with 35 tonnes of glass wool. 2 2. Insulation of refrigerated holds. 23 2/09/08 9:43 Page 24 This story begins in Germany, with two main players: Gossler and Hager. Oscar Gossler, a small industrialist from Hamburg, set up his company at the beginning of the 20 th century. He fitted ocean liner cabins in the shipyards, and very quickly discovered the need for insulating materials which had good mechanical qualities and were vibration-proof. From 1916, Gossler therefore decided to become involved in glass fibers, so he contacted Gédéon Von Pazsiczky, a Hungarian inventor who had already filed patents in this field and who drew his inspiration from the first mechanical glass fiber production process, invented by Dr Pollack at Stockerau, near Vienna in Austria.This machine's principle was itself derived directly from the use of the spinning wheel in 16 th century Venice (see p.27 'Spun glass: an old story') and consisted (and still consists) of drawing out molten glass strands onto a rotating drum. Von Pazsiczky arranged the drum horizontally and fed it with molten glass through a channel. The patent was issued in 1919 and industrial production of 'glass silk' began in 1922, in Hamburg. Gossler sold the fiber - he produced nearly 1,000 tons of it in 1930 - and sold licenses to use his process to various European manufacturers. Gossler production units appeared in Switzerland, Belgium, Austria, Italy, Sweden, Czechoslovakia and England. In France, the company 'La Soie de Verre', in Soissons, acquired the license in 1929.After having directly recruited Dr Pollack in Austria, Gossler improved his machine again, by adding an electric bushing. In 1930, he sold the improved process to a certain Boussois, who commercialized it in France… opposite the 'La Soie de Verre' factory! Gossler factories, generally of a modest size, covered Europe. Most of them were producing around a hundred tons of fibers per year, or even less. CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 THE GOSSLER PROCESS Distribution of the glass fibers on big tables, in very thin layers. These are stacked so that the fibers in one layer cross those of the neighbouring layers. This manual operation is called unstacking. Batts with an average density of 160 kg/m3 can be obtained, up to 100 milimeters thick. Diagram of the Gossler process, patent issued 22nd August 1922. Glass with a special composition is melted in a suitable oven, the lower part of which consists of a bushing. As the liquid glass flows through the holes in this bushing, it forms strands which are rolled around the rotating drum, ensuring continuous spinning. 24 25 GB 014-053-STG-7-05 2/09/08 9:43 Page 26 1 The first traces of glass fiber production date to 3,500 years ago on the banks of the Nile! The Egyptians heated glass in a clay bowl, plunged a metallic rod into the molten material and with a movement of the arm, drew out the glass which had stuck to the rod into a crude filament. These filaments were then rolled in joined spirals around clay shapes and the resulting item was heated in an oven. The glass melted and the glass stuck together. All that remained was to break the clay shape to obtain a hollow glass object. The Romans in turn improved on this technique. 2 Spun glass was then forgotten until its revival in the 16 th century, on a small island in the Venice lagoon: Murano. The objects decorated with glass strands which were made there quickly became famous. On the beginning, the process of producing the strands was quite exhausting. It took two workers, each with a metal rod called a 'ferret'. One of them would plunge his rod into the molten glass, take out a ball, which the other would immediately touch with his own ferret. Once the glass had adhered to the metal, the two associates would run away from each other. They thus drew out a strand whose fineness essentially depended on the strength of their legs! An ingenious, and perhaps lazy, craftsman soon imagined that the end of the strand could be stuck with wax to the rim of large wooden wheel. From then on, a worker held the end of the strand on his ferret and the other worked the wheel with 1. Vase in spun glass. 2. French workshop manufacturing beads and glass strands in the XVIIIth century. 3. Worn by the actress Georgia Cayvan, this spun glass dress was in the news during the 1893 Universal Exhibition in Chicago. It was actually an advertisement for the Libbey Glass Co., whose products however did not have much to do with fiberglass. Edward Libbey had called on an inventive young glass blower, Michael J. Owens, who obtained long fibers by heating the ends of glass rods then drawing them out on a foot-operated drum. 26 a crank. Both remained seated. The technique spread quickly to Bohemia, Thuringia and France. Venetian glass-makers set up at Nevers around 1560 and made small decorative objects in spun glass, such as 'angel hair' decoration for Christmas manger scenes. In 1665, the English physicist and naturalist, Robert Hooke described the drawing out of fine filaments of glass and predicted that it could be spun. But it was René Antoine Ferchault de Réaumur, the famous French physicist and naturalist who was to write the first full encyclopedic essay on spun glass. He presented this work to the Royal Academy of Science in 1713. Apart from a precise description of the manufacturing process, the report specified the product's properties (fineness, flexibility, tensile strength) and above all, anticipated applications, particularly weaving. Réaumur then moved on to practical work and made filaments of a few microns in diameter. Weaving tests were disappointing. CHAPTER 1 - - THE PIONEERING ERA SPUN GLASS: AN OLD STORY industrial significance… The 19 th century, on the other hand, saw two decisive advances. Louis Schwabe, a German who had settled in Manchester, invented the first bushing. This is a container whose bottom is pierced by numerous holes, and in which glass is melted and forms filaments, by flowing out through these holes. Schwabe presented his invention at the British Association conference in 1842, with little success. The French chemist Jules de Brunfaut, who was studying glass art in Venice, modified its composition to obtain more flexible filaments. He soon set up in Stockerau, near Vienna, and in 1886 founded the first 'industrial' glass spinning works there. Still using the wheels the Venetians loved so much, he obtained filaments which were three meters long and six microns in diameter. His catalog presented articles as varied as lamp shades, upholstery, neckties, wigs, hats and even wedding dresses… In 1822, the Gordon brothers filed a patent in England concerning lamp wicks made from woven glass filaments which were incombustible and therefore gave a smoke-free flame. There were also several famous uses for glass strands: the bees on the Empress Josephine's coat during her coronation (1804), a gown for Queen Victoria in 1844, Episcopal dress given in 1853 to the Archbishop of Strasbourg, who refused to wear it, etc. Famous anecdotes, but with no great 3 27 2/09/08 9:43 Page 28 As for the Hager process, considered to be the forerunner of the TEL, it began in a fairground! Legend has it that as Friedrich Rosengarth was walking around a fair in 1928, he was attracted to the small machine belonging to the cotton candy seller (see p.31 'Friedrich Rosengarth: the inspired handyman'). Everyone knows the principle, which was revealed to the passers-by by the sweet sellers at the universal exhibition in Paris, in 1900: sugar is melted at more than 120 degrees in a small rotating container provided with holes, through which, strands escape and immediately solidify when exposed to air. The seller collects the flying filaments with a stick. Rosengarth wondered whether such a 'drawing out' process could be applied to other molten materials, particularly glass.With no money, he turned to Fritz and Julius Hager, two industrialists who had a transformer factory in Bergisch Gladbach, on the outskirts of Cologne, in Germany.They agreed to finance the tests on condition that they could give their name to the process and co-sign the technical documents. Following his intuition, Rosengarth quickly developed a centrifugal fiber production process.The molten glass fell onto a grooved disc made from refractory material, turning at several thousand revolutions per minute. On 19 th November 1931, the Hager brothers, in association with Rosengarth, created the 'Glasswatte GmbH', which began production. The 'Hager' is a simple and rustic process, giving a fiber of average quality, but it was well suited to the needs of the time. Just like its competitor, the Gossler process, it spread very quickly in Europe. Glass-makers acquired licenses in Sweden, Italy, Norway, Denmark, Czechoslovakia, Belgium, Spain and Romania. In France, too, but not yet at Saint-Gobain... CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 THE HAGER PROCESS 2 1. The Hager process in Denmark in 1935. Fiber collection is carried out manually with the help of a hook. 2. The Hager process in Norway in 1935. Fiber was sold either in the form of loose wool, or a manually-made felt to make insulating batting of around 100 kg/m3. 1 28 3 3. Grooved disk on which the melted glass falls. 29 2/09/08 9:43 Page 30 CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 FRIEDRICH ROSENGARTH, THE INSPIRED HANDYMAN What an amazing career this glass worker turned engineer, then inventor had. Friedrich Rosengarth was born in 1885, and worked at the 'Schalke' glassworks in Germany during the 1920s. Here he improved his education thanks to evening classes. Shortly afterwards, he set himself up as a consultant and built glass-making factories in Switzerland, then in Russia and other Eastern European countries. He was also a tireless handyman, who was always working on a new invention in his garage. For example, he created the forerunner of the spinning brush car wash systems that can be seen in so many service stations. The machine in question was used to…brush his fox terrier automatically! The poor animal was attracted into the device by a sausage. Legend has it that Rosengarth got the inspiration for his centrifugal fiber production process from a cotton candy machine. He quickly made a prototype in his famous garage. A wooden disk and a vacuum cleaner motor was all he required: he produced Cellophane fibers. Here he had proof that his process was valid. To move on to glass, he would need considerable means, so he spoke to the local industrialists, the Hager brothers. What came next is well-known. A perfectionist, he tirelessly improved his process at Bergisch in Germany, occasionally intuitively following the same lines as the advances in the TEL, which was then being developed. For example, he had the idea of fixing a perforated band on the disk, which from that moment on strongly resembled a TEL spinner. Had he had the idea when visiting the La Villette laboratory in 1954, or did it derive from a first test which he had carried out immediately after the war? The fact remains that the new process was set up and christened Bergla, at the request of the workers. All these tests were expensive, however, and the factory was losing money. Rosengarth was politely asked to retire, but was to remain an informal technical consultant. Saint-Gobain paid him a salary until his death in 1977. 31 2/09/08 9:43 Page 32 CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 Sewn batting production line, at Lucens in Switzerland. 32 33 2/09/08 9:43 Page 34 CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 Group photo at the Gullfiber factory in Sweden, around 1937. 2/09/08 9:43 Page 36 SAINT-GOBAIN OBSERVES As early as 1930, Saint-Gobain acquired the rights to the Hager process. During the following years, it nevertheless allowed two opportunities to directly produce glass fiber slip by. Yet this industry was already well established in the United States and was developing in Europe. In 1930, the first glass fiber was produced from the Hager prototype. Alas, after having fiberized only twenty kilograms of glass, the clay disk exploded! As he was not a glass-maker, Fritz Hager was not sure whether he should pursue the adventure alone, so he turned to a professional, in this case Pierre Schrader, the representative of Saint-Gobain in Germany, who referred him to Eugène Gentil (see p.40 “Eugène Gentil: The architect of diversification”). Here he found an attentive ear. Since 1919, Saint-Gobain's 'Head of Special Missions' had regularly visited the United States, where the glass market was booming, driven by urban development and the rapid growth of the automobile industry. Eugène Gentil observed the changes in the glass industry there and brought back new man- In 1931 Gossler, which was in financial difficulties, approached Saint-Gobain to discuss the possibility of being bought out. The Group, whose management was not yet convinced of glass fiber's potential, did not follow-up on the proposition. In 1933, Saint-Gobain let a second opportunity to become directly involved in the production of glass fibers pass them by. The Maatschappij actually offered it the license for the Hager process in France. The Group refused, declaring itself “not wanting to launch a new activity,” so in 1933, the 'Société des Glaces de Boussois' became the French Hager licensee for the next fifteen years. Saint-Gobain, therefore, found itself in the quite paradoxical position of controlling, albeit indirectly, the best European glass fiber production process, ufacturing processes. He noticed that for the past few years, fiberglass had been selling in large quantities for house and but without the means of production, or even the legal right to exploit this process in France! building insulation. Convinced of its development potential in Europe, he felt that Saint-Gobain should become involved. He therefore suggested to the 'Maatschappij Tot Beheer En Yet, thanks to the innumerable Gossler and Hager licensees, the glass fiber industry was expanding in Europe. In this re- Exploitatie van Octrooien' that they buy the rights to the invention. This Dutch company, created in 1930 and based spect, three important names must be mentioned. First, the 'Vetreria Italiana Balzaretti Modigliani', a large Italian glass- in Schveningen, was jointly owned by Saint-Gobain and the Bicheroux family, a Belgian glass manufacturer. Its aim: to exploit the patents and manage the two partners' licens- making company, founded in 1850. At the beginning of the 1930s, Piero Modigliani went to the United States to study the new glass spinning techniques. In 1931, he es in the areas of glass and, from then on, glass fiber. It was therefore the Maatschappij which held the Hager patent in began production at Livorno, using the Gossler process. He perfected products such as Thermolux. In 1933, he bought one Germany, in 1930, ensured its maintenance and distributed its licenses. of the first licenses for the Hager process, then acquired the new American Owens process in 1937. From the pre-war 36 CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 OCF: THE RIVAL/PARTNER Owens-Corning Fiberglas (OCF), the big American glass fiber manufacturer, has always maintained an ambivalent relationship with Saint-Gobain. From the creation of the Pool in 1935 until 1949, the two firms were both partners and rivals! The story of this rival partner goes back to the 19 th century. In 1868, Corning Glass Works was created from the transfer of Brooklyn Flint Glass's factories to Corning, a small town in New York. Specializing in 'noble' glasses, the firm invented in particular Pyrex, at the beginning of the 1920s. Having suffered during the Great Depression, Corning then tried, without great success, to diversify into glass fibers and in 1935 called for assistance from its counterpart, Owens-Illinois Glass, which had just made a resounding entry into this field. The latter had seen the light in 1903, when Michael Joseph Owens left his employer, the New England Glass Co., to found his own company, the Owens Bottle Co. This productive inventor, who was already well known for his glass fiber production process, had just perfected an automatic bottle manufacturing machine. In 1929, Owens merged with the Illinois Glass Co. to form the Owens-Illinois Glass Co. The Depression arrived a few months later… The firm was already suffering from the effects of ten years of Prohibition - the banning of alcohol throughout the United States which had seriously affected the bottle market. It was time to find new outlets. These were to be first, glass bricks for the building industry, then fiberglass. In 1933, after two years' research, Owens Illinois patented a new glass fiber production process which was much better than anything that already existed. In 1935, Corning turned to Owens, and the two glass-makers pooled their fiber production activities. On November 1 st, 1938, the jointventure became an independent company: the Owens-Corning Fiberglas Co. was born. The Second World War would make its fortune. Glass fibers were everywhere: in the warships' insulation, in bombers, the crews' lifejackets, the cloth of certain parachutes… After the war, OCF, while developing its building insulation activity, embarked on a new specialty: woven glass fibers for reinforcing plastic materials. The bodywork of the famous Chevrolet Corvette was made of this composite material. At the end of the 1950s, at the time of the introduction of TEL at Saint-Gobain, OCF held 80 percent of the world glass fiber market for all applications! Saint-Gobain was to develop its insulation activity to the point of being able to attack OCF in the American market in 1967. This latter nevertheless continued its international development. OCF is still present in reinforcement fiber in Europe, but sold the whole of its European insulation activity at the beginning of the 21 st century. From then on, Saint-Gobain has been the undisputed world market leader. 37 2/09/08 9:43 Page 38 period onwards, Piero Modigliani was thus using the three major modern processes. Schuller is a very old German glass-making dynasty, and in 1931,Werner Schuller launched fiber production using the improved Pollack process. He founded the 'KG Wo Schuller' in 1937 and built four large factories, including one in Mulhouse, which Saint-Gobain took over after the war, before quickly closing it down. Last but not least, the Heye group, a very important Dutch-German glass-maker, and one of Saint-Gobain's largest competitors, bought a license for the Owens process in 1933 and began production in 1934, at Gerresheim. The following year, it bought out Gossler. On the other side of the Atlantic, Corning and Owens Illinois were preparing to dominate the market (see p.37 “OCF: the rival partner”). In 1931, the president of Owens contacted the inventor, James Slayter, who had just filed a patent concerning the manufacture of stone wool. He took charge of a research team, and the work advanced rapidly. In 1933, Owens Illinois Glass patented a glass spinning process using 'blowing,' where molten glass filaments are stretched by the effect of a steam jet. The process far surpassed the Hager method, as much in terms of product quality as in output. In 1935, Owens and Corning formed a joint-venture to exploit it. CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 THE 0WENS PROCESS 1 3 2 1. Diagram of the Owens process. 2. Owens manufacturing line. 3. 4. Glass wool manufacture on an Owens machine, at Rantigny, in 1943. 38 4 2/09/08 9:43 Page 40 THE BIRTH OF THE POOL EUGÈNE GENTIL, THE ARCHITECT OF DIVERSIFICATION 'Head of special missions'. When, in 1919, he obtained this unknown position in Saint-Gobain's management team, Eugène Gentil already had a long experience in the glass industry. After graduating from the 'Ecole Centrale' in 1903, he joined 'Verreries Legras' the following year and was recruited by Saint-Gobain in 1912 to direct the brand new flat glass factory in Chalon-sur-Saône. In 1913, he went to the United States for the first time, to study the American Window Glass process initially developed for Chalon. He returned there after the war, in 1919, as he considered that this process was out of date, and began negotiations with Libbey-Owens. This was the beginning of the 'special missions' where he showed what he was capable of. He went to the United States nearly every year between 1920 and 1937 to observe the new techniques, negotiate licenses and create a solid network of friends and relationships. In 1927, he even entered into a gentlemen's agreement with Corning, according to which each of them promised to 'tell everything' to the other. His A license for the Hager process for Owens against a license for the Owens process for Saint-Gobain: this principle of pooling the rights to the fiber-production processes was the origin of the 'Pool', created in New York in 1935. The partners each committed to improving glass fiber technology and applications. actual role was to detect and bring back the best processes in all the branches of the activity; those which would guarantee the Group's diversification policy. Notable 'conquests' include: Pyrex (1922), the Hartford feeder, then the Lynch hollow glass machine (1923), electrocast refractories for glass furnaces (1925),the Pittsburgh process for plate glass… and of course, the Owens process for glass fiber production. He was appointed deputy managing director then managing director of the 'Glaceries de SaintGobain' in 1934; he then had plenty of elbow room to launch the Group into fibers. The day before he retired, in 1949, he inaugurated the La Villette research centre, where the TEL process would be born. Following this, he regularly visited the Rantigny factory to follow developments in the process. He died in 1961 at the age of 81. agreement was signed in New York. From then on, the Maatschappij managed the Owens patents throughout the world, with the exception of North America (United States, Canada and Mexico), which was 'Owens' territory'. This latter received a free, North American license for the processes controlled by the Maatschappij. The royalties resulting from third party licensing would be divided equally between the two partners. It was forbidden to export glass fiber to the countries where Pool licenses already existed. The Maatschappij managed the export problems for the rest of the world. In 1939, the rights to the Gossler process, outside Germany, were integrated into the Pool. In addition, each Pool licensees would give its licensor the benefit of all the improvements it had made to the process, free of charge. The licensor would Heye already held the license. In exchange, Owens obtained the rights to the Hager process for North America. then pass on these improvements to the other licensees.This principle, known as Flow back, ensured constant technical progress in glass fiber manufacture. A long time after the On 22 nd May 1935, a first Memorandum agreement marked the official creation of what was to become the Pool. The end of the Pool, Saint-Gobain would continue this with the licensees of its own processes. signatories committed themselves to combining their innovative abilities and their patents, to sharing their experience and developing, as far as possible, glass fiber technology and applications throughout the world. For this, rights to all of their processes were exploited in a 'Pool' which was supposed to Leaving the port of New York, 1954. The Owens-Corning Fiberglas factory at Kansas City. 40 In 1933, Owens Illinois announced the finalization of its new glass fiber production process, which was more efficient than the Hager method. Its first licensee was none other than their major German rival, Heye. Eugène Gentil was, of course, informed of this. Managing director of the 'Glaceries de Saint-Gobain' since 1934, and determined to lead the Group into the production of glass fibers, he was convinced that for this he had to hold the rights to the most efficient processes. He asked the Maatschappij to begin negotiations with Owens. He left once again for the United States in 1934, for a voyage which would mould Saint-Gobain's policy relating to insulation for years to come. On his return, he held an exclusive license for the Owens process for all European countries, their colonies and dominions - except Holland, Germany and Italy, for which last until 1960. Negotiations with the Americans lasted nearly three years. Finally, on the first of November 1937, the main On 29 th December, 1938, the Maatschappij transferred all of its rights and activities in the fiberglass field to a new, nonindustrial company, the 'Algemeene Kunstvezel Maatschappij' (AKM), in which Saint-Gobain held 85 percent of the shares. With an office in Paris and another in The Hague, AKM managed the Hager, Owens and Gossler patent portfolios, for 41 CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 2/09/08 9:43 Page 42 CREATING THE MEANS OF PRODUCTION both 'insulation' and 'textile' fibers, negotiated the license agreements and coordinated the licensees. In the same year, Owens merged with Corning, to form Owens-Corning Fiberglas (OCF).These two changes of players did not modify the terms of the Pool agreement at all. From the initial agreement in 1935 onward, however, Eugène Gentil was in a position to take Saint-Gobain into the fiberglass market.All that remained was to build a factory. CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 In 1936, pushed by competition, Saint-Gobain bought 'Glaswatte' in Germany, then 'La Soie de Verre', in Soissons, France, before finally building a factory of its own in Rantigny. The Isover company was born and started production using the Owens process. Very quickly, it became one of the main European players. In 1935, Glaswatte, which used the Hager process, needed money to grow. Pierre Schrader, Saint-Gobain's representative in Germany, sent two observers to evaluate the Bergisch Gladbach factory. Hardly impressed by what they saw, they sent back a mixed report. The process seemed to them to be technically quite crude, but the centrifugal process was interesting and could be further developed. However, it was an outside factor which finally carried the day. The Heye group, a formidable rival which was already exploiting the Owens process, made an offer to acquire Hager.The reaction was immediate: Saint-Gobain took control of Glaswatte on 17 th September 1936. Jean Gaulis, an engineer who had been recruited earlier to coordinate the Group's fiber activities, joined Glaswatte's board. Saint-Gobain became a fiberglass producer. In the same year, the Group bought 'La Soie de Verre' in Soissons, France.The company, which used the Gossler process, produced insulating fiber batting for insulating boilers, particularly in the navy. It held an exclusive contract with the navy since 1932 and also worked for the prestigious 'Compagnie Transatlantique', insulating the boilers of the liners 'Normandie', 'Champlain' and 'Ile de France'. It also produced a felt made from longer fibers, used as a separator between the positive and negative plates of electric batteries. Advertising in the newsletter 'L'Équipe' at the beginning of the 1950s. 42 Lacking the means to invest, the company was in difficulty, 43 GB 014-053-STG-7-05 2/09/08 9:43 Page 44 as compared with its competitor, Boussois, which was preparing to launch the more efficient Hager process. Roger Lacharme, the managing director of 'La Soie de Verre', received Saint-Gobain's proposal as a gift from on high.“One day in 1936, a visitor named Gaulis introduced himself. He had hardly entered when he revealed his intentions: he had been sent by Saint-Gobain's managing director, Mister Gentil, to negotiate the purchase of 'La Soie de Verre'. The reason was simple. Mister Gentil […] had just bought the Owens process, in America, […] and was wondering how to use it in the most practical way. He leafed through the directory and when he discovered 'La Soie de Verre', decided to get in touch with the company,” he said later.The reality was, no doubt, slightly less miraculous. In fact Henri Crochet, La Soie de Verre's director, shares to Saint-Gobain. On the eve of the Second World War, the Group had a company, Isover, access to all the known fiber manufacturing processes, two production sites in France, plus those of the companies they controlled in Germany, Italy and Belgium, marketing services and a catalogue of products. Saint-Gobain was then producing around a third of the 15 to 20,000 tones of fiberglass manufactured each year in Europe. For its part, the United States was producing 20,000 to 25,000 tones. Despite its initial hesitations, in a few years Saint-Gobain had become a major player in the fiberglass field. also held an important position in the glass branch of Saint-Gobain, so the Group already knew about the company. The purchase was concluded at the beginning of 1937 and a new company was immediately formed: Isover had just been created, with an investment of a million and a half francs. Jean Gaulis was its executive director, Roger Lacharme the sales director and Lucien Deschamps the technical director.At the end of 1937, the first Owens oven started production, next to the twelve existing Gossler ovens. It alone produced 700 tons of fiber per year, against 350 tons for all the others put together. “You'll see, Lacharme, one day glass fiber will have a higher turnover than flat glass”, Eugène Gentil remarked.A prophecy which would come true…in the 1970s. Isover was a producer of fiberglass for insulation, but was also trying to be present in the 'textile' fiber market, which was however technically different. Saint-Gobain's diversification adventure with chemical textile fibers was coming to an abrupt end. THE SILIONNE PROCESS The 'Société des Textiles Nouveaux' (STN), in which the chemical branch of the Group had a shareholding, was in fact experiencing difficulties. In 1937, this company closed and the Rantigny site was dedicated to the textile fiberglass activity. Three engineers from Owens Illinois arrived in September to install the Silionne and Veranne bushings - two manufacturing processes for producing long glass fibers. The changes continued with the creation of Isoverbel (Belgium) in association with Saint-Roch, and the acquisition of Modigliani (Italy) in 1938. Piero Modigliani, who was obliged to move to the United States for political reasons, sold his Rantigny factory, twisting, winding, folding. Rantigny factory, textile weaving. 44 GB 014-053-STG-7-05 2/09/08 9:43 Page 46 CHAPTER 1 - - THE PIONEERING ERA THE WAR: A TURNING POINT Activity continued during the war, but Isover, deprived of contact with its licensor, had to manage the development of the processes alone. At the same time, the American authorities started legal proceedings against OCF. The future of the Pool was threatened. THE FIRST INSULATION CONFERENCE With the exception of a brief interruption during the German invasion of France in 1940, the war did not stop Saint-Gobain's production of fiberglass; on the contrary, it was even to become a major turning point. At the end of May 1940, the advance of the German troops forced Isover to evacuate the Rantigny factory. The personnel withdrew to Cognac, but returned to the Oise region in August to launch production of long fibers. In the same year, bombs intended for the nearby railway station partially destroyed the Soissons factory. Fortunately, the Owens line and a few of the Gossler lines were spared.They were moved to Rantigny, where all Saint-Gobain's fiberglass production was now concentrated. Even though it had been reorganized and was slightly smaller, the factory was The very first world insulation conference was held in Paris, in May 1939. Eugène Gentil, the managing director of the 'Glaceries de Saint-Gobain', felt there was a need to create an international insulation community, to reinforce the relationship between the Pool agreement signatories and the licensees. He therefore thought of organizing an annual conference. For this first of a long series, the delegates met in a restaurant on the Champs Elysées in Paris. On the menu: technical problems; commercial, legal and health aspects of fiberglass. German, American, Belgian, British, Danish, Spanish, French Italian, Dutch, Norwegian and Swedish representatives were present. porary management of the Company, decided to launch their own research into fiberglass production. The war years, and with no apparent major damage, the promising landscape of the end of the 1930s had been radically changed. still functional. The real impact of the war can be found on another level: relationships with its American partner, OCF, completely changed. For fear of incurring the wrath of the US anti-trust authorities, OCF broke the export restrictions mentioned in the Pool agreement. More importantly, by the simple fact that the war was going on, the relationship between OCF's engineers and the European users of the Owens, Silionne and Veranne processes was interrupted. Eugène Gentil himself was blocked in New York. Saint-Gobain could not, therefore, International fiberglass conference, at Wiesbaden in Germany, 1954. Around 25 countries took part. 46 benefit from the latest technical developments. However, this hiatus was to have positive repercussions. In May 1941, Tony Perrin and André Ayçoberry, who had taken on the tem- Rantigny factory. 47 2/09/08 9:43 Page 48 CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 Model made by 'les Glaces de Boussois' for a glass wool advertisement. Three drawings taken from the brochure 'Tel qu'en un écrin'. 48 49 2/09/08 9:43 Page 50 POST WAR: HOPES AND DISAPPOINTMENTS Under pressure from the American authorities, the Pool was dissolved in 1949. On the ground, however, everything was going well in a France which was being completely rebuilt… until the arrival of a formidable competitor. Isover's only solution: create a better fiberglass production process. After the Liberation, the relationship with OCF did not return to its previous basis. Boosted by the enormous orders from the army, the American glass-maker had changed scale, and this could be felt in its attitude towards its partner. What was more, the US Department of Justice, had launched an enquiry concerning OCF. In June 1949, OCF, Owens Illinois and Corning put an end to the proceedings by entering into an agreement with the authorities. According to this consent decree, the patents issued prior to 1938 were to be accessible to everyone, free of charge. In addition, OCF promised to sell licenses for the patents issued prior to 1938 to anyone, at a reasonable price, to put an end to all its agreements with foreign companies and to conclude new, non-restrictive agreements with them. Moreover, OCF was to become totally independent of its two 'parents', Owens Illinois and Corning. In short, the 1937 Pool agreements were null and void. Everything would have to be re-negotiated.This was done on February 6th, 1951, the date the new New York agreements were signed, marking the official end of the Pool. Sensing this outcome, and seeing the date its patents would fall into the public domain drawing closer, the Saint-Gobain management was thinking about AKM's mission. How could the royalties be justified when the patents were null and Insulating the cars which transported the British royal family during its visit to Australia in the 1950s. 50 void, and how could it differentiate itself from OCF? The only solution was to offer technical and commercial assistance CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 to the licensees, and thus contribute more actively to the overall development of fiberglass technology and applications.This would also be a good way to win the loyalty of these industrialists.As AKM did not have the means, SaintGobain decided, on April 8th, 1948, to create Sodefive, (Société d'Etude pour le Développement de la Fibre de Verre). Its aim, as defined in its articles of incorporation was:“the study and implementation of technical and commercial assistance which can be provided to manufacturers and users of glass fibers, with the aim of allowing them to improve and develop their industry and generally, all research and operations directly or indirectly connected with the above aim”. In the field, the atmosphere was quite optimistic. France was being rebuilt and modernized.There were opportunities to be seized for building insulation, and precisely at this moment, a new product appeared: a glass fiber mat impregnated with a binding agent, which was much easier to handle than the former pure fiber batting. The first product of this kind was intended for refrigerator insulation; this soon gave birth to the 'Imprégné au Brai à Rantigny', the famous IBR which revolutionized building insulation. Isover was convinced of its product's quality and in 1948 asked for an expert opinion from the research laboratory of the 'Conservatoire National des Arts et Métiers'. In April 1949, the CNAM gave its verdict: “It was noted that after being submitted to 37 hours of vibration, the glass wool mat called feutre Isover IBR, showed no settling, the glass fibers were not broken and no dust was detected at the bottom of the partition”. In short, it was an undeniable technical success. However, it also had to be accepted by the customers. Roger Lacharme went to the United States in 1947 and discovered new marketing methods.“Before undertaking this voyage, I was an intuitive trader. On the other side of the Atlantic, I discovered rational methods for organizing an advertising campaign, a promotional activity or conquering a market,” he declared. He therefore developed a modern sales network and launched the in-house magazine, 'L'Équipe', which symbolized the activity's revival. The architects finally listened and the contracts started to arrive. Le Corbusier called on Isover to insulate the famous 'Cité Radieuse' in Marseille, which was inaugurated in 1952. Covers of 'L'Équipe', the French sales department's newsletter. 51 2/09/08 9:43 Page 52 However, a formidable competitor appeared on the horizon. In 1948, a joint subsidiary of Pont-à-Mousson and the American Johns Manville set up a stone wool factory in Saint-Etiennedu-Rouvray, in Normandy. At the beginning of the 1950s, this new insulation product appeared on the French market under the name Roclaine. Its producers made no secret of the fact that they wanted to 'suffocate' glass fiber.To this end, they gave significant discounts to their clients, which meant that stone wool was 25 percent less expensive than glass wool. In addition, as it could stand higher temperatures, it was better suited to certain industrial uses. Finally, its salesmen never failed to point out that their product 'did not prick your fingers', which was the case with glass fibers produced using the Owens process. “It was close. There was a risk that the commercial efforts undertaken over the years would be wiped out, and these rivals spread the rumor that the Rantigny factory would be forced to close its doors in two years,” Roger Lacharme recalls. Saint-Gobain no longer had a choice. It had to perfect a new glass fiber production process which gave better results than the Owens process. Roger Lacharme literally laid siege to the research center, now set up in Paris, on the boulevard de la Villette, and arranged for the fiber production research, started during the war, to change pace and scale. The era of the engineers was beginning. 52 CHAPTER 1 - - THE PIONEERING ERA GB 014-053-STG-7-05 SODEFIVE SERVES THE LICENSEES The Société d'Etude pour le Développement de la Fibre de Verre (Sodefive), which was created to offer a service to licensees, was gradually to become an international development tool for Saint-Gobain. The story began in 1948. The brand new subsidiary's explicit mission was to provide licensees with technical and commercial assistance. By doing this, it was supposed to be contributing to the development of the fiberglass industry throughout the world… to the Group's greater profit, even if only in terms of royalties. At the beginning, the company did not provide technical assistance per se but was in charge of the coordination. The CRIR engineers looked after this in the field. Sodefive in fact took on the role of interface, organization… and promotion. “It was at the end of the fifties that a team spirit appeared between the licensees. The personality of Marc Tolédano, Claude Caron and Claude Jumentier contributed to create a type of relationship based on trust and friendship between those licensees. They knew they could count on Sodefive” explained Dominique Elineau, the last managing director of Sodefive. The word was out: through its way of operating, the company had created a real 'licensees' club'. This state of mind was put into concrete form through meetings of technical or sales managers, international conferences which brought together 'people who knew and appreciated each other', and even, at the beginning of the 1980s, a magazine. Later on, Sodefive developed a new activity meant for the licensees: sales and marketing assistance. “We understood that owning and mastering a process which was technically superior to the competition was not enough,” underlined Dominique Elineau. A small cell was therefore created to study the markets and the changes in their needs. Its aim was also to circulate information related to the new products, to assist the licensees in their industrial investments, to help them in comparing the products of the competitors… The fall of the Berlin Wall finally opened a new era. The general management of the Insulation branch gave Sodefive a new mission, different from its primary vocation. Capitalizing on its skills, knowledge of the markets and players, it participated to the establishment of the branch in Eastern Europe then in China. In 1997, only five licensees remained, and there was no significant and immediate perspective of entering into any new license agreements. A dedicated structure was not justified. After half a century of existence, Sodefive was wound up and its activity reintegrated into the Group's Insulation branch. 53 GB 054-097-STG-7-05 2/09/08 9:44 Page 54 CHAPTER 2 A technological epic “TEL” conquers the world The new license system “Everything's fine” THE GOLDEN AGE OF THE ENGINEERS After the war, the cards were re-dealt. Cut off from its technology providers during the conflict, the Saint-Gobain Group developed its own means of production. The research department got to work and soon the TEL was born - a new process based on an original fiberizing principle. It was a technical and commercial success: licenses were granted throughout the world. A good period was opening up for Isover. 55 GB 054-097-STG-7-05 2/09/08 9:44 Page 56 1945-1946 1960 Pierre Heymes, a young test engineer, filed two major patents, one after the other, dealing with the fiber production processes. The second, in particular, described the association of centrifugal force and the action of a jet of hot gas to draw out the glass. This was the first statement of the famous SaintGobain fiber production principle. 1950 Beginning of the construction of the Industrial Research Center at Rantigny, better known by the acronym CRIR. It was a genuine research and development center and associated three fundamental laboratories (chemistry, physics and applications) with industrial scale pilot lines. Research had at last found its place. 1967 After the disappointing tests of the LET machine, which was too complicated, the decision was taken to ‘turn it over’. Moreover, Heymes had already put this idea forward a few years previously. The very first TEL machine, with the spinner at the bottom, appeared at the Billancourt center before beginning a test campaign at Rantigny. 1957 This was it! After seven years’ perfecting, the TEL – actually the Supertel, as the researchers called it – began its industrial career at Rantigny, where it superseded the Owens process. Gabriel Aufaure, the factory director, took the risk. A wager which was quickly won, as the TEL was superior to all the other processes and was soon to conquer the world. 56 Saint-Gobain and CertainTeed, an American construction material producer, created CSG, a joint venture intended to manufacture and sell glass wool in the United States. The first lines, set up in the factories in Pennsylvania, Kansas and New Jersey, started up one year later. The TEL had come to compete with Owens Corning on its own ground! 1973-1979 The Yom Kippur war (1973) then the Iranian revolution (1979) provoked two oil crises, marking the end of the first thirty post-war years. It was crisis time and energy had become expensive; insulation suddenly had the wind in its sails. In an economic context which was difficult, Isover still had a prosperous decade. 57 2/09/08 9:44 Page 58 A TECHNOLOGICAL EPIC THE TEL PROCESS CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 For the researchers, Hager-type spinning was the most logical way of producing glass fibers. However, they added extra drawing by hot gases, thus creating an original fiber production principle. The TEL, which applies this principle, had a difficult birth after several changes…and an about-face. The beginning After the flight of the French civilian population during the German invasion, fiberglass production began again at Rantigny. However, at the beginning of 1941, it became clear that the severing of relationships with the OCF engineers was handicapping Saint-Gobain.The company was no longer benefiting from the latest technological advances.The same was true for Gossler. Saint-Gobain therefore decided to develop its processes itself. Tony Perrin, who had taken on the position of managing director of the 'Glaceries', in the absence of Eugène Gentil (kept in New York), and his assistant, André Ayçoberry, turned to the 'Laboratoire d'Etudes Thermiques', or LET.This Billancourt-based research and development unit was dedicated essentially to flat glass processes. Its director, Ivan Peyches, had just In a few months, Ivan Peyches had made up his mind: the Hager centrifugal process was the most logical of the three from a physical point of view. In addition, this simple process, which could returned from captivity. On his return, André Ayçoberry asked him to study all the existing processes to identify any possible improvements. In his sights were the Gossler, a slightly out of use recycled glass, corresponded well to this period of shortages. It nevertheless had one major disadvantage: Boussois held the license! So an alternative had to be found. From that date fiber production process using a wheel, the Hager, based on centrifuging, and the Owens method of blowing with steam, moment on, work began on what was to become the LET machine, after the initials of the laboratory. It lasted until 1951. inherited from slag fiber. Ivan Peyches. 58 59 2/09/08 9:44 Page 60 The LET machine was developed with various improvements on the Hager process.The most important concerned the grooved disk, which was quickly replaced by a 'spinner' whose edge was pierced with holes.What the researchers called the 'tournette' or 'whirler' among themselves looked more like a flying saucer than a spinner, and its flying qualities as it shot across the workshop during certain adjustment incidents reinforced the comparison… The first tests of the machine, built by the SEVA (see 'The SEVA: a mechanic “spins” a tale), took place in the industrial testing department at Saint-Romain-le-Puy, in 1942. It was a failure, and they had to wait until 1944 before 16 micron diameter fibers were obtained. The spinner was developed, receiving first two, then three rows of holes. New tests were started at Rantigny, with another feed method.The spinner received soft glass 'marbles', injected from below by compressed air. Once again, the tests were disappointing. Mister Herbert, who was director of Rantigny at the time, was severe.“It will never work”, he maintained.Among the grounds for complaint: excessively high cost, a fragile machine, short-lived spinners and products of a dubious quality, because of the soft glass. Not to mention the problems with the fiber collection, due to the strange arrangement of the machine, which was inherited from the Hager process and had the spinner on top.This was the end of the LET machine. CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 ACCURACY OF VOCABULARY: WHAT DO WE CALL TEL? “In the technical context of TEL, I can not find a unique element which distinguishes the process from its competitors.The entire process is the juxtaposition of a myriad of details. Taken one by one, they may appear minor, but through their synthesis into a homogenous whole, they form a technology which is perfectly competitive in the glass fiber insulation industry.”This is how it was put by René Goutte, an engineer who supervised the setting up of the Saint-Gobain insulation activity in the United States. But what exactly did he call 'the TEL'? Precise vocabulary is essential. In the beginning, there was the LET machine, which was outlined during the war and took the initials of the 'Laboratoire d'Etudes Thermiques'. The idea of turning the spinner over allowed a new centrifugal fiber producing machine to be developed: the LET machine was turned into TEL by a physical, as well as an acronymic, reversal.After new developments the TEL became Supertel, before being industrialised in 1957.What René Goutte, and everyone else with him called 'the TEL' was in fact the Supertel, then its successive developments. It became the generic name for the Saint-Gobain fiber production principle. 1 1. LET spinner. 2. Prototype of the LET machine. 60 2 61 2/09/08 9:44 Page 62 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 Spinners with different diameters. GB 054-097-STG-7-05 2/09/08 9:44 Page 64 At Saint-Gobain, glass fibers are made in spinners. Originally called 'tournettes' or 'whirlers', these spinners must withstand rotation speeds of several thousands of revolutions per minute without deforming, and receive molten glass at over a thousand degrees Celsius. These fragile parts have become the speciality of the 'Société d'Etudes Verrières Appliqués' (SEVA). It was created in 1926 under the name "Société d'Etudes et d'Exploitations Verrières" (SEEV) by Saint-Gobain to look after the design and mechanical maintenance of the brand new bottle manufacturing factory in Chalon-surSaône. In fact the company was soon in demand from the whole of the group for all the mechanical parts or units of its production installations, and therefore realised the prototypes and was responsible for manufacturing the various fiber production machines. The spinners are a special case, as not only does SEVA manufacture them, it also develops them - and at the same time adapts its production methods.These parts are a deciding factor in the quality of the fiber, to such a point that SEVA is still the only supplier for all the Group's factories and subsidiaries. The first spinners were manufactured in 1956-57 for the start up of TEL and Supertel.They were 200 mm in diameter and realised on a hydraulic press in Nicral sheet.The holes were drilled 'by hand' with drills of less than a millimetre in diameter.About twenty drillers worked in an isolated workshop, so that they could hear the drill 'sing' - to determine the state of the drill bit by ear. But the technique developed very quickly: the diameter and material of the spinners, as well as the method of production and drilling. Pressed sheet is not very strong and was quickly replaced by moulded parts. The La Villette laboratory chose an American alloy (iron, chromium, nickel and tungsten), which was to be used until 1978. It was melted in an electric furnace with no contact with the air and poured into hard sand moulds.The parts were then finished on the lathe. In the mid-1990s SEVA changed to ceramic moulds.A replica of the spinner was realised in polystyrene, then this model was covered with successive coats of ceramic, which were solidified in the furnace. From then on, most of the spinners were manufactured according to this process. Drilling by hand was superseded by an electro-erosion method, where the metal was attacked by intense, repeated electric arcs. CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS SEVA, A MECHANIC “SPINS” A TALE destined for drilling the combustion chambers of aircraft jet engines, was having trouble perfecting a system suited to spinners.A single machine of this type would however replace all the electro-erosion machines from 1998! Meanwhile, the diameter of the spinners was increased successively to 300 millimetres (1967), then 400 (1978), 600 (1980) and even 800 millimetres from 1983.The alloy was also developed, and was the subject of cooperation with CNAM and the University of Nancy. In 1985, SEVA and CRIR (Industrial Research Center of Rantigny) again strengthened their links and introduced regular technical exchanges, thus formalising a cooperation which had been initiated three decades earlier. Drilling workshop at the SEVA in the 1960s. After having unsuccessfully tested a commercial machine, SEVA designed and created its own tools and put them into service in 1964.There were up to eighty electro-erosion machines in 1997, but as the system had nevertheless reached its limits, SEVA changed to electron beam drilling. It had been studying this process for more than twenty-five years, but the only manufacturer of this type of machine, which at that time was Machining workshop at the SEVA in 1970. 64 65 2/09/08 9:44 Page 66 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 1 1. Piles of spinners in the SEVA's machining workshop. 2. Fitting a TEL spinner. 2 3 3. Stock of spinners at different stages of manufacture. 67 2/09/08 9:44 Page 68 PIERRE HEYMES, THE FATHER OF THE SAINT-GOBAIN FIBER PRODUCTION PRINCIPLE Birth of a process “The best of our test engineers”, was how Pierre Heymes was described at Saint-Gobain.After leaving the 'Arts et Metiers' school in 1942, the young graduate immediately received a grant from the CNRS to work in the 'Laboratoire d'Études Thermiques' at Saint-Gobain, which was then directed by Ivan Peyches.The latter, who at the time was developing a complete fiber production theory, needed a study of fluid dynamics. He asked Heymes to embark on a thesis, supervised by professor Ribaud, president of the Saint-Gobain research committee. On this occasion, Heymes understood that the drawing force a fluid can exert on a thin strand - in this case a strand of molten glass - depends on both its speed and its temperature. He was hired by Peyches in 1943, and began to develop what would become the Saint-Gobain fiber production principle. In 1944, he visited an exhibition of salvaged German V2s behind Notre-Dame Cathedral in Paris, and understood how to eject the essential hot gases at very high speed. From then on, everything moved very quickly.A first patent was filed in 1945.The second, which associated drawing by the combustion gases Diagram of the principle of the V2 motor. 68 with the action of centrifugal force, followed in 1946.The Saint-Gobain fiber production principle was registered, but it was several years before suitable burners were available. From the beginning of 1946, Heymes took over management of the fiber production tests, and divided his time between the laboratory in the 'Place de la Nation' and Rantigny. In Paris, he developed the Superfine process, whose burners were the forerunners of those in the Supertel.At Rantigny, he dedicated himself to the LET machine. Note that, ever the visionary, he had at that time suggested turning it over, thus designing the TEL without knowing… He supervised the development of the process until 1951.At that time, Saint-Gobain had a difficult problem to solve: the simultaneous polishing of both sides of a glass strip. SaintGobain's management gave great importance to this question, and Ivan Peyches did not hesitate for a second. The only person who could find the answer was Pierre Heymes, who therefore abandoned the fiber production process for which he had laid the foundations. The LET machine doesn't work? Let's turn it upside down! “We are designing a new approach to the LET centrifuging machine, called TEL, in which all the components are turned upside down and the spinner is on the lower part,” wrote Ivan Peyches, in his introduction to the report on the disappointing tests at Rantigny. Giving Caesar his due moreover, he pointed out that such an arrangement had been suggested in 1942, by the manager of the factory in which the first tests of the machine had been carried out, then reformulated in 1946 by Pierre Heymes, who at the time was taking over the management of fiber production tests. The very first upside-down machine dates from 1950.The glass arrived at the top through the aperture in the unit's axle.The fibers were blown downwards by an air current and fell onto a collect- Sodefive was also in favour of an acceleration of the tests. Moreover, it was its technical director, Lucien Deschamps, who had the idea of getting someone to take a fresh look at the TEL. He suggested Mister Corvillain, a graduate of the 'Ecole des Mines' and at the time, manager of the 'Glacerie de Chantereine', who took over the management of the tests in September.Thanks to numerous minor modifications and adjustments, the tests were finally satisfactory.“The future of the TEL machine can be envisaged with optimism. It is absolutely essential that industrial operation for several months on an ad hoc furnace confirms the results obtained,” Corvillain wrote. In short, the TEL was viable and tests had to be continued at full-scale. The industrial tests on the TEL began under the management of Marcel Lévecque, from the basic research laboratory at the La Villette center.They took place from 1953 to 1955 in the factory at Lucens, in Switzerland, where one of the three furnaces was given over to them. The work concerned the machine, which was still a bit fragile, the drilling of the spinners, improvement of the fibers and increasing output. Lévecque multiplied the rows of holes in the spinner, to 35. The last test campaign, carried out at Rantigny from 1954 to 1956, concerned the burner, and finally defined the composition of the glass suitable for the ing conveyor belt. Just one axle, no vibrations; the machine was both simple and better-designed than its predecessor.The first tests were encouraging; the machine worked and the fibers discharged easily. On the other hand, the burner had to be improved. A test and modification campaign began in 1951 at process.The machine now had a spinner with 27,000 holes and produced three tons of ten micron diameter fibers per day. It was finally ready for industrialization. Rantigny.Work was carried out on the composition of the glass, the external burner, and above all, the spinner. Form, material, number of holes; everything was developed. However, there first products were sold to Frigidaire, a subsidiary of General Motors. Yet, on 17th July 1956, the machines were stopped. This was the end of the TEL! Meanwhile, the Supertel had remained one problem: if the melting temperature was too low, demonstrated its superiority during a comparative test. In June 1956, two TEL machines began operating at Rantigny.The the glass devitrified; if it was too high, the spinner suffered. In short, the tests took a long time and did not give any convincing results, despite the new machine's obvious qualities. In the autumn of 1952, Roger Lacharme, spurred on by the competition from Roclaine, urged the management to launch the new fiber production process.The Owens type fiber was too prickly, too heavy and was having trouble competing with stone wool. 69 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 2/09/08 9:44 Page 70 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 THE PHYSICS LABORATORY: A SCIENTIFIC TOOL “I would like […] to emphasise again that on a research level, we need to carry out basic work which is too often disparaged…” is what Marcel Lévecque, head of the Technical Research and Development Department, had to say at the tenth anniversary of the physics laboratory, in 1971. The sound levels recorded by the microphones are transcribed directly in decibels on the recorder. As the 'theoretical branch' of the CRIR, the laboratory began its activities in 1961 under the aegis of Daniel Fournier, assisted by the former manager of the Rantigny factory inspection laboratory, Claude Jumentier.The unit included three sections - thermal, mechanical and acoustic - corresponding to the three basic properties expected of insulating materials. Its mission was also threefold. Firstly, to look at all aspects of the question - to make an inventory and describe the performances of all the materials intended for acoustic and thermal uses.To this day, the laboratory still keeps a characteristics file which has few equivalents in the world. Next, to carry out basic research into the properties of the materials. This forms the major part of the work and consists of describing and modelling the phenomena taking place in the fibrous environments, and understanding how the structure of these materials influences their performance. Finally, none of all this would be possible without the third line of research: the perfecting of precise and reliable methods of measuring these properties and phenomena.What is known as 'metrology' is essential to knowing about the different materials, as well as comparing their performances in an unquestionable manner - a trump card when having to negotiate with regulatory authorities throughout the world and develop texts which often put fiberglass at a disadvantage through simple ignorance of its properties. Isopermeability curves, thermal conductivity measuring equipment, study of convection and thermomigration in light, fibrous insulation, effect of boron.Although the laymen have difficulty imagining what it is all about, it is not difficult to guess that the laboratory works at a very high level, and often in cooperation with public research institutions and universities. From 23rd to 25th November 1971, a seminar was organised at Ermenonville.This was the opportunity to draw up a balance sheet of ten years' activity. Claude Jumentier, a former 'salesman' turned researcher, explained how a basic laboratory, which may appear to be a long way from reality, can help those who sell fiberglass in a very concrete way.“I remember that difficulties came from three directions at the same time: the customers, the competition and the regulations for the use of insulating materials.The problem concerning the customers came from the lack of adequate and reliable information. In the case of the competition, the problem was to find an appropriate and irrefutable argument. Finally by 'regulation', I mean all the rules or specifications decreed by the profession's institutes and authorities, which led to restrictions in the use of insulating materials.” The laboratory has answered all these expectations.The distance travelled can be measured since the fifties, the period when the quality of a fiber was measured… by touch! The operator measures a loudspeaker's characteristics with a sound level meter. 70 71 2/09/08 9:44 Page 72 MARCEL LÉVECQUE, THE 'BOSS' And the TEL becomes Super The name Supertel dates very precisely from 13 October 1952, at La Villette, during a meeting about the conclusions of the Corvillain report. In addition to the launch of the industrial tests on the TEL, it was decided to dedicate research effort to a new process. The idea was simple: to apply the fiber production principle defined in 1945 - 46 by Pierre Heymes to the TEL machine.This programme, called Supertel, would be carried out at La Villette and at Rantigny, under the supervision of Marcel Lévecque. th The first step consisted of drawing out the glass strands at very high speed under the action of combustion gas. Very quickly, Peyches imagined associating this with the centrifugal fiber production that he saw working during the TEL tests, for which he had taken responsibility. A patent from 1946 describes what has become the Saint-Gobain fiberizing principle: the association of the centrifugal force and 'over-drawing' by hot gases from an internal combustion burner. Finalization of the Supertel began in April 1953, with the construction of a production line at La Villette and installation of test lines at Rantigny, and lasted four years. Four years during which a metallic alloy for the spinner had to be defined which would withstand the heat, an internal combustion burner had to be created, capable of delivering 'hard' flames, that is, sufficiently rapid and coherent to draw out the fibers, stop the composition of the glass and create a glass heating system by induction. On 19th October 1953, exactly a year after the initial meeting, the first Supertel fiber was produced at La Villette. It measured two microns in diameter, but contained too many impurities.The burner was improved until April 1954, when the tests on the other constituent parts of the process began at Rantigny. In 1956, the Supertel had definitively proved its superiority over the TEL, which was stopped. In October 1950, a young man of 28 entered the La Villette basic research laboratory.A graduate of the 'Conservatoire National des Arts et Métiers', he had just spent three years at the 'Office National d'Etudes et de Recherches Aérospatiales' (Onera) where he had worked on ceramics, metallic alloys and combustion. As he had also studied thermodynamics and the chemistry of glass, he had a mastery of all the aspects of fiber production, at least in theory. This was no doubt the reason why, on 13th October 1952, Ivan Peyches entrusted him with the management of the TEL team, as successor to Pierre Heymes.“There was an excellent thermo-dynamics specialist in the basic research laboratory, called Marcel Lévecque… I decided to entrust him with the TEL process. In a few years, Lévecque was to take it through all the stages of development and turn it into a real industrial process”, Ivan Peyches later remembered. And in fact the person that his associates unanimously called 'the boss', took an interest in all aspects of the machine, had lots of ideas, and completely overwhelmed his work associates. Exhausting, CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 sometimes, but results were achieved. The brilliant theorist that he could have remained showed what he was capable of as a pragmatic and ingenious research worker. It was perhaps this aspect which gained him the respect and unfailing friendship of Gabriel Aufaure, the director of the Rantigny factory.The two associates would be in on the creation of the CRIR in 1960. Lévecque then became director of the Technical Research and Development Department of the glass Division, before becoming technical director of the glass fiber branch, then taking on responsibility for CertainTeed in the United States. CertainTeed's new research center, which was inaugurated on 26th June 1979, was christened the Lévecque technical center. 1 2 1. Diagrams of the Supertel. 2. Heating the spinners by induction. 72 73 GB 054-097-STG-7-05 2/09/08 9:44 Page 74 The molten glass falls into the spinner, which turns on a vertical axis. This spinner's exterior, in heat-resistant steel, is drilled with a large number of holes. The glass is pushed through the holes by centrifugation and is divided into numerous strands. A powerful jet of hot gas then draws out the fibers. 74 75 2/09/08 9:44 Page 76 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 A PLACE FOR RESEARCH There was no longer a place for empiricism or 'do-it-yourself solutions'. Successive research managers in the Insulation activity introduced scientific processes and launched basic research programmes. They needed laboratories and a real test center, and in 1960, this happened: the CRIR was created at Rantigny. From the beginning of the 20th century, the glass industry had become aware of the importance of research, and Saint-Gobain was no exception. However, it was during the war years that Ivan Peyches moved from the obligatory empiricism to assert the importance of scientific methods, combining the search for theoretical knowledge with controlled experimentation.A new era had just begun. Questions which were apparently as trivial as 'what determines the recovery of thickness of a glass wool mat which has been compressed during transport?' would lead to high level theoretical work, involving mathematical modelling, and would be the subject of joint theses and studies with universities or other academic institutions. In May 1956, Marcel Lévecque even wrote a quite visionary note to Sodefive, the patents department - and to Peyches: 'Product analysis has been neglected in Europe and must be more systematic. Perhaps in a few years we will see theorists looking into the architecture of fiberglass, fiber 'topologists' applying their difficult mathematics to allow us to discover the true possibilities of our products'. It was obvious that improving the properties of an insulator or discussing with the regulating authorities requires solid theoretical knowledge. Immediately after the war, nobody knew much about the properties of fiberglass or its behaviour over time. Beginning a real scientific programme required manpower, means and installations.The first work on the LET machine began at the 'Laboratoire d'Etudes Thermiques' at Billancourt, in 1941. On the night of 3rd March 1942, a bomb aimed at the nearby Renault factories destroyed the laboratory. This was then transferred to the 'Rue Fabre d'Eglantine' in Paris, close to the 'Place de la Nation', where tests on ultra-fine fiber, which required very little glass, began in the summer.The test material was then transferred to the 'Boulevard de la Villette', where the first fiber research center was built in 1949.All that remained was to solve the problem of access to molten glass, essential for the tests which took place in various factories in the Group, according to the glass strands available. In April 1953, tests of the Supertel began; the decision was therefore taken to build a complete fiber production unit. It had its own melting cell, reception conveyor belt and sizing device. had shown them that to test a process on an industrial scale, they needed their own pilot line.Added to these preoccupations was a problem which was anecdotic, but not insignificant: the burner tests generated whistling which was so intense that the Boulevard de la Villette neighbourhood had begun to tire of it… In short, it was time to think about building a real, large-scale test center.This would be the CRIR: 'Centre de Recherches Industrielles de Rantigny'. “We needed to work directly and not in the abstraction of a laboratory. So I asked for a research center to be built next to the factory. In that way, everyone would be happy and could work in their own area.” Lévecque remembered.Work began quickly with the construction of the pilot workshop, to which were joined three basic laboratories dedicated respectively to chemistry, physics and applications. As a consequence, the organisation of research within the glass Division was revised: the Technical Research and Development Department was created in 1960 and placed under Marcel Lévecque's responsibility. Research had finally found its place. This was not yet enough. In January 1960, Marcel Lévecque and Gabriel Aufaure were thinking: even though the Supertel had been successfully launched, it needed improvement. What was more, the need for insulation was developing very quickly.The rural exodus, urbanisation and economic growth had combined to create an explosion in house building.The licensees needed assistance and training to follow the developments in such a promising market.As for the researchers, the experience of 1953 Rollisol, one of Isover's first big commercial successes in the 1950s. 76 77 GB 054-097-STG-7-05 2/09/08 9:44 Page 78 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS 'TEL' CONQUERS THE WORLD May 1957: industrial exploitation of the Supertel began at Rantigny. The process was much better than the competition, producing a fiber of unequalled fineness and lightness. This was the beginning of an international success. In a few years, dozens of licenses were entered into across the world. Unquestionably, the Supertel surpassed the rival processes technically, but should its industrialisation be generalised? The answer, which is so obvious now, was far less so in 1957. The licensees wondered. There remained some uncertainty about the viability of the process over time, notably concerning the behaviour of the spinners, which were subjected to high temperatures. In addition, investment was needed to adapt production lines which had been optimised over many years for the Owens process. Nevertheless: Sodefive quickened the pace, having seen OCF make direct promises to the licensees.At the same time, the Heye Group was adopting new glass compositions for the Owens process and was letting it be well known. In 1956, Sodefive could only gain time, while hoping that the process would soon be perfected. It organised countless visits by foreign company representatives to Rantigny, to show them the new process under test. Finally, in May 1957, Gabriel Aufaure, the director of the Rantigny factory, took the decision. The Owens process was closed down and replaced by the Supertel, which everyone apart from the Saint-Gobain researchers called the TEL. Industrial production began with six 'heads', as Supertel operated according to the 'rule of sixes': six tons of fiber per day (per head), six Japanese visitors from the Asahi Glass company, accompanied by Marc Toledano from Sodefive. 78 thousand holes per spinner, six microns in diameter. “There is a risk, but we are taking it”, Aufaure replied to questions from a worried associate. It was a gamble which rapidly paid off: the Spanish advertising, 'Neither hot nor cold, and no noise'. 79 GB 054-097-STG-7-05 2/09/08 9:44 Page 80 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS 1 product fulfilled its promises. Not only was it soft to the touch, but for equal insulating performance, it weighed half as much as stone wool. Customers, who were at first surprised by this lightness, had to be convinced, but this happened quickly. Isover reoriented and refined its marketing by offering its customers a product which was no longer basic, but effective and with real characteristics. From then on, it was to be judged using performance criteria. Even though new developments saw the light of day at La Villette until 1959, the 'TEL' was officially launched. It was to dominate the insulation world for decades to come. 1 The following industrialisations took place outside France. The 1958 world insulation conference in Cannes was the first opportunity to take stock. Marcel Lévecque presented the Supertel to the representatives of the whole world. 1958 to 1963 was the 'golden age for granting of TEL licenses', in the words of Claude Jumentier, the technical director of Sodefive. Most of the pre-war Hager licensees became TEL licensees, and new ones arrived. Sodefive showed what it was capable of.A mobile team was set up to help each new licensee design, build, then start up its installations. The crowning achievement of the edifice, or in any case the most significant: in 1968, SaintGobain installed the TEL in the United States (see 'CertainTeed: The American adventure'). And the movement continued towards the East. 2 2 1. Construction of a TEL line in Brazil, in 1963. 2. Lighting the furnace at the Etten-Leur factory in the Netherlands in 1962. 1. 2. TEL line start-up at the Vamdrup factory in Denmark, in 1965. 80 3. TEL line in production at the Etten-Leur factory in the Netherlands. 3 81 2/09/08 9:44 Page 82 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 CERTAINTEED: THE AMERICAN ADVENTURE In 1966, CertainTeed, an American construction material producer, took over the glass-maker Gustin Bacon and wanted to get into the insulation market. However, its fiber production process, which it had bought from Pall in 1964, at the same time as a factory at Mountaintop (Pennsylvania), had never been successful. Malcolm Meyer, the managing director, therefore contacted Saint-Gobain and began negotiations, which concluded with the creation of a joint venture, with equal shares held by the two companies. CertainTeed Saint-Gobain (CSG) was born on 1st July 1967 for a period of thirty years. Saint-Gobain made its technology available as part of a license paid for with bonds which could be converted into CertainTeed shares, while CertainTeed brought access to the American construction market, where it was already firmly established, thanks to its asphalt shingles. On this occasion, Saint-Gobain took a first share in CertainTeed and finished by taking total control of CSG in 1988. During the summer of 1967, a team of American engineers came to Rantigny in order to familiarise themselves with the TEL process. Then a French team directed by René Goutte left in the autumn, to supervise the factory installation. The deadlines were very tight: seven production lines had to be set up and started before July 1968. They were divided among the sites at Mountaintop, Kansas City and Berlin, New Jersey. On the Mountaintop site, the ground first had to be 'cleared', as the Pall installations had remained as they were, including the solidified glass! The factories 82 finally started up at the agreed time, despite the difficulties, surprises and sometimes fits of laughter due to a radically different technical culture. For example, as energy costs practically nothing in the United States, there was no provision for recovering the heat from the smokestacks as Europe usually did.When it started up, Mountaintop was the Saint-Gobain Group's biggest TEL unit. Due to the oil crisis, which brought new insulation regulations, the American market exploded. A new factory was opened in Athens (Georgia) in 1975, with an enormous electric oven, and a big production line was set up in Kansas City in 1978, then at Chowchilla (California) in 1979. CSG was selling in particular a product which had been perfected previously by CertainTeed: InsulSafe. This was a fiber without binder designed for attic insulation. It was highly compressed as it came off the production line, to limit transport costs, given the large delivery distances characteristic of the United States. It regained its initial volume during its blowing application. This product alone occupied four production lines. 83 GB 054-097-STG-7-05 2/09/08 9:44 Page 84 1 2 THE LONG VOYAGE OF A POLAR 'ICE CUBE' Mo-I-Rana, February 1959. In this small Norwegian village close to the Arctic Circle, some men were indulging in a very strange occupation: they were cutting a three-ton block out of the Svartisen glacier, wrapping it up carefully in glass wool and loading it onto a truck, covered with a simple tarpaulin. On the morning of the 22nd, to the music of the local brass band, the giant ice cube began a 12,000-kilometer voyage, which took it to Lambaréné in Gabon, after having crossed Europe, the Mediterranean, the Sahara desert and the Equatorial forest! Norway, Sweden, Denmark, Germany, Belgium and France were crossed quickly. On 28th February after an uneventful week's drive, the truck and its precious load embarked at Marseilles aboard the Sidi Mabrouk. At this point, the ice cube had only lost three liters of 1. Leaving for Oslo, along the Norwegian fjords. 2. Algeria, the truck is unloaded from the 'Sidi Mabrouk'. 84 water. It was unloaded in Algiers on the first of March, and remained there for two full days, thanks to formalities. It must be said that Operation Svartisen was also delivering medication intended for Dr. Schweitzer; a very attractive cargo in an Algeria at war. On 3rd March, the truck set off early in the morning, under military escort. Ahead of it were more than 3,000 kilometers of desert, in temperatures which could reach 55 degrees centigrade (131°F) in the shade. At Ghardaïa, no road, just a track remained. Real hell began. From dune to dune, oasis to oasis, the truck finally reached Zinder, close to the Nigerian border, on 12th March. The Sahara was behind it. In the nineteen days of the 7,500-kilometer trip, the ice cube had lost 177 liters of water. On 13th March, the last stage began; an Equatorial one, to Gabon. The red dirt track now crossed the forest, in a perpetual moist heat. Nigeria and Cameroon were swallowed up, as far as the port of Douala, where the truck embarked on 19th March for an overnight crossing to Libreville. Gabon's decrepit bridges would not have been able to take the weight of the truck, making the last planned land stage impossible. On the 20th, when they arrived in the Gabonese port, they met with Admiral Le Gall, the director of Sodefive who organized the whole adventure with the team of the Norwegian licensee, Glava. The Gabonese capital was celebrating the first anniversary of the country's independence, and the truck drove on to Dr. Schweitzer's hospital, in Lambaréné. The cases of medicine were delivered to the famous doctor on 22nd March. Finally the moment everyone had been waiting for arrived: the tarpaulins were removed, then the glass wool. The 'ice cube' appeared its corners were slightly rounded, but that was all. It had lost just 336 kilos, a mere tenth of its weight, since the start! Glass wool had just proved its effectiveness as a thermal insulator, in a brilliant manner. After 12,000 km, the block of ice has only lost 1/10th of its weight, thanks to its glass wool protection. Diagram of a section of the truck transporting the ice. Dr Schweitzer, awarded the Nobel peace prize in 1952, helped unload the medicine given by several European Red Cross organisations. 85 2/09/08 9:44 Page 86 THE NEW LICENSE GAME The Saint-Gobain Group had become a technological driving force. For its part, Sodefive launched a policy of global assistance for its licensees, and little by little, built the 'Sodefive licensees' club'. During the negotiations for the 1951 agreements, which were supposed to replace those of the Pool, OCF realised that something had changed: Saint-Gobain's R & D efforts were bearing fruit and visits by OCF's researchers to Rantigny and Lucens, Switzerland, in the summer of 1954 confirmed this. At this time, a new series of agreements were being negotiated, this time specifically concerning the centrifugal processes. On 22nd October 1954, a 'basis for agreement' was signed for each to use and license the TEL and Supertel processes. OCF received the license for these processes, as well as the right to grant sub-licenses, in return for royalties for Saint-Gobain. The same applied in the other direction for the centrifugal processes that OCF was perfecting. Yet while the technicians were exchanging their knowledge and the agreements were being signed, the patent departments were involved in a bitter legal battle. The patent filed by Pierre Heymes in 1946, which described the Saint-Gobain fiberizing process, and therefore that of the Supertel, was attacked without respite from 1948 to January 1958, the date on which the American patent office finally granted paternity of the principle to Heymes. For each opposition, the claims had to be reformulated. After a final skirmish concerning the date of issue, the affair was finally closed in 1961… for a patent which was to fall into the public domain in 1965! Good always comes 86 out of bad, however: on this occasion the Group's management became aware of the importance of a solid patent portfolio to support a strong licensing policy. The licensing policy became an international development tool for the Group.The royalties financed research efforts, the 'flow-back' principle, maintained and even reinforced by Sodefive, contributed to technological progress, but above all, the assistance given to licensees gave Saint-Gobain a knowledge of the foreign markets that it could not have acquired otherwise. This system of assistance was institutionalised when Marcel Lévecque imposed systematic technical assistance for each licensee, at the rate of one visit per year. This visit was programmed at the beginning of the year and of course did not exclude specific visits on request. Intervention in the case of an incident, but also basic research for new operations or technical improvement: Sodefive's range of missions was widening. To a point that in 1959, a techno-commercial assistance cell was created, whose creed was: 'the licensee must be helped to increase its sales.' It maintained a technological watch over the products, led the licensees' network, organised the insulation conferences and studied local markets (climatic, economic and architectural characteristics)… Little by little, what was to be called the 'Sodefive licensees' club' was formed. CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 RANTIGNY : BIRTHPLACE OF THE FIBER The Rantigny site, birthplace of Saint-Gobain's glass fiber, is today an industrial research center and logistical platform. The industrial history of this village in the Picardy region of France, 70 km from Paris, goes back to the 17th century. At that time, the Brèche, a small tributary of the Oise river, turned around fifty watermills, certain of which would be turned into factories in the 19th century. The biggest of them, the 'Roue de Rantigny', which for a time belonged to the Duc de la Rochefoucauld, became 'national property' during the Revolution, before passing into various hands. In 1826, it was enlarged and modernised, and in 1876 became a copper and gold rolling mill, which was to develop into a gold and silver goods factory towards 1900. In 1927, the 'Société des Textiles Nouveaux' (STN) bought the site to set up production of artificial fibers. STN became a subsidiary of SaintGobain when the group began making cellulose fibers and closed down its activity in 1937. The site was then given over to textile fibers. The newly-created Isover set up Verrane and Silionne lines here, then in 1941, the Owens and Gossler lines repatriated from the bombed Soissons factory arrived. Rantigny was then producing 'textile' and 'insulation' fibers. Moreover, during its history, the site would at one moment or another house all the fiber production processes that Saint-Gobain has exploited. factory set up in 1919 next to the watermill, had been acquired. From then on, the site continued to expand and was covered with new buildings; work extended to a diversion for the Brèche in 1958-59. In 1960, work began on setting up the research center, next to the factories. During this decade, Supertel was working at full output. New extensions were necessary. The site was producing nearly 20,000 tons of fibers per year in 1960 - and reached nearly 70,000 tons in 1982. Polystyrene, with a 'home-made' process developed by the CRIR, arrived in 1972. In 1976, most of the old buildings had been destroyed to make way for a single large modern building. From one and a half hectares in 1937, the site finally reached 32 hectares in the 1980s, at the height of its splendour! This was to be its swan song. Industrial production progressively decreased from 1983 to 1986. The polystyrene manufacturing workshop was sold off to Lafarge; the insulation production lines were divided between the Orange and Chalon-surSaône factories. The historic mill and its outbuildings were destroyed in 1987 for safety reasons, and the last line producing pipe sections closed down permanently in 1997. The activity, suspended, then re-started in slow motion during the war, began again with a vengeance in 1946. The previous year, the site of a former aluminium powder producing The Rantigny factory. 87 2/09/08 9:44 Page 88 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 The Rantigny factory in 1953. 2/09/08 9:44 Page 90 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 1 2 1. Advertisement for glass wool, in 1954 2. Some examples of advertising which appeared in the press, in 1951. 91 2/09/08 9:44 Page 92 'EVERYTHING IS FINE' Faced with a hostile tender offer, Saint-Gobain allied itself with Pont-à-Mousson, in 1970. Once it had overcome this initial destabilisation, the Group went from strength to strength. Two successive oil crises, in 1973 and 1979, caused the insulation market to explode. Saint-Gobain's insulation branch has a spectacular decade. December 1968, a bomb drops. Boussois-Souchon-Neuvesel (BSN), number two producer of flat glass in France, after SaintGobain, launched a hostile public takeover bid for its bigger rival! Antoine Riboud, its young managing director, suddenly became famous for wanting to 'swallow up' a Group which was three times bigger than his own. It was in fact a public offer to provide BSN for those of Saint-Gobain, not a purchase. Antoine Riboud intended paying with bonds which would be convertible into BSN shares. Would David beat Goliath? In any case, the operation was on the front page of the newspapers, as it was the first big financial manoeuvre of this kind in French industry. Saint-Gobain was suffering at the time; despite the promising development of the insulation activity, other branches, particularly the chemical activity, were experiencing difficulties and the Group was losing money. The counterattack took surprising forms. For example, the Group asked the French communication agency, Publicis, to launch a huge communication campaign, which among other things would see the shareholders visiting 'their factories' during their 'open houses'. A group of bankers, led by the 'Compagnie Financière de Suez', came to Saint-Gobain's rescue. Finally, Antoine Riboud's project failed: at the close of the operation, BSN had only picked up 7% of Saint-Gobain's shares. However the Development of the Erika logo (Epaisseur Rentable d'Isolation k), the feminine face associated with the brand from 1969 to 1981. Group was further weakened by this episode. It was short of liquid assets and 40% of its shares had changed hands. Since 1964, Suez had held an important share in Pont-à-Mousson's Advertising campaigns in the professional and consumer press. 92 93 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 2/09/08 9:44 Page 94 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 capital.This iron and steel group,the world leader in cast iron pipes, was merely a third of the size of Saint-Gobain, but held strong financial reserves. The idea of a merger was raised, and encouraged by the the French President Georges Pompidou and his government. In 1970, it happened: 'Saint-Gobain-Pont-àMousson' (SGPM) was born. A world-size group had just emerged. As part of the “dowry”, Pont-à-Mousson brought the Roclaine company, which was immediately attached to Isover - and finally absorbed in the 1980s. But the most outstanding event was the arrival at the head of this newly-formed group of Roger Martin, managing director of Pont-à-Mousson, who introduced a new, more modern and better organised style of management. The group was structured by product branches. The visibility given to the insulation business in this new organisation showed its strategic importance for the Group. The Rantigny factory could no longer meet all the demand and work began on a new factory in Orange, in 1971. The first oil crisis came in 1973, closely followed by the second. The insulation market exploded. Saint-Gobain took up the position of leader on the world insulation market and even set up in Japan. The 1970s were euphoric; everything was going well, or so it seemed. Promotional campaign for roof insulation in France, 1978. 94 95 2/09/08 9:44 Page 96 CHAPTER 2 - - THE GOLDEN AGE OF THE ENGINEERS GB 054-097-STG-7-05 Invitation to the Batimat trade show, 1970s. 96 Advertising for the Isover stand at the Batimat trade show in 1967. 97 GB 098-137-STG-7-05 2/09/08 9:46 Page 98 CHAPTER 3 Far from the needs of the market The reaction Renewed profitability The model's limit Another test A TIME OF TURBULENCE AND ADAPTATION At the end of the 1970s, the Insulation branch of Saint-Gobain was 'surfing' the wave of its success. Production capacities were continuing to increase. Why should the coming decade not be as good as the last? And yet… technological excellence was not enough to sell products. As a consequence of not having realized this in time, Isover was to have a turbulent decade. A period of questioning which would see the emergence of new strategies, closer to the customers' needs. 99 GB 098-137-STG-7-05 2/09/08 9:46 Page 100 1986 1957-2007 The privatisation of Saint-Gobain-Pont-à-Mousson was a success. Despite the multitude of individual subscribers, the ‘hard core’ of the shareholding returned more or less to what it had been before nationalisation. Jean-Louis Beffa took charge of the Group on 23rd January. In half a century, nearly a hundred TEL production lines had been set up throughout the world. This technology had reached all the continents. At the same time, a real network of licensees was formed. 1982 The Saint-Gobain group was nationalised and in December, a new management team arrived. Éric d’Hautefeuille took responsibility for the Insulation branch and undertook its recovery. On the menu: international development with the acquisition of licensees and above all, the predominant requirement to take into account customers’ needs. 1986-2000 Improvement of customer service: computerization, logistics, palletization. The Multipack was the successor to the Compact, Saint-Gobain’s first innovative and patented packaging, and moved on to a new stage. All insulation products were now available on a pallet, in standard sized packages. A plus for Isover’s logistics..and its customers. 1984 On 12th May of this year, Saint-Gobain signed a license agreement with the Korean glass maker Hankuk Glass Industries. The Group thus continued its conquest of Asia. A glass wool factory was created in 1986, at Inchon. A new factory started up in 2004 at Dangjin. 100 101 GB 098-137-STG-7-05 2/09/08 9:46 Page 102 FAR FROM THE NEEDS OF THE MARKET Intoxicated by their success and the new means made available to them, the researchers perfected even more high-performance processes and new products, which were at times not suited to demand. Isover also extrapolated strong market growth and set up new production lines. Unfortunately the market returned to normal after the euphoria, and Isover found that it had excess capacity. In addition, the rest of Saint-Gobain was suffering from the crisis. The 1980s were starting badly… Research and products which were out of touch with the market The TEL process alone could not cover the whole range of insulation applications. In particular, it did not meet the needs of industrial insulation, which required insulation capable of resisting high temperatures. The fiber production engineers therefore invented a new, more versatile process, the TOR (see p. 104 “The TOR: technical success and economic failure”). Research begun in 1967 came to a successful conclusion ten years later. A pilot line was built and two industrial lines began in Germany.The process the engineers had thought up allowed fibers to be produced from practically any kind of glass! The quality of the products intended for industrial insulation was clearly superior to that of stone wool. Unfortunately, this engineers' dream came to a sudden end.The high energy consumption used in production proved fatal after the first oil crisis and the resulting increase in the price of gas. Isover also tried its hand at products outside its core business, glass wool. These diversifications generally met with failure. The first attempt concerned phenolic foam production from 1975 to 1983. The research phase ended with the construc- 102 103 2/09/08 9:46 Page 104 THE TOR PROCESS THE TOR: TECHNICAL SUCCESS AND ECONOMIC FAILURE “For several years, our research departments have been exploring new avenues and have discovered a fiber production process that can without a doubt be described as revolutionary. It has now passed from the laboratory stage to that of a pre-pilot”. On 24th January 1974, Roger Martin, president of Saint-Gobain, was very optimistic, in front of journalists invited to the 'Théâtre de la Ville de Paris'. In fact the new process had not yet been perfected, but the competition heard the message. Saint-Gobain was not resting on its laurels and it would be difficult and certainly costly to challenge its technological lead. The story of this 'revolutionary' process began in 1965, when Marcel Lévecque asked the CRIR to think about the successor to the TEL, even though the TEL was still being developed. New preoccupations had emerged, such as pollution, profitability, the wish to compete with stone wool in high temperature applications, and the fear of difficulties with the supply of boron, an ingredient in the glass used by the TEL. In December 1967, after two years' inconclusive exploratory research, a brainstorming meeting was convened. On the menu: procedures in which the material to be fiberized would not have to run through holes. The ideas flowed. Prototype followed prototype and on 15th September 1969, a first fiber appeared on an original static device. A burner swept the surface of a layer of molten glass deposited on a horizontal plate, equipped with holes through which powerful compressed air jets blow. 104 These pass through the layer and enter the flame, taking some glass with them, which is then drawn out into filaments. This was the beginning of a long perfecting period, strewn with technical developments and u-turns. In 1972, the process produced fibers as fine as those from the TEL! Theoretical studies showed that at the junction between the flame and the secondary jet, intense vortices are generated, and it is these that draw out the glass filament. The process was therefore named TOR for 'Turbulence ORganisée'. In 1975, the TOR was giving results which were stable and reproducible enough to move up to pilot or even industrial scale. Another advantage was that the TOR could produce fibers from different materials. The decision was then taken to build two pilot lines. The first was dedicated to basalt fiber production, to obtain stone wool which would stand up to high temperatures and thus be suitable for the insulation of industrial installations. On 27th June 1977, after additional finalization at the CRIR, a real TOR basalt industrial production unit started up in Ladenburg, at G+H, a German subsidiary of Saint-Gobain. The second, set up at the CRIR, was dedicated to 'low density' glass wool for building insulation. This line started up in August 1978, also with dimensions typical of an industrial unit. Then came the difficult period. At the end of the 1970s, the industrial insulation market weakened. The Ladenburg line was stopped. A TOR line using a glass as fireproof as basalt was launched in 1980 at Bergisch Gladbach to manufacture CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION GB 098-137-STG-7-05 pipe sections. It too would be stopped. At the same time, the tests being carried out at the CRIR to replace the TEL in the area of classical thermal home insulation showed no advantage. The savings due to the use of glass without boron, for example, were cancelled out by higher energy consumption and the slightly inferior quality of the products. The TEL remained unsurpassable. At the end of 1981, the Insulation Branch's technical management drew up the TOR's balance sheet. It was undeniably a technical success, but offered no economic advantage over the TEL for building insulation. As for high temperature insulation, this was no longer a strategic priority for the Group. The R&D expenditure on this process was not continued in 1982. This was the end of the TOR. The adventure had nevertheless allowed a more economic burner to be designed, since adapted for the TEL, and a pilot line to be set up at the CRIR from 1981 to continue the TEL adventure. It also allowed Saint-Gobain to show its competitors and licensees its capacity for innovation and its adaptability to the economic contexts. The CRIR. 105 GB 098-137-STG-7-05 2/09/08 9:46 Page 106 tion of an industrial pilot, but the increase in costs of oilderived raw materials, as well as the difficulty of improving the image of the material's fire-resistance, condemned this adventure. Another significant attempt was made with the manufacture of U-shaped preformed plaster trays which held a fiberous insulation and formed a roof insulation system.The process, nicknamed Gilda, was stopped in 1983. Here again the engineers had perfected a product which was remarkable, but not suited to market needs.As the distances between roof beams are not standard, a huge number of product references would have been needed. In addition, the U-shape led to exorbitant transport costs, due to the low filling ratio of the trucks. Badly-adapted production At the end of the 1970s, glass wool was selling more quickly than it could be made. After the oil crises, Isover had actually worked hard to worked hard to influence regulations encouraging the use of insulation. Assisted by these new regulations, Isover's results were on a good path and the company was in the situation of having a virtual monopoly in France. The result was a casual commercial policy… “We couldn't supply all the customers on time, so we made choices and negotiated delivery times with the others,” a commercial manager recalls. In short, the customers waited. The 'backlash' was not long coming. New competitors sprang up in France, such as the Slovenian,Termo, the Finn, Paroc, and above all, the Dane, Rockwool. Rockwool arrived in 1975 offering high quality stone wool, capable of competing with glass wool, not just in industrial applications, but also in residential applications.They finally built a factory at Saint-Eloy-lesMines in the Auvergne region in 1980.All these manufacturers were trying to take market share and had aggressive commercial policies. They went looking for customers and launched an intensive price war. At the same time, based on the market explosion, the Insulation branch had increased the production capacity of its factories at Orange in France and Speyer in Germany. Alas, the optimistic forecasts had not included the drop in prices or a dip in the market after a few euphoric years. Isover found itself with overcapacity and products which had become more difficult to sell. Added to this was the bad results of Saint-Gobain Pont-àMousson's other branches. Unlike insulation, the flat glass and pipe divisions were suffering from the economic slump due to the oil crises. At the end of the 1970s, Isover was the only profitable branch of the Group. It, therefore, supported the others, both on a financial level and by taking on personnel, and thus suffered indirectly from the oil crisis! Everything was going badly. In 1982, Saint-Gobain Isover was losing more than a million francs per day. It had to react.The Group's nationalization, (see p.110 “Nationalization and Privatization”), followed by the arrival in December of a new management team at Isover led by Eric d'Hautefeuille, marked a turning point. ÉRIC D’HAUTEFEUILLE, 'BIG ERIC' “He managed an international group but as he liked meeting regular people and concrete discussions so much, he would without a doubt have preferred to be the boss of a small to medium sized company. He was the opposite of a technocrat”, recalls Xavier Grenet, who was for a long time an associate of Eric d'Hautefeuille. Born in 1940,chief engineer of the Mines, he began his career in the Civil Service, then quickly turned towards the iron and steel industry, which was at that time a sector in crisis. In 1982, Jean-Louis Beffa called on him to manage the Insulation Branch of the newly-nationalized company. He was to be the main architect of Isover's recovery, and then would implement a bold international development strategy. He began with Scandinavia and built the foundations for the conquest of the Eastern Europe and Asia. A paradox for a man who preferred 'taking the train to Guéret to flying out to Seoul' according to a joke at the time. In fact Eric d'Hautefeuille loved above all meeting the 'small' customers and confronting the realities on the ground. In 1992, after 10 fruitful years, he was appointed director of the Flat Glass branch, which he reorganized from top to bottom. His success encouraged Jean-Louis Beffa to appoint him to the post of chief operating officer of Saint-Gobain in 1996. He also became a director in 1998. But apart from his industrial success, what impressed people was his human dimension. All accounts of him are full of expressions such as 'deep sense of humanity', 'constant kindness' or 'simplicity and warmth'. He attracted unanimous respect from all those who were close to him. Both before and after his retirement in 2000, he was involved in volunteer work, such as that of the 'Apprentis d'Auteuil'. 'Big Eric' as his associates called him, died prematurely in 2004. Saint-Gobain's board of directors in 1987. Éric d’Hautefeuille during a Sodefive conference. 106 107 GB 098-137-STG-7-05 2/09/08 9:46 Page 108 CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION GERMANY: SPEYER, TECHNICAL PERFORMANCE At the beginning of the 1970s, the old Bergisch Gladbach factory was surrounded by the town. Despite having around 20 spinners on 8 different lines, it could no longer satisfy market demand. It was decided to build a new factory further south at Speyer. The factory started up in 1973 with spacious solid buildings on a site which was big enough for future developments. In the main courtyard there was a bronze bust of Eugène Gentil, an homage to the past, on a site turned towards the promise of the future. The start up of the two lines was a clear success and the good technical performance at the beginning has been maintained invariably until the present day. The Speyer factory was well designed, well built and well run and has for more than twenty years been Saint-Gobain's technological model in Europe, the first stop for any important visitor, future licensee or customer. Additionally, it has been the industrial test site for the CRIR's pilot line, as it was certain that instructions would be respected, procedures followed, measurements carried out and reported and cooperation guaranteed. Numerous long-term industrial tests have been carried out: tests on alloys, the first 600 mm diameter spinner, then 800 mm, etc. It was also enough to say “it worked at Speyer” to silence the opposition and promote a new technique elsewhere. Despite its age and thanks to reinvestment year after year the Speyer factory remains a remarkable production unit. 108 109 2/09/08 9:46 Page 110 THE REACTION After the nationalization of the Saint-Gobain Group in 1982, then its privatization in 1986, Isover was reorganized and its approach changed. The company was to implement a very tough restructuring plan. In a few years, manpower in France was reduced by half and production was rationalized. The TEL process, slightly forgotten at the beginning of this period, still contributed to the insulation companies' recovery. On a marketing level, from then on, Isover was to meet with its customers and develop a new range of products suited to its users' real needs. Meeting the customer Isover began its cultural revolution by 'rediscovering' the customer. From now on, it would go to meet this 'unknown person' on their turf. First of all, physically. Up to that point, Isover had sold its products to 'super-stockists', wholesalers who took care of distributing them to the dealers and retailers, without worrying about market needs. In other words, the company was quite distant from its real customers… The decision was therefore taken to work without these “super-stockists“, and to deliver directly to all the dealers, large or small. The factories would look after the logistics: transport, adjustment of production to demand, and guarantee service to their clients. From now on, the products would go directly to the final distributor. NATIONALIZATION AND PRIVATIZATION “The public sector will be enlarged by the nationalization of the nine industrial groups laid down in the Common Program and the Socialist Program, the iron and steel industry and the publicly-funded arms and space activities. Nationalization of loans and insurance will be completed.” This was the 21st of François Mitterrand's 110 proposals during the May 1981 presidential elections. Saint-Gobain - Pont-àMousson appeared on the list. The nationalization law was adopted on 13th February 1982, and on 21st April, the nationalization of SGPM was announced. Roger Fauroux nevertheless remained CEO of Saint- Gobain and appointed Jean-Louis Beffa as his deputy. Saint-Gobain refocused on its business and began a restructuring plan. In the 1986 parliamentary elections a center-right government came to power, run by Jacques Chirac, with Edouard Balladur as Minister of Finance. On the program: privatization of 65 public companies… including Saint-Gobain. The law was passed on 2nd July 1986. Saint-Gobain, profitable once again, was the first to be offered to the public, between December 1986 and January 1987. The offering was a success: a million and a half buyers acquired 20 million shares. However, when taking institutional investors into account, Saint-Gobain's capital distribution was fairly close to what it had been before nationalization. Back to square one, in a way. Meanwhile, the management team had changed. Jean-Louis Beffa had taken charge of the Group on 23rd January 1986, for the first time, and was reappointed after the privatization. When it returned to power in 1988, the Left changed nothing. This was the period of 'neither-nor' policy of the Socialists: neither nationalization nor privatization. Meeting the customers on their turf also meant offering products answering their expectations. Glass wool is an efficient building material, and Isover indisputably mastered its production.The consumer, however, was faced with a specific problem: how to insulate a roof, an attic, a pipe, a partition wall or a refrigerator? Proposing a fiber was not enough. “There is a shortcoming at this level” Eric d'Hautefeuille noted on his arrival. Products suited to the different market segments had to be developed.This was the beginning of a new Isover advertising from 1978. 110 research and development effort, on terms different from those of the previous decade. 111 CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION GB 098-137-STG-7-05 GB 098-137-STG-7-05 2/09/08 9:46 Page 112 CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION CONFIDENCE MEASURE The ‘Association pour Certification des Matériaux Isolants’ (ACERMI), created in France in 1985, delivers conformity certificates guaranteeing on the one hand that the product really has the characteristics advertised on the label, and on the other, that the manufacturer has an effective operational quality control system. Such a document is essential to obtain the tax reductions that the government grants to anyone starting insulation work on their residence. ACERMI is independent of the producers, and for its analyses relies on the ‘Centre Scientifique et Technique du Bâtiment’ (CSTB) and the ‘Laboratoire National d’Essais’ (LNE). Twice a year it takes products from the manufacturers and inspects their quality control system. Saint-Gobain has taken the initiative in the creation of this system. The aim of the operation, apart from the obvious benefit for the users, is to ‘clean up’ the market. From then on, competition is based on indisputable foundations. Several other countries have implemented similar certification systems (Komo in the Netherlands, Aenor in Spain, Tüv in Germany…). 112 113 2/09/08 9:46 Page 114 Research continues, refocused on the TEL process Despite the disappointing TOR adventure, the CRIR did not give up.The research effort, refocused on the TEL, did not let up. Even during the crisis period, the company maintained its R&D effort.A 600 mm diameter spinner saw the light of day in 1980 and the fiberizing process named 'Arlanda' produced finer fibers with better mechanical properties. With a more efficient burner and a very speed of the spinner, 'Arlanda' fiber production increased the process's productivity. It was a great technical, economic and commercial success because of the lower density it allowed and the investments it avoided. 'Arlanda' fiber production meant that CertainTeed did not have to build a new line and increase its capacity at a time when the company was having financial problems. Its president,Art Winner summed up his satisfaction with the phrase “One square foot saved, one million dollars in CertainTeed's coffers”. Production per spinner reached 20 tons per day. This improved productivity and the increase in the compression ratio which considerably reduced transport costs, helped Isover get through the crisis. Without a doubt, palletization represented the best example of the use of the TEL fiber's new mechanical properties to answer real market demand (see p.125 “Palletization. A winning load”). This packaging process, perfected by the Orange development center, was industrialized in 1987 and spread to all the companies. Germany, with Isover G+H, adopted it first, in 1990, followed by Finland, Italy, the Netherlands, Poland, Austria, Denmark, Switzerland, Great Britain, Russia, Ireland… Internationalization of new products - and good ideas - was from now on one of the building blocks of Isover's approach. Among these products was Calibel, which combined plasterboard with a mineral wool panel. Painful decisions At the end of 1984, Rantigny's main production lines were closed down for good. Granted, it had long been superseded by the Orange factory, but the closing of the historic site, decided in 1983, symbolized the recovery plan begun in December 1982. The Group's losses left few choices: hard decisions had to be made and the production capacities and manpower reduced - decisions which are always painful. Saint-Gobain-Pont-àMousson launched several successive reorganization plans.As a result, the Group's manpower decreased by 20 percent between 1982 and 1986. In France alone, Isover lost, 2,600 employees between 1982 and 1984. As for the production capacities, they were then concentrated at the Orange factory for most of the product line and for long runs, and at the Chalon-sur-Saône factory for more specific products. To this was added the stone wool factory at Saint-Etiennedu-Rouvray, from Roclaine, which had been part of Isover since May 1982. The Insulation Branch refocused on its core business, glass wool: the foams were sold, glass tissue production was stopped in France and a unit was created dedicated to using glass and stone wool fibers for other than insulation (hydroponic cultivation, fibers for roads, fine fibers for battery separators…). Internationally, too, things had to be 'tightened up'. The policy of conquering the Asian market suffered a setback. Although everything was going well in Korea, in Japan, Nihon Glass Wool, (the joint venture between Isover and the Japanese cement manufacturer Nihon Cement, created in 1974), was going badly. (see p.118 “Japan”). The construction of a factory to anti-earthquake standards and problems adapting the product to the local market cost a lot of money.What was more, the competitors began a price war.The losses accumulated, and in 1982 Isover had to pull out of this adventure. The TEL fiber qualities also crossed the Atlantic and allowed a new product to be created: InsulSafe (see p.116 “InsulSafe crosses the Atlantic”). 'Problems, solutions, services' brochure, 1981. 114 115 CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION GB 098-137-STG-7-05 GB 098-137-STG-7-05 2/09/08 9:46 Page 116 In 2005, CertainTeed Insulation Group's American war horse finally set foot in Europe. This glass wool, called InsulSafe, is sold 'loose' with no binder. Heavily compressed for transporting, it is applied by being blown with a blowing machine. InsulSafe was cheap, quickly installed, non-flammable and a good acoustic insulator, and met with success from its launch in 1982 - a clear success for the engineer Les Infante who persisted for years in trying to manufacture blowing wool with the TEL process. Numerous development tests of the InsulSafe production line took place from 1972 onwards at the Berlin, New Jersey factory. Tenacity paid off: today, five production lines in Kansas, California and Georgia are working at full capacity to supply a product which alone represents a third of the American market! Since 1982, the Blue Bell technical center in Pennsylvania has continuously developed the product. Originally intended for loft spaces and unconverted attics, the product quickly became usable for house walls. The other American producers had trouble following the progress of InsulSafe, which was still the leader. However since 1997, the eternal competitor, Owens Corning, had been following closely, with its own blowing wool. So in 2006, CertainTeed launched InsulSafe Super Premium - this fifth generation product allowed 20 percent extra surface to be covered with the same volume. Enough to take an undeniable lead over the competition. At the same time, InsulSafe became the first really worldwide Insulation Activity product. In fact Isover AB's CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION INSULSAFE CROSSES THE ATLANTIC factory at Billesholm (Sweden) has been producing its own version since 2005. It is denser than the American product to meet North European climatic requirements and intended for the Swedish and Finnish markets. It appeared in countries which were already familiar with blowing wool, but depended on its superior performance to make a name for itself, faced with the competition. And since 2006, more temperate zones in Europe have become interested. The CRIR has perfected an 'intermediate' version, between the American and Swedish products, intended for the French and British markets. Although initially produced at Rantigny, as of 2007, InsulSafe will come from the Orange factory. Application of InsulSafe blown glass wool in an attic. 116 117 GB 098-137-STG-7-05 2/09/08 9:46 Page 118 Fresh out of the elite French engineering school, 'Polytechnique', the young René Goutte was offered a scholarship by Saint-Gobain to spend a year at the Massachusetts Institute of Technology, in Boston. “An offer which couldn't be refused!” In 1961, back in France, he began working at the Rantigny factory, where he had his first contact with the TEL, then being developed. During the summer of 1967, the long journey began. Management proposed that he look after the setting up of the factories for the new joint venture it had just created with the American, CertainTeed. The mission was a clear success (see p.83 “CertainTeed: The American Adventure”). But in February 1974, another challenge presented itself: Japan, where Saint-Gobain had just signed a joint venture with Nihon Cement, the second biggest Japanese cement producer. René Goutte left with his family to live in Tokyo. Bolstered by his experience in Rantigny and Pennsylvania, René Goutte was keen to have a factory with a basement for the motors, the waste disposal conveyors, the water cleaning filters, the fans in short, all the supporting systems for the manufacturing process itself. Akeno was thus to be the first insulation factory on two levels, a solution which has since become standard. The first products came off the line in 1976. His stay was coming to an end. After the Japanese episode, René Goutte returned to the United States, where he finished his career. However, the Japanese adventure had not always been easy: adapting the products to Japanese market standards had been tricky, as had managing the different Japanese regional dialects, not to mention the cost overrun on the construction of a factory to anti-earthquake standards… to the point where in 1982 Isover decided to withdraw from a joint venture which was losing money, to become a simple licensor again. However, one aspect had always worked: the TEL technology and its different developments. And the results in production terms were quickly seen. When the Akeno factory was ready, in August 1976, Japan was producing 75,000 tons of glass wool per year. Nippon Glass Wool's production alone reached 40 percent of this volume. The Japanese manufacturers such as Asahi Fiber Glass, Nitto Boseki and Nippon Sheet Glass were very unhappy about being attacked. The price war which followed was not beneficial to any of the companies. Nippon Cement and Nippon Sheet Glass moreover merged putting an end to this war. This was how Nihon Micro-G wool, was created, and renamed MAG en 1994. As the TEL licensee for Japan, MAG today has a 41 percent share of the national market. CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION JAPAN 1 2 1. Tsuchiura factory in Japan. 2. Akeno factory in Japan. 3. The Japanese version of the Erika logo. 118 3 119 GB 098-137-STG-7-05 2/09/08 9:46 Page 120 RENEWED PROFITABILITY In the middle of the 1980s, the Insulation Branch became profitable again. With a process which had a significant advantage over the competition and a new distribution system, the Isover brand was now showing its true strength. The Insulation Branch launched a policy of acquiring its licensees. Improved distribution From 1987 onwards, the distribution system developed in France, with the creation of the regional warehouses. Six big warehouses, all linked to the rail network, covered France.They contained all the available products on palettes - the major part of the range - which were immediately sent on by truck to the final customer.The famous yellow Isover trains appeared at this time, which according to the French national railway company (SNCF) were the longest trains in Europe. Each was composed of 52 open wagons, carrying 16 or 18 Isover palettes - packages which met the SNCF's very strict quality checks. A load was not allowed to move, even when meeting a highspeed TGV train in a tunnel! Each week, four or five of these nearly 800 meter giants left the factory at Orange, in addition to the two hundred trucks loaded with specific products. 1 2 1. 2. The yellow Isover trains being formed at the Orange factory. 120 121 2/09/08 9:46 Page 122 CHAPTER 3 - - LE TEMPS DES TEMPËTES ET DE L’ADAPTATION GB 098-137-STG-7-05 From packaging to shipment. 123 GB 098-137-STG-7-05 2/09/08 9:46 Page 124 “It is imperative to find solutions which provide answers to customers, work sites and factories.” Jacques Chevenard, director of the Insulation Branch from 1978 to 1981, did not mince his words. At the time, the products were coming off the manufacturing line, in rolls or packages of batts stacked by hand on to palettes. Difficult to handle, badly protected and cumbersome, they were a nightmare for the shippers and users alike. The dealers asked for packages which could be handled by fork lift trucks, stacked and protected from moisture… but retained the unit packaging the users needed and were marked with clear instructions for use. The answer came from the Orange site. It emerged in two stages. All the technical, commercial and human constraints of the operation had to be taken into account. Cosmiques refuge The Cosmiques mountain refuge, at 3613 meters on the slopes of Mont Blanc, was destroyed by a fire in 1983 and rebuilt the following year. Insulation is particularly important in this environment, and was carried out using Isover products. The pallets of Bicompact Vertical were particularly appreciated for their suitability for helicopter transport and their small dimensions, essential on this tiny rocky peak… 124 In 1979 a new type of package appeared, made up of nine, lightly compressed horizontal rolls, lying on a preformed cardboard palette. The Compact was born. Officially launched in October 1980, the Compact was protected by two patents in 1981 and 1983. The first line equipped with palletization machines started up at Orange in May 1981. The dealers appreciated it… The Compact was protected from bad weather, could be stacked two or three high and was easily handled by a fork lift. A fork lift driver could load a truck with 288 rolls in half an hour, whereas before, it took two hours for two operators to pack 240 uncompressed rolls into the same truck. The Bicompact, soon appeared, made up of two linked Compacts, but there was still room for improvement. The brand new development center at Orange dedicated itself to this from 1983. The first idea: place the roll vertically - obvious - then stack two loads on a wooden palette and cover everything with polyethylene shrink wrap. This was to become the Bi-compact vertical, which was more rigid than its predecessor. Meanwhile, the competitors, Johns Manville and Rockwool drew inspiration from the Compact and launched their own palletized loads. But at Orange, reflection continued. CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION PALLETIZATION : A 'WINNING LOAD' pallets. The success spread to SaintGobain's other factories, beginning with Germany. Progress continued: continually increasing compression ratios meant that eighteen rolls per palette in 1986 increased to thirty-six in 1994 and forty-one rolls per palette in 2002! And, without a doubt, it will not stop there. Isover was in the forefront in the palletization of mineral wool insulation under compression, and is still leading the field with a compression ratio on its palettes 30 percent greater than that of its closest competitor. Finally, in 1986, the Multipack appeared. This solution was attractive because of its flexibility and simplicity: single panels or rolls were compressed for a first time on the the production line, then gathered together under a polyethylene belt which compressed them again. A 'module' of three rolls (for example) was then obtained. Three modules stacked formed a 'load', which was itself compressed again and lined-up. Finally, two loads were stacked on a wooden palette. The whole, which was two and a half meters high, was wrapped in polyethylene cling film, or shrink wrapped to hold everything in position and keep it watertight. The Multipack was duly protected by patents. But it was not enough to think up a packaging system. Machines were needed which would be capable of realizing it at the end of the line, without slowing things down. Finally, the first palletization line started at Orange in January 1986. Soon all the Isover products were delivered on 125 2/09/08 9:46 Page 126 CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION GB 098-137-STG-7-05 Multipack palletisation line, patented by Isover. 126 2/09/08 9:46 Page 128 Acquiring the licensees THE MODEL'S LIMIT Saint-Gobain was healthy once more, and at the same time, a certain number of licensees were for sale. There were so many opportunities to be seized… The Insulation Branch reaped the fruits of the licensing policy it had operated since the 1950s. So began a round of acquisitions which was to last for two decades and continues to this day.This began in 1985 with the full acquisition of the Swedish company, Gullfiber, in which Saint-Gobain already held shares. The Scandinavian offensive continued with the purchase of Ecophon, a specialist in acoustic ceilings, in 1987. The following year it was the turn of Glasuld, a 'historical' Danish licensee, as it had been linked to Saint-Gobain since the Hager process era; next was Ahlström in Finland and Vasa in Argentina. At the very beginning of the 1990s, the 'Sodefive licensees club' only had six members left; all the others had become Saint-Gobain subsidiaries.This policy continues today, as shown by the takeover of Hankuk Glass's insulation activity in Korea, in 2004 (see p.130 “The Korean adventure”) and the purchase of the Turkish licensee Izocam in 2006. The Insulation branch of Saint-Gobain was present in nearly all the open markets on the planet. The only development possibilities: the Asian 'dragons'. In these small niche markets, Isover took on a new type of competition. A Danish house insulated with Glasuld glass wool, 1979. 128 At the end of the 1980s, Isover was more profitable than ever. Whether through its subsidiaries or its licensees, the company was producing and selling insulating products throughout the developed world. Australia joined the family of licensees, with the license granted in 1987 to Bradford 'dragons' at the time, were likely to welcome new factories or buy insulation products. Isover already had a licensee in Korea. There remained Thailand, Malaysia, Indonesia and Taiwan. All of these are “hot” countries where the demand for insulation for residential construction remained limited. Sodefive therefore launched a study of the industrial and commercial insulation markets: ceilings, pipe sections, panels for industry, etc.All these products required a coarser fiber; a less sophisticated process than the TEL would be more than enough. On the other hand, the Isover units were designed to produce large quantities of fibers, more than was needed locally. They therefore had to suggest small factories using flexible and basic processes. At that time, the patents relating to the TEL principles were coming into the public Insulation, a subsidiary of CSR, whose brand new Ingleburn factory started up in 1989. Isover had become the world leader in insulation, ahead of OCF.What then remained to be domain, one after the other. New competitors were appearing: engineering companies, who were offering simple fiberizing units, based on the first generation centrifugal processes and explored? Where were the new markets to be found? The Eastern European countries were entrenched behind the Iron therefore free of royalties. From then on, the candidates did not hesitate. Why link themselves to Saint-Gobain with a Curtain and China, while showing some signs of interest, was taking a long time to open up. Moreover, as the demand for insulation obviously depends on climatic conditions, as well process which was too sophisticated for the needs of markets that were essentially industrial? So the Branch's Engineering department designed a small capacity production tool, based as the country's level of development,Africa and the poor part on simple technologies and adapted to the needs of these coun- of Asia were excluded. Compared with this, only the emerging southeast Asian countries, those that were called the tries: this was to be the Mini TEL unit. It was offered in Egypt or in Tunisia, but these projects did not get off the ground. 129 CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION GB 098-137-STG-7-05 2/09/08 9:46 Page 130 CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION GB 098-137-STG-7-05 1 2 THE KOREAN ADVENTURE Contrary to preconceived notions, Korea is a rather cold country. Additionally, it has shown strong economic development. Two good reasons behind the development of an insulation market. Also, two good reasons for Isover's interest in that market. Finally, after setting up in Japan, a Korean licensee would allow them to keep a close eye on the Asian market. A first license agreement was signed with Kolon Nylon, an artificial textile specialist, in 1979, but would never become effective. This is why, in 1982, Saint-Gobain began negotiations with the only Korean glass producer: Hankuk Glass Industries. The license agreement was 130 signed on May 1984. Two years later, the company's purpose-built factory, started up at Inchon, using the TEL process. Isover supplied all the necessary technical assistance during its successive expansions, until a second electric oven was installed in 1994. In January 2003, after the closing down of the Inchon factory, Haniso, still with Isover's support, launched a factory construction project at Dangjin. This unit, which brought the company's production capacity to 25,000 tons per year, began production in March 2004. It manufactures, in particular, sandwich panels for industrial buildings. At the beginning of the 2000s, Saint-Gobain took control of the glass producing group, Hanglas, and therefore its subsidiary, Haniso a profitable operation in a booming Korean insulation market. In fact foams, which represented up to 70 percent of insulation sales in Korea, were penalized by the stricter norms in force since 2001, following a series of lethal fires. Glass wool is a fireproof material and from then on, regularly won market share. Haniso hoped soon to achieve a third of the country's sales. As for the idea of an Asian 'bridgehead', it too began to be concretized in 2004 with the creation of a common purchasing group between Haniso, Isover China and MAG, Isover's Japanese licensee. 1. Opening ceremony of the new factory on 2nd June 2004. 2. Dangjin factory production line in Korea. 3 3. Dangjin factory. 131 2/09/08 9:46 Page 132 ANOTHER TEST From 1987, Isover had to fight on another front. Alarmist articles in the press were spreading the theory that glass wool and stone wool fibers were carcinogenic. Isover and the other producers put a lot of research, and therefore money, into proving that the use of their products was safe. Glass wool is a reliable and safe product. From the middle of the 1970s, research into the effects of glass fibers on health began. EURIMA (European Insulation Manufacturers' Association) called on recognized experts in order to create a research body on the subject, the Joint European Medical Research Board. On its program: epidemiological research, with the 'International Agency for Research on Cancer' (IARC) in Lyon, France; animal testing; industrial hygiene research. The American producers' association (NAIMA) launched a similar program. Moreover, Isover products are certified by the EUCEB (European Certification Board for Mineral Wool) showing their conformity to the criteria defined by the European Commission and repeated in all the national regulations, thus exonerating them from any carcinogenic classification. Shaken and suffering a growth crisis, the company was soon helped by an unexpected external event: the fall of the Berlin Wall. The professional epidemiological studies carried out on around 45,000 persons by recognized independent organizations, confirmed that glass wool is not a particular risk to health. For this reason, and on the basis of more than 1,000 scientific publications, the International Agency for Research on Cancer (IARC) reclassified glass and stone wools to the same group including products used as commonly as tea and coffee.This decision was exceptional: only five products have been the subject of a positive re-evaluation in 40 years. 133 CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION GB 098-137-STG-7-05 GB 098-137-STG-7-05 2/09/08 9:46 Page 134 Tests were conducted on an industrial scale in Switzerland (Lucens, 1953-1955), South Africa (Springs Fiberglass South Africa, 19561957), France (Rantigny, 1956) and Denmark (Kastrup, 1956). The first operational production line started operating in 1956 in Kastrup at Dansk Superfos. Launching Factories - Countries date Companies 1956 1957 Kastrup - Denmark Dansk Superfos Closed France - Rantigny Isover Saint-Gobain Closed Springs - South Africa Fiberglass South Africa Isover Soraker - Sweden Gullfiber Closed Stockerau - Austria Linzer Glasspinnerei Isover Austria Lucens - Switzerland Fibriver (SG) Isover CH Bergisch Gladbach - Germany Grunzweig+Hartmann (SG) Isover G+H Karhulä - Finland Ahlström Closed Saint Helens - United Kingdom Pilkington Insulation Ltd. Knauf Askim - Norway A/S Glassvatt Vidalengo - Italia Balzaretti Modigliani (SG) Billeshölm - Sweden Gullfiber Etten-Leur - Netherlands Glaceries de Saint-Roch (SG) Isover Benelux Azuqueca - Spain Fibras Minerales SA (SG) Isover España Llavallol - Argentina Vasa Isover Argentina Santo Amaro – Brazil Santa Marina Isover Brasil Stjordal - Norway A/S Glassvatt Thane - India Fiberglass Pilkington (FGP) Closed Ruukki - Finland Ahlström Closed Inophyta - Greece Monyal Closed Teheran - Iran Iran Glass Wool Closed Gebze - Turkey Izocam Roche (SILLAN) Mountaintop – United States CertainTeed Saint-Gobain Berlin - United States CertainTeed Saint-Gobain 1959 1960 1961 1962 1964 1965 1966 1967 1968 134 Current status Launching Factories - Countries date Companies Current status 1971 1972 1973 1975 Forssa - Finland Ahlström Isover Oy Orange - France Isover Speyer - Germany Grunzweig+Hartmann Isover G+H Athens - United States CertainTeed Saint-Gobain Pont-y-Felin - United Kingdom Pilkington Insulation Ltd Knauf Akeno - Japan Nihon Glass Wool MAG Kansas City - United States CertainTeed Saint-Gobain Shiraz - Iran Iran Glass Wool Chowchilla - United States CertainTeed Saint-Gobain Shuaiba - Kuwait KIMMCO Hyvinkää - Finland Ahlström Isover Oy Vamdrup - Denmark Glasuld Superfos Isover A/S Chalon-sur-Saône - France Isover Inchon - Korea Hankuk Isover Italia Tarsus - Turkey Izocam Isover AB Candiac - Canada Fiberglass Canada Tsuchiura - Japan MAG Ingleburn - Australia Bradford Closed 1976 1978 1979 1980 1982 1984 1986 1988 1990 1996 1998 1999 2003 2004 2007 Zhuhai - China CSR Guangdong Runcorn - United Kingdom British Gypsum Isover Sunagawa - Japan MAG Ardfinnan - Ireland Moy Isover Gliwice - Poland Gullfiber Polska (SG) Lübz - Germany Isover G+H Yegorievsk - Russia Isover Yegorievsk Dangjing - Korea Hankuk Haniso Ambernath - India UP Twiga Ploiesti - Romania Isover Romania CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION INTERNATIONAL DEVELOPMENT OF THE TEL PROCESS Closed Closed Isover UK Isover Polska 135 GB 098-137-STG-7-05 2/09/08 9:46 Page 136 136 CHAPTER 3 - - A TIME OF TURBULENCE AND ADAPTATION INSULATION ACTIVITY SITES IN THE WORLD (APRIL 2007) 137 GB 138-185-STG-7-05 2/09/08 9:48 Page 138 CHAPTER 4 A world opens up Pursuit of a customer-based policy Birth of a worldwide brand The TEL pushes back its limits again New frontiers Answering a planetary problem RECOVERY AND NEW CHALLENGES The last decade of the XX th century opened with new challenges: the frontiers were opening to the East and protection of the environment became a preoccupation very much in the foreground.The Kyoto Protocol commitments and the new oil crisis have changed the situation: insulation is one of the main activities contributing to reducing the consumption of non-renewable energies, and thus greenhouse gas emissions. This is Isover’s crusade for the XXI st century. 139 GB 138-185-STG-7-05 2/09/08 9:48 Page 140 1993 2004 After the fall of the Iron Curtain, a world opened and Saint-Gobain’s Insulation branch began to set up in the Eastern European countries, where insulation needs were huge. First markets concerned: Poland (creation of Gullfiber Polska) and the Baltic countries (opening of sales offices in Latvia, Lithuania and Estonia). Since 1986, Saint-Gobain’s research had tried to make fibers from stone or high temperature resistant glass, with the TEL process. An essential advance for the naval and industrial applications. In 2004, the new glass wool generation, ULTIMATE, was launched. Since then, it has accumulated successes and medals. 1998 2005 Signature of the Kyoto protocol (Japan) on 16th March. The world became aware of climate change and the scale of its foreseeable consequences if nothing is done to decrease the emissions of greenhouse gases. The insulation of buildings, which allowed millions of barrels of oil to be saved every year, became a planetary venture. 2000 Globalisation was a reality; Isover took note. All the insulation subsidiaries now carried the same name and shared the same yellow logo, with its characteristic ‘O’, unveiled at the end of 1999 at the Batimat show in Paris. Isover became a worldwide brand. 140 Saint-Gobain acquired the British Plaster Board group, the world leader in plaster and plasterboard. The two activities (Insulation and Gypsum) complement one another perfectly, as much from a product point of view as that of geographic location. The biggest world company dedicated to interior fittings had just been born. 2006 Isover launched the ‘Multi-Comfort house’. This house, combining optimal thermal insulation, insulating windows, heat recovery and renewable energy sources, is cool in summer, warm in winter, protected from noise all the year round, and does not consume any more energy than it produces. 141 GB 138-185-STG-7-05 2/09/08 9:48 Page 142 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES A WORLD OPENS UP When the Berlin Wall fell in 1989, a huge market opened up for Isover. Everything had to be created in Eastern Europe: an insulation culture, including the means of distribution and production. Poland, the Czech Republic, the Baltic countries, Hungary and Russia in turn came into the Insulation branch's field of operations. On the night of 9 th/10 th November 1989, residents of Berlin brought down the 'wall of shame' which had cut their city in two since 1961.This was the high point of the dismantling of the Iron Curtain which had separated the two blocs since the war. The Hungarians had begun this destruction on 2nd May 1989, by attacking the fortified frontier separating them from Austria. A prelude to the 'velvet revolution' in November December.The process thus set in motion ended in December 1991 with the resignation of Mikhaïl Gorbatchev, the last president of the Union of Soviet Socialist Republics (USSR).The Warsaw Pact had lapsed, and the USSR had been partly replaced by the Commonwealth of Independent States (CIS). For Isover, the collapse of the Wall was a turning point: a world which had up until then been inaccessible was opening up. It was a world of cold, developed countries, whose housing stock was decaying. Insulation needs were huge. Everything had to be done, firstly to create a culture of comfort and energysaving, therefore insulation, in populations used to decaying accommodation and almost-free energy.There were certainly insulation manufacturers in some of these countries, but in general they were using obsolete technology. Some of them in central Europe were old Hager licensees, separated from Isover by the war and isolated for years behind the Iron Curtain. Isover transports. 142 143 GB 138-185-STG-7-05 2/09/08 9:48 Page 144 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES Sodefive studied these potential markets and became ipso facto a real international development tool. It fulfilled its duty - while pursuing its mission of supporting the licensees - until it was wound-up at the end of 1997. Sodefive decided to bet on the historical links between Eastern Europe and the major neighboring western European countries, even though these links had been dormant for several decades. So a working group formed by Sodefive, representatives from the German company Isover G+H and Isover Sweden (ex-Gullfiber) took responsibility for studying these countries. Gullfiber Polska was created in 1993 and, three years later, bought a stone wool factory at Gliwice, near Katowice. With the addition of a new TEL line and the modernization of the stone wool line, it became the Polish market leader and exported its products to the Ukraine, Russia, Lithuania, Byelorussia and the Czech and Slovak republics. Partition of Czechoslovakia had in fact taken place on 31 st December 1992. In February 1996, G+H (Germany) bought Orsil, a Czech stone wool producer. After serious modernization of its factory, this company has now become an exporter. For Russia, it was Isover Oy, the old Finnish licensee and subsidiary since 1994, which served as a base for the conquest of this huge market, before a factory could be set up there… but that's for later. In 1991, when the USSR was dissolved, the Baltic countries decided to join the European Union. Two years later, Isover Oy opened its sales offices in Latvia, Lithuania and Estonia. Here again, the first job was to acquaint the general public with the benefits of insulation 1 3 2 in these very cold countries. For five years, Isover's representatives traveled to trade shows, met with the authorities and ran repeated publicity campaigns. This work bore fruit: today, Saint-Gobain's Insulation activity has a strong position on these three markets. 1. Polish advertisement, 2005. 2. Gliwice factory in Poland. 3. 4. Saint-Gobain Orsil factory in the Czech Republic. 144 4 145 GB 138-185-STG-7-05 2/09/08 9:48 Page 146 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES 2 3 1 1. Dance center known as 'Fred & Ginger', Prague, Czech Republic. Architects: Vlado Milunic and Franck Gehry. 2. Agora Group's head office, Warsaw, Poland. 3. Stadium Allianz Arena, Munich, Germany. Architects: Jacques Herzog and Pierre de Meuron. 4. Lecture room, Moscow, Russia. Architect: Konovalov Yurij N. 5. Turning Torso Tower, Malmö, Sweden. Architect: Santiago Calatrava Valls. 146 4 5 147 GB 138-185-STG-7-05 2/09/08 9:48 Page 148 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES PURSUIT OF A CUSTOMER-BASED POLICY In 1990, Isover launched the 'Carte des Services' in France. It guaranteed even faster, more flexible, more reactive deliveries. The company no longer sells just glass wool but now offers complete 'solutions', from assistance with decision-making, to the insulating system with its accessories. The sense of service In 1990, Saint-Gobain Isover committed itself in the area of logistics and customer service by launching the 'Carte des Services'. For the dealers, this was the guarantee of systematized, reliable service with guaranteed deadlines. It was also a guarantee of of greater flexibility, as they could choose the type of service that suited them, at no extra cost. Generally, Isover depended on palletization and its new distribution structures to guarantee delivery in 48 hours, then in 24 hours, from 1998. In fact, the commitment has grown stronger with time. According to the chart, there is, for example, the 'service chantier' (work site service), which consists of delivering directly to the end user rather than to the distributor who has bought the product from Isover. The dealer is The time is also long gone when Isover just sold insulation and left the customer to find out how to use it. From the 1970s, Isover has developed knowledge of energy saving problems notably through the idea of the 'cost-effective insulation thickness' or the launch of the R certification. Since the 1990s, Isover has offered 'solutions'. The first sales action, moreover, consists of helping the customer to determine his needs. Whether a dealer, user, architect or foreman, he will find a suitably qualified person to speak to. In Germany, for example, there is a technical telephone help service, Isover Dialog, mainly consulted by architects and designers. therefore spared the task of delivering to his own customer… The ultimate in delivery deadlines is the ‘rendezvous chantier’, (work site appointment), set up in 1998. Pallets are unloaded using cranes or fork lift trucks which the works managers hire at an hourly rate. Punctual delivery means savings for the customer. This service has been pushed to the limit in Finland, where drivers are linked by telephone to the delivery site. Traffic problems or last minute changes in direction: everything can be organized. Advertising launched in the United Kingdom in 2006: 'Since 1665, the customer has always been king'. 148 Maps of Isover services in 1990 and 2005. 149 2/09/08 9:48 Page 150 Development of systems viewers of a Buster Keaton silent film having to put up with the soundtrack of a disaster film next door? The solution suggested by Isover led to the creation in 1997 of Technostar, a system which combines a metallic frame, different glass wools and a plasterboard facing. The Technostar partition was efficient, quickly erected and could be dismantled; it has been fitted to dozens of multiplex cinemas. It continued an international career in Denmark, then in Belgium, the Netherlands, Brazil, Morocco, Bulgaria and more recently, in China. Finally, the products themselves have evolved. After the restructuring in the 1980s, which was carried out by refocusing on the glass wool business, the commercial strategy developed from 1990 to 2000. Isover was offering a wide range of insulation products: mineral wools, foams, hemp wool… and was developing more and more 'systems', where the insulating materials were integrated into more or less complex structures, with their fixing accessories (Optima, Climaver, Vario systems…). The Technostar partition is an example. In 1991, Pathé was building one of the first multiplex cinemas in France. How could they avoid the 1 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES GB 138-185-STG-7-05 2 1. The Vario “smart” membrane associated with insulation allows optimization of thermal performance of the walls. 2. Implementation of an air-conditioning system with self-supporting conduits in Climaver glass wool. 3. The Optima system combines wool insulation, metal studs, accessories and plasterboard. 150 3 151 2/09/08 9:48 Page 152 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES GB 138-185-STG-7-05 Ecophon ceilings for acoustic treatment of offices. Fitting a Technostar partition wall. GB 138-185-STG-7-05 2/09/08 9:48 Page 154 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES 1 1. Diagram of acoustic insulation. 2. Estonian advertising, 2003. 2 154 3. Concert hall, Vienna musical Association, Austria. Architect: Wilhelm Holzbauer. 3 GB 138-185-STG-7-05 2/09/08 9:48 Page 156 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES COMFORT CONTACT! Following market demand, and anxious to improve user comfort when installing glass wool, the Orange development center perfected, in a year and a half, a new product called 'Contact'. It just looks like a roll of classic glass wool batting, except that it is covered with an extremely flexible and soft polypropylene film. The film material comes directly from babies' diapers. The user now has no contact with the glass wool in normal use. This was an immediate success with the craftsmen, who can now install glass wool without gloves. Contact has been adapted in numerous countries (for example, Comfort in Finland and Integra Comfort in Germany). 156 157 GB 138-185-STG-7-05 2/09/08 9:48 Page 158 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES BIRTH OF A WORLDWIDE BRAND The same name for all the subsidiaries throughout the world, a single brand for all the products, a new logo. In 1999-2000, Isover underwent a face lift and became a genuine integrated, worldwide group. And research followed the change. Commercial synergies At the end of the 1990s, the marketing teams of the Insulation branch companies throughout the world acknowledged globalization, its consequences and opportunities. Working with different historic brands, they decided from then on to display the same brand worldwide. After research and discussions, this was to be… Isover, with a new logo suited to the period.Thus, beyond the visual identity, the Isover teams exploited the potential of international synergies and increased the exchanges of good practices.The customer, in first place, immediately benefited from successful experiences on the other side of the world and from the size of the group. The logo first appeared at Batimat Paris, the European construction show, in November 1999. At a big evening the new generations of customers. Significant investments in communication pushed the launch of the world brand; they are still going on in numerous countries. R&D synergies On its own scale, Isover's research has followed the same path. The three centers at Rantigny (France), Ladenburg (Germany) and Blue Bell (Pennsylvania, United States), as well as all the product development centers in the factories, had been working more closely since January 1999, the launch date for the '2i' project, '2i' standing for 'Isover International'. The aim was to define a method of working which would allow a balance to be found between effective central coordination and local creativity.A 'matrix' organization was celebration, the teams and the main clients, who had come from all over the world, felt the 'world family' spirit. From then on, all Isover's subsidiaries used the same name and the same therefore set up. In more concrete terms in the future, research would be carried out on projects, and communication tools were set up so as to form just one virtual center. Thus a colors, in this case yellow. The new logo was unveiled at this occasion, with a distinctive 'O'. Certain local nuances were main- 'technical intranet' was created, a support for R&D's project spaces, for the databases and the models necessary for tained, however, so Eurocoustic, in France, Orsil in the Czech Republic or Haniso in Korea kept their names, but used the yellow and the 'O' which linked them to the family. factory management. As a real tool, giving structure to the Insulation branch, this 'Isoline' was extended little by little to all the company's functions. Common validation methods Nowadays, the Isover world brand is an asset which must be protected and above all brought to the attention of were also defined, so as not to launch into projects with no commercial or industrial outlets. The Isover federating logo. 158 159 GB 138-185-STG-7-05 2/09/08 9:48 Page 160 THE TEL PUSHES BACK ITS LIMITS AGAIN The engineers had not always given up the idea of producing fibers from materials which could resist very high temperatures. After 10 years of research, the new generation of glass wool, ULTIMATE, launched in 2004, has been a success perhaps because it was the TEL, improved once again. The spinner, with the burners and the blowing ring, is the most important component in the TEL process. It is what determines, to a large extent, the capacity of the process and the fiber quality. Therefore the spinner has been the subject of most of the development efforts. The increase in production materialized in 1983, with the appearance of an 800 mm spinner which allowed the production of more than 30 tons per day per spinner. The TEL was therefore 'unbeatable' for manufacturing glass wool intended for building insulation. However, an important market was not being serviced by its products: high temperature applications, an area "reserved" for stone wool. In 1986, the technical management of the insulation branch asked the CRIR if fibers could be produced from stone compositions using the TEL process. It was essentially a question of finding a super-alloy, heat-resistant enough to make the spinner. This was the beginning of the THT project, standing for 'TEL High Temperature'. Spinner definition, choice and patenting of the suitable fireproof glass composition, burner improvement, no stone was left unturned. Result: products could be obtained which were more heat-resistant than the glass wool, and as strong mechanically or stronger than stone wool, but as light as glass wool. The advantages for insulation of industrial installations, or protection against fire were obvious. 160 GB 138-185-STG-7-05 2/09/08 9:48 Page 162 The ULTIMATE project was launched. It ended in 2004. The ULTIMATE glass wool showed excellent performance in high temperatures, which predisposed it to all fire-resistant applications. It offered fire-resistance during 30, 60, 120 minutes or even more, and resisted at 1000°C. It was also adapted to applications for which an operating temperature between 500 and 700°C was required. It was an excellent thermal and acoustic insulator, flexible, compressible and above all…half the weight of stone wool. This was an important 'detail' for one of its chosen markets: ship insulation, where every ton saved resulted in fuel economies. Apart from the technical insulation of ships and industrial installations, ULTIMATE was also suitable for the protection of buildings against fire. Industrial production started up in 2003 at the German Lübz factory, and ULTIMATE quickly attracted attention.The product received the ISO 2004 prize for innovation at the Wiesbaden fair in Germany, in March 2004. The first major commercial endorsement came in 2006: most of the fire protection at the Munich Allianz stadium (where the football world cup was held) was manufactured in ULTIMATE by Saint-Gobain Isover G+H. Benchmarks in the marine field started to appear in Germany, such as the 'Norwegian Jewel' in the Meyer Werft shipyard, then in other European countries. Moreover, pilot production of ULTIMATE pipe sections began in January 2006 at the Bergisch Gladbach factory. This was again a market success, immediately rewarded by the prize for the best ISO 2006 product, at Wiesbaden. Industrial investment at Bergish was decided at the beginning of 2007, for production of pipe sections exclusively in ULTIMATE. In 2007, an ULTIMATE line will start up at Tarui, in Japan. Sloping ceiling with wooden framework, insulated with ULTIMATE. 162 2/09/08 9:48 Page 164 2 1. 2. Fire-doors and ventilation ducts insulated with ULTIMATE. 3. Insulation of industrial buildings requiring fire resistance. 1 3 ULTIMATE production line at Lübz, in Germany. 164 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES GB 138-185-STG-7-05 2/09/08 9:48 Page 166 NEW FRONTIERS Isover is always conquering new territories - in Russia, where it is building a factory, in the United States, where the market is expanding rapidly, but above all in the country-continents which are finally opening up in Asia: China and India, each of which has more than a billion inhabitants and immeasurable needs. In 1999, Peter Dachowski, director of the Insulation branch between 1996 and 2004, reaffirmed Isover's priority was development in the United States and Eastern Europe.Ten years after the fall of the Berlin Wall, Eastern Europe was still a territory to be conquered. In particular penetration of the Russian market was to be continued. In the 1990s, Isover was selling products there which were manufactured elsewhere, in Poland, Finland,and even in China.But a project appeared which took shape in 2002: to set up a production factory near Moscow. Isover Russia therefore bought an old prefabricated concrete factory in the town of Yegorievsk, and rebuilt it from top to bottom.The European Reconstruction and Development Bank participated in the project, conscious of its economic importance for the whole area.The Yegorievsk factory, which started up in 2003, is On the other side of the world, in the Far East, a countrycontinent had finally opened up: China. More than a billion inhabitants, a harsh climate in a large part of the country, and immeasurable insulation needs. But did a Chinese market exist? Accommodation was allocated by the State, which in addition supplied the heating and electricity free of charge. Under these conditions, demand for home insulation was non-existent. However, the country was developing very quickly, and it was important to get a foothold. So Isover created a joint venture in 1996, with a local partner, Beijing Fiberglass Reinforced Plastics Factory. Beijing Isover Glasswool Co. Ltd was aiming above all for the big official or technical buildings and the railways: each year more than two thousand wagons were built and insulated with glass wool manufactured in the Beijing factory. But this factory was condemned by Beijing's town planning policy for the 2008 Olympic Games. Isover therefore sold this unit to its old partner and at the beginning of 2004 bought another factory at Guan, about fifty kilometers south of Beijing. A second factory at YiXing, near Shanghai, was purchased soon afterwards.With a third site near Hong Kong, operated in partnership with CSR Bradford Insulation, its Australian licensee, Isover has set up a modest capacity unit which can be developed rapidly, when China wakes up to insulation. With a population comparable to that of China and an equally fast-growing economy, the other Asian giant is India.To tackle it, Isover returned to its 'traditional' license policy. The first agreements were signed with UP Twiga, a glass wool and glass tissue manufacturer, and Rockwool India, a stone wool manufacturer, in July 2005. As for the territories left by Isover on the world map, corresponding to a few emerging countries, they are conquered little by little, following the example of South Africa, where Isover is setting up in 2007, by acquiring its old licensee, which was bought in 1996 by OCF. now the second biggest glass wool production unit in Europe. The other country for expansion to the west: the United States. Sustained economic growth in the country was boosting the demand for new housing, and new laws affecting insulation were contributing to the development of the market. For its thirtieth anniversary, in 1998, CertainTeed Insulation Group launched an ambitious development plan. The biggest glass wool production line in the world was then launched in Kansas City, with an annual capacity of 90,000 tons! At the time, it was the biggest industrial investment that Saint-Gobain had ever made. Beijing international airport, China. 166 167 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES GB 138-185-STG-7-05 2/09/08 9:48 Page 168 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES GB 138-185-STG-7-05 1 2 3 1. Yegorievsk factory in Russia, aerial view. 2. 3. Production lines. 168 169 GB 138-185-STG-7-05 2/09/08 9:48 Page 170 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES ANSWERING A PLANETARY PROBLEM Global warming, a new oil crisis: at the beginning of the 21 st century, the need to reduce greenhouse gas emissions and the planetary consumption of non-renewable energies is becoming urgent. Building insulation is making a major contribution. Isover is involved in a battle which is both commercial and environmental. On 16 th March 1998, the Kyoto Protocol (Japan) was open to ratification. Most of the developed countries committed themselves to reducing their greenhouse gas emissions below their 1990 levels. After ratification by most of the signatories, with the notable exceptions of the United States and Australia, the agreement has been in force since 2005. All the climate specialists agree when they say it is urgent to do something. Additionally, since spring 2003, there has been a new upsurge in the price of oil.To take the example of Europe, the houses alone represents 40 percent of the total energy consumption and a quarter of the carbon dioxide emissions! As one can imagine, energy efficiency is the word of the day... In the last few years, from being an individual preoccupation, the stakes are now planetary. The figures are impressive. Energy losses from new buildings have been divided by four in thirty years, thanks to successive insulation regulations and standards. However, this only concerns recent constructions: the major part of the existing stock was built without insulation, or to out of date standards. In 2006, EURIMA, the European insulation manufacturers' association, published a study, according to which bringing the whole of the European Union's housing stock up to present standards would save 3.3 million barrels of oil each day. The 'Let's insulate the planet against CO2' cooperative campaign: 'Badly insulated buildings endanger the planet' 170 Advertising campaign in Scandinavia. 171 2/09/08 9:48 Page 172 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES GB 138-185-STG-7-05 LET'S INSULATE THE EARTH To limit the scale of the global warming and respect the Kyoto commitments, Europe must cut carbon dioxide emission per inhabitant by a factor of four before 2050. In 2003, in France, eight concerned industrialists, including four Saint-Gobain's companies Isover, Ecophon, Eurocoustic and Saint-Gobain Vitrage - launched the ‘Isolons la Terre contre le CO2’ (let's insulate the earth against CO2) cooperative, after a very simple observation: the current regulations, or those being prepared, will not be sufficient to achieve this aim. The cooperative suggested launching a national plan over forty-five years, providing for a 15 percent reduction in the energy consumption of new buildings every five years. Four hundred thousand dwellings would have to be renovated and brought up to standard every year, using materials as effective as those used in new buildings. Another idea: to display the energy consumption of buildings. All this obviously assumes there will be financial and tax incentives. France is not the only country concerned; the cooperative's lead has already been followed in Belgium (Isoterra) and the Netherlands (Spaar het Klimaat). On the technical level, 'Isolons la Terre' has joined forces with local organizations, technical centers and banks to launch the association Effinergie. Inspired by similar steps in Switzerland (Minergie) and in Austria-Germany (Passivhaus), the association wants to draw up a national building label and promote low energy consumption construction. The final aim is to reach a 'zero energy' building, which will produce as much energy as it consumes, or even a surplus. 'Let's insulate the planet against CO2' cooperative advertising campaign about the necessity of reducing greenhouse gas emissions from buildings. Translation: ‘When a car pollutes, we take it to the garage, but when 30 million buildings pollute, where do we go?’ 172 173 2/09/08 9:49 Page 174 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES GB 138-185-STG-7-05 By compressing the glass wool, Isover limits storage space requirements, reduces transport movements and the impact on the environment. Thus over a period of 50 years, the energy saved thanks to glass wool can represent more than 100 times that needed for its production. 175 2/09/08 9:49 Page 176 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES GB 138-185-STG-7-05 Glass wool is 100 percent recyclable. It is manufactured from sand and recycled glass (up to 80 percent cullet) and offers a very positive environmental balance sheet. It protects the environment, from the beginning to the end of its life cycle and gives more comfort and savings to the occupants of the buildings it insulates. 177 GB 138-185-STG-7-05 2/09/08 9:49 Page 178 Insulation can decrease energy consumption and the accompanying greenhouse gas emissions… while improving comfort inside the buildings. It is a rare situation, one where everyone can win. A co-operative of European industrialists has therefore launched various actions to develop regulations which are still too timid (see p.173 “Let's insulate the Earth”). Thus the European directive on the energy performance of buildings (2202/91/CE), which was published in December 2002 and which came into effect in January 2006, to take into account the Kyoto commitments, only concerns new buildings or the renovation of buildings of over a thousand square meters. As one can imagine, almost all private homes and small industrial and commercial premises are not covered, yet they represent 90 percent of the possible savings. Nor was it by chance that the 2005 edition of Batimat chose as its theme 'sustainable development'. For the occasion, Saint-Gobain built a stand called 'Aujourd'hui pour demain' (Today for tomorrow), based on rational use of energy and scarce resources, and concern for the comfort of everyone inside the buildings. The environment and all its aspects have given new themes to the work of the Group's research centers, as although use of current products can easily exceed the demands of the regulations, there is still a long way to go. For example, to find solutions for bringing old housing up to standard, insulation must be developed which is as effective as current 2 products, but thinner, as there is a lack of space. Respect for the environment also assumes a global view of a product's life, from the production of raw materials, to its recycling at the end of its life. On a world level, the question of building insulation will become even more crucial as countries like China and India quite legitimately want to catch up with the level of activity and comfort in the developed countries. That will inevitably imply a sharp increase in their energy consumption and greenhouse gas emissions. Once again, as during the oil crises in the 1970s, Isover is in phase with a global preoccupation and lucky enough to be selling a product which genuinely contributes to a solution. For Isover's teams, helping to fight global warming has become a real mission. 1. At Isover, safety is an absolute priority, applied by the teams all areaspar of the company. e et in appliquée les équipes dans tous les domaines de l'entreprise. 1 178 2. Swedish advertisement 'It's priceless'. 179 GB 138-185-STG-7-05 2/09/08 9:49 Page 180 Measurements show that hot water, household appliances and lighting represent just 25 percent of the average consumption of buildings in Europe. Heating alone represents 75 percent. This unbalanced distribution has a cause: poor insulation. Heat escapes to the exterior in winter, and the building does not remain cool in summer. Result: the energy needs are always higher. By improving the insulating envelope, energy losses can be limited and consumption therefore reduced. But we can do better and reach a reduction of 75 to 90 percent. How? By radically changing our approach to construction methods and using renewable energies. This is the concept of the 'Multi-Comfort House', launched by Isover. This is not about future construction, but existing dwellings which are 'in use' at this very moment everywhere in Europe. Thanks to a choice of very effective 'passive' components highly insulated windows, heat recovery systems, optimal thermal insulation - Saint-Gobain's 'MultiComfort House' could almost do without any active method of heating. Its main heat sources are the sun, the inhabitants, the household appliances, as well as the heat recovered from the stale air; renewable and inexhaustible energies from natural sources. Result: its energy consumption is particularly low; the 'Multi-Comfort Home' only consumes 1.5 liters of fuel per square meter, per year! By comparison, an old construction needs around 20 liters of fuel, while a new house, built in the traditional way needs from 6 to 10 liters. Thus a 'Multi-Comfort House' not only allows a spectacular reduction in household energy bills, but also ensures a greater level of comfort. The hermetically sealed envelope which surrounds the house protects the inhabitants against cold, heat and noise, while guaranteeing a pleasant interior climate all the year round. A controlled ventilation system ensures a constant supply of fresh air. The humidity level is stable, which solves the eternal humidity problems, and the temperature is homogenous in all rooms. Saint-Gobain's 'Multi-Comfort House', which can take any imaginable architectural shape, is a solution to the two big challenges of the 21st century: protecting the planet by limiting the damage to resources and the atmosphere, while improving the inhabitants' living conditions. An optimal interior climate thanks to an air circulation system. 180 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES THE ISOVER MULTI-COMFORT HOUSE IMPROVES ENERGY EFFICIENCY WeberHaus, Rheinau-Linx, Germany. 181 2/09/08 9:49 Page 182 CHAPTER 4 - - RECOVERY AND THE NEW CHALLENGES GB 138-185-STG-7-05 2 1 1. Proyer multi-comfort house, at Steyr, in Austria. 2. Multi-comfort house at Salzkammergut, in Austria. Architects: DI Hermann Haufmann. 3. Gymnasium Albstadt at Tübingen, in Germany. Architect: Prof. Schempp. 182 3 183 2/09/08 9:49 Page 184 CONCLUSION “ When Saint-Gobain launched itself into glass wool, Since its launch, half a century ago, this process has just before the Second World War, insulation was a dominated the others. It was well-designed at the out- “If we try to define an activity which corresponds perfectly to the Group's strategy, we come up with a description of insulation.” “When I joined the Group, the TEL immediately appeared to me as a major asset for Saint-Gobain. Our strategy concentrated on this exclusive process, and I think it has paid off.” ” Jean-Louis Beffa Chairman and Chief Executive Officer of the Saint-Gobain Group from 1986 to 2007 promising adventure. During the immediate post-war period, it was still a marginal activity within the Group, to the point where the glass makers in the traditional branches, considered to be 'nobler', made fun of it in a good-humored way. But thirty years after the war, insulation had become Saint-Gobain's most profitable business! Today, insulation is definitely at the heart of Saint-Gobain's strategy, and represents one of the driving forces behind the growth of the Construction Products Sector. In fact, the Insulation activity possesses all the required criteria for success: a technological lead, being in line with the new building regulations, and regional markets. Insulation is not applied in the same way or in the same constructions in Norway, in the United States, or in South Korea. The climate, the architectural traditions, the level of economic development and even culture in the wider sense of the term determine the particular needs of each country, which must be met by specific products. All the Insulation set, and has constantly evolved, as its latest development, ULTIMATE, shows. From the perfecting of the process to the design and distribution of adapted products, via the technical sales assistance for licensees, the story of the TEL process is also that of hundreds of men and women at Isover throughout the world.This book pays a tribute to them, by showing how they developed over the decades to follow the market closely while keeping the same creative fiber and taste for technological challenge. With a real technological lead, a constant flow of innovative products, establishments all over the world and a well-defined strategy, Isover has a lot going for it. But today, circumstances outside the Group are widening the development prospects of the Insulation activity. In fact, the successive oil crisis and the global warming have combined to encourage authorities to enact more and more demanding regulations concerning the performance of new or existing buildings. This is a time for saving ener- activity's establishments pay particular attention gy and protecting the Earth.Without a doubt, insuto this. In December 2005, the purchase of British lation has a very bright future. Plaster Board (BPB), the world's biggest plaster and plasterboard manufacturer, reinforced the Group's preeminence on the interior products market. Why has Saint-Gobain become the world leader in insulation in a few decades, despite having entered the fray after its main competitors? How can such progress be explained? All the players agree, the TEL has been at the center of this development. 184 185 CONCLUSION GB 138-185-STG-7-05 GB 186-192-STG-4-05 2/09/08 9:50 Page 186 We would like to thank here all the people who helped with the creation of this participatory and collective work. First of all, Jean Battigelli for his meticulous research and documentation, and his writting on the TEL and the Insulation activity. But also: Saint-Gobain Archives (Catherine Bigot, Didier Bondue, Nathalie Duarte, Hervé Mahoudeau, Jacky Robinet), Pascale Alix, Jean-Yves Aubé, Georges Bancon, Lucien Berthon, Bernard Bichot, Stéphane Cousin, Yves Darche, Francis Da Silva, Jacques Delrieux, Dominique Elineau, Jean-Paul Fauchez, Dr Hans Furtak, René Goutte, Virginie Gourc, Maurice Hamon, Tsutomu Kadowaki, Sorin Klarsfeld, Catherine Langlais, Jean-Pierre Leroy, Michel Monserand, Sigurd Natvig, Jean Noziere, Marc Olagne, Dominique Plantard, Jean-Claude Rias, Mark Sadoff, Daniel Sainte-Foy, Marc Sauvage, Raymond Villain... for their help, their testimonials and the light they shed on the TEL adventure. And of course, all the old and new associates, the retired people, the licensees, the customers and and the partners who every day create the Insulation activity story. 186 GB 186-192-STG-4-05 2/09/08 9:50 Page 188 Photo credit: All documents in this book come from Saint-Gobain iconographic and photographic library, except J.Piffaut (p.66-67). PRINTED IN MAY 2007 BY IMPRIMERIE KAPP IN ÉVREUX (27 - FRANCE) PHOTOENGRAVING: LA STATION GRAPHIQUE ISSUE NO.: 566 PRINTED IN FRANCE GB 186-192-STG-4-05 2/09/08 9:50 Page 190