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JAA Technical Guide - Jewellers Association of Australia
JAA Technical Guide This document is intended to set standards, and to give guidance to the industry on technical and other jewellery and related products. This Guide will also represent a reference document for the JAA Industry Code of Conduct. Acknowledgements American Gem Traders Association Anthony Smallwood Big Bead Little Bead Company (USA) CIBJO Blue Pearl Book Federation of the Swiss Watch Industry FH Gemmological Institute of America (GIA) Gemselect.com Japan Watch and Clock Association Ken Anania Mark McAskill Nash Pearls Najo Oblo Jewellery Opals Australia Opals Down Under Paspaley Peter Keep Peter Sherman Ronnie Bauer Correct at time of publishing: 6 June 2016 (final draft version 1) Page 2 of 73 Index 1. Materials a. Precious Metal i. Gold ii. Silver iii. Platinum iv. Rolled Gold v. Care of Gold and Silver Jewellery vi. Rhodium vii. Palladium b. Gemstones i. Gemstone Colour Groupings ii. Mohs Scale of Hardness iii. Diamonds 1. The Four C’s 2. Common Diamond Cuts 3. Synthetic, Man Made and Treated Diamonds 4. Laboratory Reports iv. Other Gemstones 1. Glass Filled Corundum’s and Other Treatments 2. Pearls 3. Opals 2. Jewellery and Watch Product Knowledge a. Types of Jewellery and Components b. Jewellery Production Methods c. CAD/CAM d. Parts of a Ring e. Types of Settings f. Types of Shanks g. Types of Chains h. Platings and Coatings i. Watches 3. Information for Jewellery Retailers a. Gemstone Specifications and Care Chart b. How to Use a Jewellers Loupe c. Finger Size Comparison Chart d. Repair Take in Procedure e. Refunds and Returns f. Lay By and Special Order Procedures g. Special Care Guide 4. Other Information a. Specific Gravity Chart b. Birthstones c. Anniversary stones d. Valuations and Insurance Page 3 of 73 1. MATERIALS a. Precious metals There are five metals in the precious metal group: 1. Gold: a yellow metal with chemical symbol Au 2. Silver: a white metal with chemical symbol Ag 3. Platinum: a bright white metal with chemical symbol Pt 4. Rhodium: a white metal with chemical symbol Rh 5. Palladium: a silver grey metal with chemical symbol Pd Note: Palladium, Rhodium and platinum are all part of a group of metals known as the Platinum Group (PMG) The group of five are also referred to as noble metals because of their ability to withstand chemical attack (corrosion and decolourisation). i. Gold Since ancient times gold has been highly valued as a metal for jewellery production due to its density and the fact that it is malleable (able to be easily beaten into a shape or flat sheet which is so thin that it becomes transparent) and ductile (able to be easily drawn into a long strand). Fine gold is resistant to corrosion and discolouration by all single acids but does dissolve in a mixture of nitric and hydrochloric acid called aqua regia. Fine gold is refined to a purity of 999.9 and in the carat system this purity is called 24 carat. Commonly used alloys of gold in Australia are 9ct and 18ct gold. 18 carat means that the alloy contains a ratio 18 fine gold to 6 parts of other metal. I.e. 18/24 gold and current production is stamped 750 (3/4=18/24) and means that the item will contain 750 parts out of a thousand of fine gold. 750 is called the standards mark. 9 carat contains 9 parts of fine gold out of 24 which is equivalent to 375 parts per thousand fine gold and 675 parts alloy. 375 is called the standards mark. Note: All fine gold is yellow but we can change the colour of a gold alloy by varying the alloy metals we add to the mix. We have learned that 18 carat must have 750 parts of fine gold. If an equal amount of silver and copper is used to make up the 250 parts of the alloy component the resultant 18 carat gold will have a yellow colour. Similarly if the proportion of the alloy material is rich in copper we will get a pink gold, sometimes referred to as a rose gold. 18 carat white gold alloys usually contain a percentage of palladium as well as silver. The 18 carat metal must have 750 parts fine gold, the addition of palladium (also a costly precious metal) results in an 18 carat white alloy that is more expensive than the yellow. As the amount of gold is lowered in the mixture, so the resultant alloy becomes more prone to discolouration. White gold jewellery products are often rhodium plated and it is important to advise customers that over time this will wear away and the item will need to be replated. Page 4 of 73 Lower Caratage gold alloys contain more metals that are oxidisable. Silver for example reacts to Sulphur and copper with ammonia. These oxidising substances are contained in sweat and in certain skin creams, soaps, perfumes and fabrics. Caratage International symbol Parts of fine gold Other metals 24 22 18 14 9 Nil 2 parts of alloy 6 parts of alloy 10 parts of alloy 15 parts of alloy (parts per 1000) 24 22 18 14 9 1000 916 750 585 375 Gold plating is an electro galvanic process whereby ions of metal in a solution are deposited on the item being plated. The item to be coated is suspended in the solution at the cathode and a gold anode is suspended in the solution. The anode is depleted as it transfers metal through the solution to the article being plated. By controlling the voltage and knowing the surface area of the item being plated and monitoring the amperage the amount of metal being deposited can be calculated. The thickness of the deposit is expressed in microns. Items that are covered by less than the Australian standard for gold plated items should not be referred to as gold plated. ii. Silver Silver is a member of the group of precious metals that make up the noble metals and like gold, is also very malleable and ductile but less so than gold. Fine silver is a very soft metal and is much more abundant than gold. Silver is less dense than gold and this means that the same article made in silver will be lighter than its gold equivalent. Silver will tarnish if it comes into contact with sulphur, which is often present in the atmosphere in the form of sulphur dioxide. Articles of silver need to be regularly cleaned to be kept looking their best. iii. Platinum Platinum is a very dense Noble metal which is white in colour. It has a very high resistance to chemical attack and mechanical scratching. Platinum has gained in popularity as more equipment and techniques are developed to ease its use as a jewellery metal of choice. It has a very high melting point. Due to its high specific gravity, items of platinum are much heavier than the equivalent gold piece. The Australian standard for platinum is 950 parts per 1000 for the platinum alloy to be stamped Pt. CIBJO recognises the Pt mark on product over 850 parts per 1000. iv. Rolled Gold Rolled gold is a mechanical application of gold onto a base metal by means of pressure usually through a roller but may also be done with a press. The quality standard of rolled gold is usually expressed as a percentage of the total mass of the item. You may see a mark that says 1/10th 9ct gold or 1/10th 375 gold Ion plating is a modern process which deposits a very low level of metal on an article. This metal thickness is well below the Australian standard for gold plating but cannot be referred to as plating because the process is not carried out in a solution. Page 5 of 73 The covering is durable as after coating with precious metal, a ceramic coating is applied which is hard wearing considering its thickness. Plating and coating The quality of a silver plated item is measured by the micron thickness of the silver coating. The plating process is similar to gold but with the appropriate silver anode and solution. Look out for EPNS. This stands for ‘electroplated Nickle silver’ and only the outer plating is silver on a base metal blank. v. Care of gold and silver jewellery Be conscious of the fact that many commercial gold and silver ‘dip cleaners’ are corrosive and strip a layer of metal of the item being cleaned. It is important to warn customers not to use the solutions on silver plated articles as the silver coating will be removed. Note that after using a dip cleaning process the item being cleaned must be thoroughly washed in running water. Dry with a soft cloth. Customers should be told that placing each item into a separate bag before placing in a draw or jewellery box will prolong the life of their jewellery as damage occurs when items rub against each other. It is also a good idea to take your jewellery off before going to bed at night – if it’s on wear will still occur. Of course delicate items should be removed before doing manual chores such as gardening, exercising or cleaning. v. Rhodium Chemical symbol Rh. Rhodium is a very hard silvery metal with a very high lustre which is highly reflective. Its jewellery uses are mainly limited to that of a coating material (usually electronically plated) to provide a tarnish resistant layer on silver items and to improve the colour of white gold jewellery. Its industrial uses include as a component of thermocouples and as a coating where corrosion resistance is required. It also finds use in catalytic converters. vi. Palladium Chemical symbol Pd, is a lustrous silver grey white metal which has the lowest melding point of the platinum group of metals. It is also the least dense. The main use of palladium is as an industrial metal which is widely used in catalytic converters. A more recent industrial use has been in fuel cells which combine hydrogen and oxygen to produce electricity with heat and water a by-product. Palladium is known to be relatively brittle and may discolour if heated beyond 400 degree centigrade. During the Second World War palladium was used for the production of white gold wedding bands as the allied countries had declared platinum (which at the time was used for the production of wave guides for radar), a strategic material was not available to the jewellery industry. During the period 1960 to 2000 palladium’s jewellery use was manly confined to that of an alloy for the production of good quality non-allergenic white golds. Page 6 of 73 In the early years of the new millennium production difficulties and problems associated with the casting of Palladium were resolved and as a result of steep price rises in the price of Platinum, palladium was used as a white metal in its own right. It should be noted that some European hand manufacturers had been continually producing Palladium jewellery through the 70’s and 80’s but production was confined to individual pieces. In 2010 the British assay office introduced a palladium mark for the purity grades: 500, 950 and 999 parts per thousand. b. Gemstones i. Gemstone Colour Groupings Black Jet Onyx Tahitian pearls Tourmaline Blue Agate – Blue lace Aquamarine Diamond Iolite Lapis Lazuli Sapphire Spinel Tanzanite Topaz Tourmaline Turquoise Zircon Purple/Violet Amethyst Iolite Jade – Jadeite Kunzite Sapphire Tanzanite Tourmaline Red Alexandrite Carnelian Coral Diamond Garnet Jade – Jadeite Rhodolite garnet Ruby Rubelite Tourmaline Spinel Topaz Brown Diamond Smokey Quartz Topaz Zircon Yellow/Orange Amber Apatite Citrine Diamond Fire opal Golden topaz Sapphire Spessatine Garnet Tigers Eye Tourmaline Zircon Green Alexandrite Apatite Chrome diopside Chrysophase Emerald Jade – Jadeite Jade – Nephrite Malachite Peridot Sapphire Turquoise Tourmaline Tsavorite garnet Pink Diamond Kunzite Morganite Rose quartz Sapphire Spinel Tourmaline White/Colourless Diamond Jade – Nephrite Opal Pearls Sapphire Zircon ii. Diamonds A diamond is composed of crystallised carbon and is the hardest natural substance known to man. Fifty-eight times harder than anything else in nature, in fact. Only Mother Nature can make a natural diamond. A natural diamond is identified using only the single word, "diamond". Page 7 of 73 1. The Four C’s The 4 C’s are considered the global language of diamond quality. The four C’s helps determine the value of each individual diamond. These are the measures by which diamonds graders assess the variations in these stunning natural wonders, as each natural diamond boasts its own unique characteristics. Once the rough diamonds are mined, the artisan who creates the finished gem plans their cut accordingly, producing a masterpiece with a unique size, shape, clarity, number of facets, and scintillation. Cut Cut (proportions, symmetry, and polish) is a measure of how a diamond’s facets interact with light. Together, these measures rate the cut facets from “Excellent” to “Poor”, regardless of shape. Jewellers often use the term “cut” to describe the shape of a diamond, as well as the quality of workmanship. A round shape is a favourite for engagement rings. Princess, emerald, pear, marquise and ovals are among the many other shapes available. Colour The less colour, the higher the grade. Even the slightest hint can make a dramatic difference in value. Diamonds are graded for colour on a scale from "D" or colourless, to "Z" or dark yellow. A chemically pure and structurally perfect diamond is completely transparent with no hue or colour. The colour of the diamond may be affected by chemical impurities and structural defects in the crystal lattice. A "D" colour diamond is considered colourless–and the standard for a "white" diamond. Deeper tones, up to H, are often considered "near colourless". Generally, the hue and intensity of a diamonds colouration can enhance or detract from its value. Diamonds with deep yellow, pink or other significant colour have become especially prized and are extremely rare. Page 8 of 73 Clarity Flaws inside a diamond are commonly referred to as inclusions. Clarity grades assess the number, size, type, position and visibility of inclusions and blemishes. These imperfections may be crystals of a foreign material, another diamond crystal, or structural imperfections (tiny cracks that can appear whitish or cloudy). Diamonds are graded from "flawless" (FL grade) to grades of VVS, VS, SI and "included" (I or P grade). Carat The carat weight measures the mass or size of a diamond. One carat is defined as exactly 200 milligrams. The value of a diamond increases exponentially in relation to carat weight, since diamonds of larger sizes in gem qualities are rare. 2. Common Diamond Cuts A round shape is a favourite for engagement rings. Princess, emerald, pear, marquise and ovals are among the many other shapes available. Page 9 of 73 3. Synthetic, Man Made & Treated Diamonds Scientific and technological advances in the jewellery industry have made it possible for synthetic diamonds to be manufactured and laboratory-created (made by man). Synthetic diamonds also known as Laboratory (LAB) Created Diamonds. Synthetic diamonds are not imitation diamonds. Synthetic means the product is made by man, in a laboratory, using the same chemical substance (pure carbon) found in natural diamonds. A synthetic diamond has the same physical, chemical and optical properties as a natural diamond. It's cut like a natural diamond but a synthetic diamond is created by man, not by Mother Nature. Synthetic/Lab Created/Man made diamonds is less expensive than their natural counterparts. There are many varieties of diamond look-alikes or diamond imitations. These products are not diamonds. If you decide to buy a diamond simulant or a stone that closely resembles a natural diamond, but the stone is not a diamond, be sure you know what you are buying. Simulant, diamond simulant or simulated stones are imitations. A simulant or simulated stone is not a diamond but rather an imitation man-made product that resembles a diamond. A diamond imitation should not be confused with a synthetic diamond which possesses essentially the same physical, chemical and optical properties of a natural diamond. An imitation or diamond simulant can be made of glass, plastic or some other compound such as zirconia oxide, better known as CZ or cubic zirconia. Simulated/imitation stones are made by man and are usually very inexpensive to manufacture. Be aware that the selling of imitation diamonds may use names that confuse consumers into believing that they are natural diamonds and not imitations. It is misleading to advertise a diamond simulant or diamond alternative, without the appropriate terminology or declarations. For example, ‘Royal Diamond’ or ‘The same as a real diamond’ or ‘Just like a real diamond’. Only a natural diamond can be identified using only the word "diamond", no other description is needed. Natural diamonds are different to synthetic diamonds and diamond simulants such as CZ. Treatments Treatment or enhancements to natural diamonds with the goal of improving the diamond's overall appearance are common. These treatments are acceptable and have their place in the jewellery world, provided the consumer understands if a particular diamond was treated and exactly what enhancement/treatment was performed on the diamond and why. Treated diamonds are a way for consumers to own lovely jewellery at affordable prices. Treatment or enhancements to natural diamonds with the goal of improving the diamond's overall appearance are common. These treatments are acceptable and have their place in the jewellery industry, provided the consumer understands whether a particular diamond was treated and exactly what enhancement/treatment was performed on the diamond and why. Some diamond treatments are less durable that others, meaning that the appearance of the diamond may change over time. Treated diamonds are a way for consumers to own lovely jewellery at affordable prices. Page 10 of 73 Laser drilling This treatment is done to reduce or eliminate dark "flaws" (inclusions) in natural diamonds. A laser beam is used to drill a narrow path to the flaw. This path looks like a fine white thread starting at the surface travelling to the inclusion. The effects of the laser treatment are permanent and the diamond does not need special care. A laser-drilled diamond is an affordable alternative to paying more for a natural untreated diamond. Fracture filling Fracture filling is a treatment to improve the appearance of a natural diamond. Surface cavities or fractures which reach or break the surface of a diamond, are filled with a substance (often times a type of epoxy or resin). This treatment does not remove the cavities or fractures but makes them appear less visible. Fracture filling is not a permanent treatment since the heat of a jeweller's torch as well as ultrasonic cleaning can affect the filling used in the treatment. For example: the filling sometimes dries and therefore the cavities or fractures might reappear. Selling a fracture filled diamond requires the seller to fully disclose and explain the treatment, and any special care requirements. Selling a fracture filled, treated diamond without proper disclosure is not an acceptable jewellery trade practice. Additionally, heat must never be applied to a treated diamond; it should always be removed from the setting before any repair work is completed. A customer must advise their jeweller if a stone is treated so that any work being completed on a piece of jewellery is adequately handled. Failure to advise the jeweller may result in damage to the diamond and further costs for the customer, as a jeweller will not be liable if any treatments were not declared. Moissanite Moissanite, (chemical compositions: silicon carbide), is a laboratory-created, near-colourless jewel. While Moissanite closely looks like a natural diamond, it is not a diamond, synthetic diamond, brand of diamond nor is it marketed as a diamond substitute. Rather moissanite is marketed as a unique jewel. However, some people do purchase it as a diamond alternative. 4. Laboratory Reports Diamond grading is a subjective task due to the non-standardised nature of diamonds. Whilst diamond grading is subjective in nature, there are recognised standardised methodologies in place internationally to reduce subjectivity. Grading is intended to quantitatively and qualitatively describe a diamond’s unique characteristics so that any diamond can be identified based on its own diamond grading report. Grading can only be carried out before a diamond is set. It does not give any value for a diamond, however it is the main tool used to determine the value of a diamond in the marketplace. The JAA recognises independent grading laboratories that work to internationally recognised and respected grading rules and guidelines. Any diamond grading laboratory needs to be independent of the diamond selling process, thereby transparent and free of conflict of interest. The JAA monitors the international diamond grading "landscape" and recognises the following diamond grading laboratories*: 1. American Gem Society Laboratories (AGS) 2. Australian Diamond Grading Laboratory (ADGL) Page 11 of 73 3. Diamond Certification Laboratory of Australia (DCLA) 4. Gem Studies Laboratory (GSL) 5. Gemmological Institute of America (GIA) 6. HRD Antwerp (HRD) 7. Independent Gemmological Laboratory (IGL) 8. International Gemological Institute (IGI) 9. International Institute of Diamond Grading & Research (IIDGR) 10. Scientific Gem Testing Laboratories (Auscert) * Due to ongoing monitoring of Diamond Grading laboratories this list is subject to change over time and will be updated as a nd when required. JAA recognition is based on the information currently available however it advises consumers to always do their own research. A laboratory is only deemed independent if it is not in any way involved in the sale of diamonds. Last updated 19 January 2015 What does a grading report include? A grading report should include: A statement that the diamond is a natural diamond A report number The accurate carat weight The shape and measurements The colour grade The clarity grade The cut grade (not applicable on fancy shapes) The polish grade The symmetry grade The fluorescence type. The plot to show where inclusions are located and the type of inclusion Any applicable comments Laser Inscription Most JAA recognised laboratories will offer laser inscription services. Laser inscription is minute writing, not visible to the naked eye, applied on the girdle of the diamond. The main purpose is to be able to identify the diamond. This will ensure that the diamond matches the report and will minimise the possibility of your diamond ever being switched. The safest laser is a cold laser system which is guaranteed not to damage the diamond and which has no effect on the purity. iii. Other Gemstones 1. Glass Filled Corundum’s & Other Treatments Enhancement of gemstones refers to treatments or processes that improve the appearance, durability or value of a gemstone. Today many gemstones have been enhanced by countless methods to improve the natural properties of gemstones. Some treatments and processes are fairly simple where others are more complex. Some gemstone enhancements are less durable that others, meaning that the appearance of the gem may change over time. Additionally, heat must never be applied to a treated stone; it should always be removed from the setting before any repair work is completed. A customer must advise their jeweller if a stone is treated so that any work being completed on a piece Page 12 of 73 of jewellery is adequately handled. Failure to advise the jeweller may result in damage to the gemstone and further costs for a customer, as a jeweller may not be liable if any treatments were not declared. Types of enhancements are, but not limited to, bleaching, coating, dyeing, filling, flux heating, heating, impregnation, lasering, oil/resin infusion, irradiation and waxing/oiling. Caution must be exercised when cleaning or using ultrasonic cleaners. Excessive cleaning and the use of ultrasonics may affect the treatment that has been applied to certain gemstones. For example, most emeralds are oil or resin impregnated and the use of ultrasonics may remove this treatment or expand existing fractures. Organic porous gemstones such as opals and pearls should under no circumstances be exposed to ultrasonics. If unsure if a gemstone can be cleaned in an ultrasonic, do not use an ultrasonic. Gemstones such as opal, pearl, coral, amber and turquoise are heat sensitive. It is advisable not to leave them sitting in hot sunlight, near heaters or in hot cars. Once an opal begins to craze, it is irreversible. Craze occurs when the water in opal dries too quickly. 2. Pearls Natural Pearls Natural pearls are defined as all types of pearls formed by chance in various saltwater and freshwater molluscs from a grain of sand or tiny speck of coral, without any human intervention - there is no implanted nucleus. Historically, all pearls discovered were natural pearls; however the ocean’s natural supply of pearls was seriously depleted around a century ago. Today the occurrence of natural pearls is very rare. They are often traded at international auctions as investment pieces. Cultured Pearls Cultured pearls are formed when humans intentionally introduce an irritant into the oyster. Most of today’s pearls are cultured pearls. To produce a cultured pearl a highly skilled technician inserts foreign matter into a healthy, mature oyster or mussel. To protect itself from this irritant, the oyster produces cells that secrete multiple layers of nacre that eventually coat the foreign matter to become the cultured pearl. After the insertion, the oyster is placed in wire mesh baskets for protection and hung from floating rafts in the sea. Usually after one to three years beneath the sea the pearls are then harvested. The shape and size of the resulting pearls depends, to a large degree, on the shape and size of their implanted irritant. Harvesting valuable pearls requires luck as well as skill. The number of gem quality or 'perfect' pearls harvested each year is still fairly low. Today • • • there are three main groups of cultured pearls: Akoya pearls White, Black and Gold South Sea pearls Freshwater pearls It should be noted that Keshi Pearls are a by-product which can arise from any of the above groups. Page 13 of 73 Cultured Pearl Chart Akoya Pearls The term Akoya refers to nucleated saltwater pearls cultivated in the Akoya Pinctada fucata (martensii) oyster. The first pearls were cultured in Japan, where the techniques for growing pearls were developed about a hundred years ago. Only one pearl grows in the Akoya oyster and the period of cultivation is between eight months and two years. The Akoya shell is no bigger than the palm of a hand and is found mainly in Japan, Korea and China. Its pearls generally grow from 2mm to 9mm, or very rarely 10mm. The majority of Akoya pearls harvested are round in shape. However, other shapes like baroque, button, oval, drop etc. can also be found. White South Sea Pearls White South Sea Pearls refers to pearls grown in the southern ocean, mainly off the coast of Western Australia, Indonesia, the Philippines and Myanmar. They are grown in the Pinctada Maxima oyster which is the biggest oyster of all species (size 20-30cm). There are the “yellow-lip” (mainly Philippines, Indonesia) and the “silver-lip” (mainly Australia and some parts of Indonesia) Pinctada Maxima oysters which all produce a slightly different colour of pearl. Pearls produced range in size from 9 to 20mm (occasionally bigger). The largest cultured South Sea pearl is 24mm. Most of the harvested pearls will be in different shapes such as oval, drop, button and baroque. Page 14 of 73 White South Sea pearls come in a variety of colours, ranging from white through to silver blue, and from cream to golden colours. The rarest and expensive colours are silver white, white rose and dark gold. The other colours like cream, yellow, blue, grey and champagne are more affordable. Note: There are now some Freshwater pearls that also come in larger sizes, i.e. approx. 9mm – 15mm. Black South Sea Pearls Black South Sea Pearls are cultured using a species of oyster called Pinctada Margaritifera or "black lip" oyster. This variety of mollusc is indigenous to the lagoons and the atolls of French Polynesia and the surrounding South Pacific area – Tahiti, Cook and Fijian Islands. They are also grown in small quantities off the Western Australian coast – Shark Bay and Abrohos Island. Tahitian oysters love the pristine lagoon waters, where temperatures range between 24-29 degrees. As with other South Sea pearls, the Tahitian pearl ranges in size from 8-16mm (sometimes bigger). Colours of Tahitian pearls range from gold through greens to aubergine or purple, and to quite a dark black. Generally, the darker the pearl, the more valuable it is. True peacock black pearls are typically expensive. Shapes come in round (only a limited percentage), off round, oval, drop, button and baroque and circle. Gold Southsea Pearls Gold South Sea Pearls are cultured using a species of oyster called Pinctada Maxima, a silver or golden lipped pearl oyster. These pearls come from the waters off Australia, Indonesia, Myanmar and the Philippine’s. They are also grown in small quantities off Vietnam, China and Papua New Guinea. Freshwater Pearls Freshwater pearls grow in a mussel species (Hyriopsis Schlegeli) and/or (Hyriopsis cumingii). The mussels are not rare and are mainly found in rivers, lakes and ponds in China and Japan, and also in Europe, Russia and America. They are propagated in water tanks and ponds. Page 15 of 73 Freshwater pearls have an endless variety of shapes, sizes and colours from lilac to purple, orange, brown, rose, grey, gold, champagne and white. It is simply a question of taste. Keshi Pearls The word 'Keshi' means 'poppy seed' in Japanese and these pearls are also sometimes referred to as seed pearls. It is an old Japanese trade name for small saltwater natural or non-beaded cultured pearl that is essentially baroque in shape. There is considerable controversy as to the classification of whether Keshi pearls are natural pearls or cultured pearls. It is impossible to determine the difference in the laboratory. As a basic rule, if the oyster has been seeded by human intervention and an additional pearl (by-product) is created through the provocation of any substance, the pearl is considered to be cultured and is therefore called a “Keshi” pearl and is 100% nacre. They are generally small in size and their shapes vary widely. Keshi come in a wide variety of colours and tend to have a high lustre. Most common today are the South Sea and Tahitian Keshi pearls. Biwa Cultured Pearls A freshwater beaded or noon=beaded cultured pearl produced in Lake Biwa, Japan using the freshwater bivalve mollusc Hyriopsis Schlegeli. Imitation Pearls Imitation or simulated pearls are entirely man made from a variety of materials. They are mostly manufactured from beads of glass, plastic, or polished shells that are coated with a varnish that traditionally was made from finely ground fish scales but more recently from reconstructed mother of pearl. Pearl Quality Unlike gemstones such as diamonds, there is not a universal international standard of quality used when judging the quality of pearls. Various systems have been developed for grading pearls. Beauty is considered the most important criteria when selecting a pearl. There are however, certain grading characteristics for judging the quality of pearls which include: colour, lustre, shape, size, and surface finish. For all the above criteria that determine the value of a pearl, there is one more important factor that is frequently omitted: the matching of pearls. There is a saying that “no two pearls are alike”. It is therefore extremely difficult to find a perfectly matched pair of pearls or matched pearls for a necklace or strand. Helpful tips for judging the quality of pearl strands: • Examine the strands on a flat white surface, e.g. white cloth, board or paper. Lustre and colour are hard to judge when pearls are suspended in the air or lying against a dark surface. • Try to examine the pearls directly beneath a bare light instead of away from the light source. This helps to bring out the lustre and true colour of the pearls. • Look for the darkest and brightest areas of the pearls in a strand. Then compare the contrast between the two. The lower the contrast and the milkier the appearance of the pearl, the lower the lustre. • Examine the reflection of light on the pearls. Usually, the less sharp and intense the reflection is, the lower the lustre will be. Sometimes, however, a lack of sharpness in reflections is due to surface flaws rather than the overall lustre. • Compare the lustre, colour and blemishes of individual pearls in a strand. The quality of a strand is determined by its overall appearance, not just by one pearl. Page 16 of 73 • • • Roll the pearls slightly to see their entire surface. The lustre, colour and surface imperfections not only vary from pearl to pearl, but also vary on each individual pearl. Check the regularity of size and shape (especially in graduated strands). If possible, lay the pearls alongside other strands and compare lustre and colour. A strand will look better when viewed next to lower quality strands rather than next to those of higher quality strands. Required care of pearls It is possible for pearls to retain their lustre for hundreds of years if the generations of owners are educated in their required care. Taking proper care of pearls is not difficult. It is helpful to remember that these gems are organic by nature, grown in water from the living cells of a living creature. Like the oysters which formed them, they require moisture from salt or fresh water. Never expose pearls to chlorinated water and be aware that pearls are prone to damage from pollution, heat and injury. How to care for pearls • • • • • • Store pearls separately from other pieces of jewellery in a cloth bag or jewellery pouch. Wrapping pearls in slightly damp linen will help to prevent them from dehydrating in low-humidity atmospheres which have often been centrally heated. Before putting pearl jewellery on, apply cosmetics, perfume and spray products first. Try to avoid wearing pearls if you are wearing sunscreen lotion or insect repellent as the chemicals in these products can damage the pearl. Clean spills immediately if pearls come in contact with food acids. Use a soft cloth moistened with water to wipe them down and then dry with another clean soft cloth. Always wipe pearls after wear, using a clean soft cloth. Have pearls re-strung regularly for the sake of the pearls as well as to avoid a broken string. Make-up, powder and skin oils will form a soft, gluey paste on the string, deteriorating both the silk and the pearls. Replace individual pearls based on the advice of a competent and experienced pearl stringer. Cultured pearls which always lie against the neck when worn will absorb acid from the skin and eventually lose lustre as well as their spherical shape. Things to avoid when wearing pearls • • • • • • • • • Perspiration and acids Make-up, skin creams, perfume, hairspray, sunscreen, insect repellent, talcum powder Dust and grit Soap and detergent Scratches Chlorinated water in shower or pool Safety deposit boxes in bank vaults over a long period of time Dehydration from being wrapped in cotton wool or from exposure to light and heat, especially spotlights in shop windows and showcases The kitchen with acidic ingredients and the high heat used in cooking. There are five physical characteristics by which all fine pearls are graded. Lustre/Orient Lustre is the most important characteristic of a pearl. Of all precious gems, only pearls have lustre and it is this that gives pearls their singular beauty. Orient which is an optical phenomenon caused by the interference and diffraction of light from within the surface of some nacreous pearls. Page 17 of 73 A pearl consists of countless layers of pearlescent organic material known as ‘nacre’. Lustre arises from the interaction of light with these layers of nacre. The refraction of this light produces delicate shades of iridescent colours which is referred to as the Orient. The lustre of Australian South Sea pearls is attributable to the superlative quality and thickness of the nacre produced by the wild Pinctada maxima oyster. Together, these factors result in lustre of incomparable radiance and iridescence. A pearl with deep and radiant natural lustre is desirable and valuable whatever its shape, colour or size and despite any surface imperfections. Natural lustre is everlasting and should not be confused with the superficial metallic shine of treated pearls that may diminish over time. There are four categories of lustre: Excellent – reflections are bright, sharp and distinct. Good – reflections are bright but not sharp and they are slightly hazy around the edges. Fair – reflections are weak, hazy and/or blurred Poor – reflections are dim and diffused. Surface Blemishes A pearl with a flawless surface is exceptionally rare. As living organisms produce pearls, nearly all pearls have minor bumps, pits or uneven colour imperfections, known as blemishes. A pearl’s quality is influenced by the number and size of imperfections and their degree of visibility. Clearly noticeable imperfections compromise a pearl’s allure and value. Some of these imperfections may include, cracks, patches of missing nacre, prominent flaws and obvious discolouration. Blemishes come in four categories: Clean Lightly blemished Moderately blemished Heavily blemished Page 18 of 73 Shape A pearl’s shape does not affect its quality. However, the demand for particular shapes does have a bearing on value. Round is considered the most valuable shape for a pearl, however teardrop and oval are also especially high in demand. Some other shapes, such as circle and baroque, are no less beautiful and have an appealing individuality. A circle pearl features one or more grooved rings around the pearl. Baroque pearls are irregular in shape. These organic, free-form shapes can be very beautiful and lend themselves to exciting and creative jewellery designs. Pearls are classified into nine shape categories: Round – perfectly spherical and highly desirable. Near round – Slightly flattened or elongated rather than being a perfect sphere. Semi-round – less round but still have an overall round shape. Oval – narrower at the ends than they are in the centre. Button – flattened to some degree making them resemble a button or perhaps a disk. Often used in earrings. Drop – are pear or teardrop shaped and can also be triangular. These pearls make attractive earrings or pendants. Circle (ringed) – Has one or more parallel grooves around the circumference of the pearl. Can be present on drops, ovals, near round, semi round, triangles and buttons. Baroque – a pearl which is both non-symmetrical and irregular in shape. It can be purely abstract in shape or can resemble a cross, stick or some other shape. Semi-baroque – are slightly irregular in their shape. For example a pearl that may be considered an oval or button shape but which is not symmetrical in nature. Colour Australian South Sea pearls are available in a wide array of natural colours mirroring the overtones of the Pinctada maxima shell in which they form. Page 19 of 73 Colour is a personal choice but the popularity of a particular colour can influence a pearl’s value. Australian South Sea pearls are predominantly white or silver and may have multi-hued overtones including pink, blue and green. The pearls hue can be broken down in to three categories: Hue – the colours first impression Tone – its lightness or darkness Saturation – its strength or intensity. A pearls colour can have along with the Hue three main characteristics: Body colour – overall body colour of the pearl Overtone – which is one or more translucent colours that appear over a pearl’s body colour and Orient-iridescent – which are rainbow colours shimmering on or just below the pearls surface. Size Australian South Sea pearls are the largest of all pearls, typically ranging from 11 to 16mm in diameter. Larger sizes up to 20mm and beyond are occasionally found and such pearls are highly prized. Trade names for Natural pearls. Trade term Colour Treatment type Frequency Conch Pearl Abalone Pearl All colours All colours Blister pearl All colours Saltwater pearl All colours Oiled Oiled Filled Oiled Dyed Filled Oiled Dyed Rarely Rarely Occasionally Rarely Rarely Commonly Rarely Rarely Page 20 of 73 Blister pearl Freshwater pearl Freshwater Blister Pearl White, pink to purple White, pink to purple All colours Grey to black White, pink to purple All colours All colours Grey to black Filled Oiled Oiled Dyed Irradiated Oiled Dyed Filled Irradiated Rarely Rarely Rarely Rarely Rarely Rarely Rarely Rarely Rarely Trade names for Cultured pearls Trade term Colour Treatment type Frequency Mabe Pearl White All colours White White All colours Grey to black White to yellow and Grey to black Bleached Dyed Coated Bleached Dyed Irradiated Dyed Commonly Commonly Rarely Commonly Commonly Occasionally Rarely All colours Bleached Commonly (Pinctada fucata) White Bleach Uncommon (Pinctada Maxima) Rarely (Pinctada Margaritifera) Freshwater Cultured Pearl (beaded) Freshwater Cultured Pearl (non-beaded) Keshi Saltwater Cultured Pearl (nonbeaded) Saltwater Cultured pearl (beaded) Akoya Cultured Pearl South Sea Cultured Pearl Tahitian Cultured Pearl Dyed All colours Grey to black Dyed Coated Filled Oiled Irradiated Occasionally (Pinctada fucata) Occasionally (Pinctada fucata) Rarely Rarely Occasionally Occasionally (Pinctada fucata) 3. Opals Precious opal is a gemstone which shows a special phenomenon known as Play-of-Colour (POC). This play-of-colour is revealed as an arrangement of small colour patches or colour grains that are arranged and distributed over the surface of the gemstone and which change in colour when the gemstone is moved or rotated. Page 21 of 73 The colours seen are the same colours as seen in a rainbow and are called “spectral colours” due to the nature of how the colours are produced in the gemstone. The Play-of-colour originates from the interaction of light with an amazing three dimensional array of tiny silica spheres which cause the diffraction of white light into spectral colours. This structure was originally revealed by the scientists at the Australian CSIRO who observed the sphere structure under the electron microscope. Natural Precious opal is classified under four separate types, Opal, Boulder opal, Matrix opal, and Hydrophane opal. There are two distinct types of opal that form under similar but different chemical and geological environments. Almost all Australian precious opal forms nearby or within the Great Australian Basin (GAB) which is sometimes also named the Great Artesian Basin. This is an environment of a sedimentary nature where the weathering of the rocks has provided a suitable chemical environment that forms a silica and water solution to allow the formation of silica spheres that can form opal. Types of Opals Natural Opal (Type 1) - is opal presented in one piece in its natural state apart from cutting or polishing, and is substantially homogenous chemical composition. Natural Opal (Type 2) (Opal and rock) – is opal presented in one piece where the opal is naturally attached to the host rock in which it was formed and the host rock is of a different chemical composition. This opal is commonly known as bolder opal. Natural Opal (Type 3)(Opal in rock) – is opal presented in one piece where the opal is intimatley diffused as infillings of pores or holes or between grains of the host rock in which it was formed. The opal is commonly known as matrix opal. Until Recently Australia produced about 95% of the world’s precious opal gemstones, however during the last 10 years large deposits of precious opal has been discovered and mined in Ethiopia. Ethiopian precious opal is different from Australian Precious opal in many aspects, and has different gemmological constants that allow for it to be distinguished. Much of the new Ethiopian material is known as “Hydrophane opal” and it has been given this name because the material is porous in its nature and as such can absorb water and other fluids. (See special care notes below). Precious hydrophane opal is also “type 1” as the material is “all” opal, it will be distinguished in the nomenclature by a definition noting its porous nature. Precious opal qualities. Precious opal is often classified or graded by its “Body colour” or “Body Tone. This grading is a neutral scale from Black to white as listed in the chart below. Body Tone Chart Black Opal Dark Opal Light Opal Page 22 of 73 Black Opal is the family of opal which shows play-of-colour within or on a black body tone when viewed face up and may be designated N1, N2, N3 or N4 on the Scale of body tone. This type of opal mostly comes from Lightning Ridge (NSW) and high quality stones are very rare. Black Crystal is the family of opal which shows a degree of transparency the colours are often brilliant and can appear to come from within the depth of the gemstone. Good black crystal opals are very rare. This type of opal is mainly mined at Lightning Ridge (NSW) Dark Opal is the family of opal which shows play-of-colour within or on a dark body tone, when viewed face up and may be designated N5 or N6 using the Scale of Body Tone. This type of opal mainly comes from Mintabie (SA) and Lightning Ridge (NSW). Light Crystal Opal is the family of opal which shows a play-of-colour within or on a light body tone, when viewed face up and may be designated N7, N8 or N9 on the Scale of Body Tone. The N9 category is referred to as white opal. This type of opal is mainly mined from the South Australian fields of Mintabie, Coober Pedy and Andamooka, although the first material was mined 1890 when the first mining leases where granted in White Cliffs. Crystal Opal is an opal that is transparent or very translucent and in the better qualities shows a distinct and very bright play-of-colour. This type of opal is found in most Australian opal fields. Boulder Opal: is the family of opal naturally occurring on its host rock. It is easily identified because, when cut, the host rock brown ironstone) is left on the back of the opal. Boulder opal may be light, dark or black. In the last twenty years this type of opal has become extremely popular as it can display the same darkness and brilliance as a high quality black opal. There is also “Yowah” and “Yowah nut” opal which also come from the Queensland mines. Opal with a distinctly coloured body (such as yellow, orange, red or brown) should be classified as black, dark or light opal, by reference to the Scale of Body Tone, and also have a notion stating its distinctive hue appended to its determined body tone. Mexican Opal. The most notable gemstone opal material produced by the Mexican opal fields is material commercially traded as “Mexican Fire opal”. Fire opal is a well-known term used in the gemstone industry to describe orange to dark red colours of common opal that is transparent to semi-transparent in nature. This material is often faceted in to orange and red gemstones like other faceted gemstones. Page 23 of 73 Also seen form the Mexican opal fields is a precious Mexican opal that is very different to Australian precious opal. Most often the Mexican precious opal shows a Play of colour within a very orange body coloured gemstone. This material can vary from a bright orange body colour through to a “crystal” or transparent variety with almost no body colour, although it is usually slightly pale yellowish. This material is usually cabochon cut, like other precious opal, to show the play-of-colour. Sometimes a variety of Mexican boulder opal is produced which shows precious opal within or on a light rhyolite rock. This material is very different from Queensland boulder opal, which typically has an ironstone component. Mexican fire opal and Mexican Precious opal is distinguishable from Australian precious opal not only by its orange body colour, but also by its gemmological constants and attributes. Factors determining the value of all types of opals The three major factors of value for precious opal are, the blackness or darkness of the body colour, there brightness or brilliance of the play of colour, and the amount of red in the spectral play-of colour. When you add to these factors the element of the pattern, (which is the way in which the colour grains are arranged) and what the pattern looks like, whether it is a regular pattern, or a consistent pattern, or a directional pattern, the difficulty in providing a value can readily be seen. This is also highlighted due to the fact that each and every precious opal is different or unique in its play-of-colour, no two opals are exactly the same. Opal Cutting Most precious opal is cut en cabochon, usually in oval shapes; however boulder opal and especially Queensland Ironstone boulder opal is often cut in freeform shapes with an undulating surface, and this is because the opal is usually a very thin layer on the top of the ironstone rock from which it is cut. More recently there has been a larger amount of precious opal that is also carved and shaped into different freeform shapes and abstract figures. Composite opals. Composite opals are manufactured items of either two pieces (Doublet opals) or three pieces (Triplet opals). They can appear in jewellery manufactured out of either natural opal laminates or synthetic opal laminates as illustrated in the diagrams. Sometimes small opal “tiles” are joined to a substrate in fitted pieces to form an opal mosaic. More recently some new designs of opal jewellery items have been manufactured where the precious opal is “inlaid” or fitted and polished flush to the surface of the jewellery item. Again this opal may be natural opal or it may be synthetic/imitation opal. Imitation opal in silver jewellery is now quite abundant Page 24 of 73 Doublet Opal Triplet Opal Mosaic and Inlaid Opal A composition of two pieces where a slice of natural opal is cemented to a base material. A composition of three pieces where a thin slice of natural opal is cemented between a dark base material and a transparent top layer (usually of quartz or glass). These are a composition of a small flat or irregularly shaped pieces of natural opal cemented as mosaic tile on a dark base material or encompassed in a resin. Synthetic/Imitation opal. Like many other gemstones, a man manufactured opal material has been produced and offered for sale in jewellery items. Whilst it is not prevalent in Australian market places it is abundant overseas, and especially in South East Asian and Chinese markets. A substantial amount of imitation/synthetic opal has been made into bead necklaces as well. Opal Treatments The most well know opal treatment is the dying or carbonising treatment of sugar and acid applied to Andamooka Matrix opal. In this treatment the lighter coloured matrix opal is given a black or dark background in order to imitate precious black opal. This treatment is common. Also a substantial amount of Queensland boulder matrix opal has been treated in a similar but slightly different fashion, and at least one product known as “fairy stone” has been used to produce beaded necklaces. Also seen in the market place is a substantial amount of Ethiopian hydrophane opal that has been coloured black, usually by a process of “Smoke treatment” this material is abundant on the internet and in the overseas markets. Special care requirements. Recently the International Coloured Stone Association (ICA) issued the following information regarding Ethiopian hydrophane type opal: Precious opal Type 1- Hydrophane Special care required Hydrophane generally indicates a material that is absorbent when immersed in liquid. Keep away from cleaning agents, perfumes, oils and any liquids as they can be absorbed and may alter colour and/or appearance. Avoid sudden and extreme temperature changes. Avoid steam and ultra-sonic cleaners, clean with a soft cloth. Page 25 of 73 2. JEWELLERY PRODUCT KNOWLEDGE a. Types of Jewellery & Components Rings Some Rings have carried special significance; an example is in times when most people could not sign their own names seal rings that were imprinted into wax bore testimony to the authenticity of a document. Early Chiefs and Kings would send an emissary with their seal ring to negotiate inter kingdom agreements. Later wedding bands, which were consecrated in a religious ceremony, indicated a person’s marital status. The significance of the ring carries on to this day with promise and engagement rings preceding a marriage and eternity (some call them anniversary) rings following. Wedding rings Usually a flat or domed (D shape) ring which are plain but some variations are stone set, diamond cut patterned or engraved. These may be produced in a variety of metals. D shaped band (also known as half round or domed) Plain flat Gem set Styles which have stones set into the band. These sometimes take a nonconventional shape in order to fit snugly into a special engagement ring design. Signet rings A solid band with a flat top. Sometimes engraved with a pattern and often engraved with the owners initials. These rings are often die struck and the standard shapes are oval, round, square, cushion and shield. They can also be stone set with family insignia. In the North America most universities, schools, clubs and units of the armed forces have their own signet rings. Page 26 of 73 Stone set rings, also referred to as – Dress rings, Cocktail ring, Dress ring A term used to describe both diamond and coloured stone rings, such as above. Whose use is ornamental without needing to bestow a special meaning to the occasion of purchase. Cluster Dress ring Cocktail ring A term used to describe both diamond and coloured stone rings whose design is in a cluster style without needing to bestow a special meaning to the occasion of purchase. Style of large rings with fancy stones or multiple stones which are not suitable for everyday wear and care needs to be exercised when wearing these items. Multi-stone Cluster Multi-stone rings with a large central stone may be accompanied by two or more smaller stones on the shoulder These often take the form of a larger centre stone with rows of smaller stones encircling the centre stone. Engagement ring Broadly divided into 3 groups. Solitaire Solitaire which holds one centre stone as the hero of the piece. Variants of this style may have stones set into the shoulders of the ring Brooches The origin of the brooch is as a clip mechanism for holding garments closed. Later it evolved into having just a decorative use. Often worn on the lapel of a coat or to secure a scarf. Baby brooch Classic vintage bar style brooch Modern bar brooch Given at birth and used to attach bib Page 27 of 73 Cameo brooch Other plain and stone set brooches 21st key Leaf brooch Nature as inspiration Hinged Slave or golf Key hole Manufactured with a hinge to allow the bangle to open and usually with a tongue and groove box snap to hold closed. A continuous circle or oval that is pushed over the wrist. Usually worn in multiples. In some countries this is still a form of accumulating wealth. Bangles A width of polished metal with a keyhole closure mechanism and a loop to hold the metal in. Cuffs These are large light weight for their size pieces often made in silver or base metal which often make use of laser etching to produce fancy pieces with cut out patterns. Some are also diamond cut to add sparkle. Bracelets Made from chain with a length between 17.5cm and 21cm and an appropriate closure. Tennis Stone set Mesh Gate Page 28 of 73 Stone set bracelet, usually with diamonds. Stone set bracelet, usually with a combination of diamond or gemstones. Bracelet of interwoven design. Made in a variety of widths and clasp closures. Traditional English style with long oval and short links. Made in a variety of standard patterns. Body Jewellery Apart from toe rings and ear-cuffs most body jewellery is associated with piercings. Toe rings Belly Bars A semi-circular ring with an opening that allows the ring to be bent to fit. Made with a ball on one end that unscrews allowing the shaft to be inserted and a decretive head at the other end. Some other forms body jewellery are nose rings, tongue piecing’s ear-cuffs, labrets and more. This is mainly a costume jewellery area as the articles for piecing are often made from surgical grade stainless steel for safety reasons. Lockets Originally made to hold a lock of a loved one’s hair, but after the invention of photography, often used to hold a picture instead. Pendants The origin of the pendant goes back to the amulets that early mankind wore to ward off evil spirits. As metal working became more skilled these evolved into intricate and beautiful items. These include gem and diamond set pendants in a multitude of different designs. Pink sapphire and diamond pendant Blue topaz and diamond pendant Religious Pendants These take the form of Crosses, Crucifixes, Saints medallions, Stars of David, Chai’s and many more. Page 29 of 73 Maltese cross Crucifix St Christopher Medallion Star of David Chai - Hebrew symbol for life Other styles of pendants Dog Tag Styles: evolved from military personnel ID tags Dog tag style pendant with diamond cutting Earrings - Pierced Studs Drops Hoops Other The definition of a Stud Earring style is that it consists of a head piece to which is attached a post (pin) and is kept on the ear by passing the post through a hole pierced in the ear lobe and securing with a butterfly fitting. (Also called a scroll) Studs may be plain or stone set and have various finishes. These styles use a stud top (as described above) to which is attached one or more pieces that hang down below the lobe of the ear. They may be plain metal or stone set. A multitude of styles that have in common the fact that they encircle the lobe of the ear. Many have a hinged fitting that goes through the lobe and clips into a bracket to hold it closed. Others have a hinge at the bottom and a wire form that passes through the lobe at the top and a notch cut into the wire that clips into a reciprocal hole in the other half. Earrings - Non-Pierced A screw fitting is attached to a u piece which is produced with a winder that allows the wearer to tighten the screw head against a plate when the u is placed onto the ear lobe. The earring design is soldered in front of the plate. Page 30 of 73 Ear screw A pearl cup attached to a screw fitting Cuff links There are two main cufflink groups. Torpedo Torpedo styles with chain links between the cuff-link fancy top and the torpedo (sometimes made in the shape of a dumbbell). Clip Clip fitting Clip fittings are another method of securing the earring to the ear for those who do not have pierced ears. Swivel Swivel mechanisms These styles consist of a plate which is attached via a joint to a mechanism which folds flat to allow for easy insertion through the double button holes of the shirt sleeve. Once passed through the mechanism unfolds at right angles to secure the cuff-link on the sleeve. Tie jewellery The tie pin consists of a front to which is attached a pin which is pushed through the tie and shirt front and secured with a clip mechanism at the back. Tie chain Tie bar Tie chains use a metal wire which is bent to pass over the button on the shirt and at the end of the wires is attached a piece of chain which holds the tie against the body whilst serving a decorative function. Sometimes small charms are hung from the chain or plate inserted in the chain. A belcher chain attached to a tie chain back. Note the double loop for safely securing the article. The Tie Bar works by passing over the Tie and Shirt front, clamping the two together and Holding the tie in place. A tie bar set with a small diamond. Page 31 of 73 Findings Findings are a collection of often used components manufactured by specialist suppliers in a variety of carat golds, silver and base metals. They are also often used in jewellery repairs. Earrings Traditional shepherd hook Shepherd hook with safety A scroll or butterfly placed on the pin/ post to secure earrings Drop earring top. Note hole punched out below half ball. Pin is usually 8mm thick Screw fitting with pearl cup for non-pierced ears Wire clip for non-pierced ears Banjo style clip for attachment to earring Chains, bracelets and similar findings Parrot clasp Jump rings Bolt ring The parrot clasp comes in many sizes and variations. (Lobster claw, carabina and many more). Small sizes are used on gold chains and large pieces are to be found on bracelets. These clasps have a small steel spring that keeps the tongue closed. Lock Jump rings are used to secure the parrot clasp to the chain and also to pass through the clasp jaws for ease of use where the chain link is small. The bolt ring is the most widely used clasp fitting. Made from a hollow tube which contains a steel spring that acts against a pin with a plate at the end (inside the tube) to ensure it stays it is this piece that gives the clasp its name. Toggle Bar Safety chain Swivel (also known as albert clasp) Swivel usually found attached to a fob chain used for pocket watches. Later it was used as a bracelet and chain finding in its own right. Page 32 of 73 This lock works by having a hinged end on one side of the loop and a niches end on the other side that clips into place to hold the loop closed. Usually found on bracelets. Toggle Bar and Dumbbell Bars: Used as closures on bracelets and necklets, often a feature of the pieces design. Not recommended for valuable pieces as there is a higher risk of loss than with other styles. The sketch is of style usually die struck and assembled. Others are made from cast pieces soldered together. The Safety Chain is used to ensure the item does not drop off in event of a failure of the clasp mechanism. It is attached to the article on one end and is closed on the other with the bolt ring. In many bracelets it is permanently attached at both ends and the article is put on as one would with a bangle. Variations for brooches are made with a safety pin mechanism replacing the bolt ring. Other Clasps Pearl Fold over The pearl clasp has a loop at both ends for attaching the pearl strings. The spring action in most pearl clasps comes from the fold over of the piece that is inserted into the case. This basic clasp is called a fold over clasp and is often used on identity bracelets. The folded over loop at the end acts as a kind of fail-safe system as when strain is on the clasp the chain is acting against the bent over section. Other findings Brooch pin Roller catch Cuff link backs Tie tack Brooch pin used in conjunction with a hinge and roller catch to secure the brooch to clothing Roller catch on the left with the u shaped bracket to fit the tail end of the pin. A wire is passed through the u shaped bracket and the pin and is riveted in place to secure. Cuff link backs are attached to the cufflink fronts to complete the style. The hinged tubular piece folds down to create a straight part that can easily be inserted through the shirt cuff with one hand. A plate mounded onto a pin. Tie tack back with safety chain attached and “T” bar to slide through shirt front button hole. Page 33 of 73 b. Jewellery Production Methods i. Traditional Bench Manufacturing The traditional method for manufacturing jewellery is to manufacture products using rolled and drawn gold alloys, shaping by hand, cutting and soldering parts together, before setting stones and polishing. Jewellers Bench Gold Alloy Granule Gold Wire Gold Plate Rollers/Mills Wire Drawing Saw Piercing Annealing Assembly Page 34 of 73 Soldering Emerying Stone Setting Polishing ii. Lost Wax Casting Mould made from prototype Wax injected into the mould Wax removed from the mould Page 35 of 73 Wax pattern placed onto a wax tree Wax tree ready for investing Plaster poured to produce a ceramic mould Flask placed into a kiln to burn out the wax Flask heated to 730 Molten gold alloy is poured into the flask Plaster is removed to recover the gold tree Pasrt ready for removal Castings are set with stones and polished iii. Laser Welding Laser Welding technology allows the jeweller to undertake repair work using very little heat and achieve fine detailed work. Page 36 of 73 One of the advantages of using a laser, is that the metal used for the repair is the same as the metal used to manufacture the item, therefore no ‘solder’ is used, the caratage remains the same and there is no colour difference. Many repairs made on jewellery items can be done using the laser and avoiding the need to remove stones, which then reduces the risk of stone breakage. iv. Laser Engraving Laser Engraving technology allow decorative patterns and customer logos and inscriptions to be engraved onto the surface of designs, allowing very complex patterns to be created with very fine details. v. Plating (Decorative) Electroplating jewellery is the process of depositing a bright and colourful surface coating to finished items, to produce a mirror finish and changing the original appearance. Once the item is chemically cleaned, it is placed in a solution that contains the required metal to be plated, and an electrical current is passed through the item, which causes the metal that is in the solution to be deposited (plated) onto the surface of the item. If two or more colours are required, the item is painted with a masking lacquer to prevent the areas not requiring plating from being changed. The colour of the item after plating is dependent on the chemical composition of the solution in the plating bath. Page 37 of 73 The most common metals plated are gold, silver and rhodium. Gold Plating Typically there is a range of yellow gold colours to choose from, as well as several shades of red gold plating. Silver Plating Silver plating is use to give silver items a very white finish after polishing. This is typically found in trophies, cutlery, plate ware, and other similar items. Rhodium Plating Rhodium is an element that is part of the platinum group of metals. it is a ‘hard’ white metal in appearance. As white gold is alloy of pure gold and other ‘white’ metals, (i.e 18ct = 750/1000 parts gold + 250/1000 parts other metals), the final colour of a white gold alloy will vary between manufacturers due to the different amounts of metals they mix with the gold. The majority of white gold jewellery is Rhodium Plated to give a shiny bright ‘white’ appearance that is consistent amongst manufacturers. This consistency is required in the retail environment as item are sourced from multiple manufacturers. Rhodium Plating is a very thin coating, and overtime will require re-plating as the coating wears off through abrasion. Surface Coatings There are many different forms of ‘protective’ surface coatings that can be applied to jewellery items in order to reduce the effects of the environment and reduce the incidence of tarnishing. Most of the new nano-tech coatings are design to protect the jewellery whilst in-store, but do not offer much resistance to the daily ‘wear and tear’ when the items are worn. c. CAD/CAM CAD/CAM is an acronym for Computer Aided Design / Computer Aided Manufacturing. CAD is the software tool used by a jewellery designer to create a 3 dimensional graphical representation of the design required to be made. When completed, the 3D design can be ‘rendered’ to produce a photo-realistic representation of what the design will look like when manufactured. This visualisation allows the customer to see how the custom design will Page 38 of 73 look before any major expense to manufacture has been made. Modifications to the design can be easily made to the CAD drawing to ensure the design meets the customer expectations. When satisfied that the design meets expectations, the CAD file is exported as a surface mesh (STL, SLC, SLF), which can then be used by the CAM software to create the tool paths required for the machine being used to create the physical model. By creating a 3D model, the design can then be coded to allow a machine to “print” the design using wax, UV resin or other substrates. Model to be ‘sliced’ into layers Multiple layers CAM is the process used to convert the 3D design created by a designer, and produce a physical item by utilising a commercially available printer. Printers can use either a subtractive or additive process to produce the physical final piece. a. CAM Software: Once the design has been saved as a ‘surface mesh’ the file is imported into software package that ‘slices’ the surface mesh into layers, and then creates the tool paths for each layer specific for the machine being used. The printer will take this ‘sliced model’ file and build the design, layer by layer. Page 39 of 73 b. Subtractive Process: involves the removal of material from a block, typically using a milling process. This process is limited for jewellery applications due to the limited ability for the tools to mill undercut and hollow parts of the item. Wax milling c. Milled design Additive Process: use different materials such as wax, UV resin and metal powders, to progressively build the design layer by layer. The process allows for very complex designs with no limitation on the shape of the item. Wax printing Wax printed designs UV printing UVresin printed designs Metal powder printing Page 40 of 73 d. e. f. Parts of a ring Parts of a ring Types of Settings Claw Bezel set or rub over Types of Shanks Flat D Shape (also known as half round) Shank Channel Head or setting Bead (also known as grain set) Tapered Hammer set (also called Swiss set) Split End Set Cross-over g. Types of Chains Descriptive terms associated with chain and pearl strands lengths: Collar: approximately 25-35 cm long. This sits lower on the neck line Choker: approximately 35-40 cm long. This should sit up on the neck line Pendant: approximately 45cm long. This should sit at or just below the collarbone Matinee: approximately 50 to 60cm long Opera: approximately 70cm or longer Sautoir: approximately 70-90cm long Rope/Lariat: approximately 115cm long Page 41 of 73 Some types of chain Anchor Belcher Byzantine Cable Curb Box (also known as Venetian) Bead Figaro Rope Snake Prince of Wales Serpentine Trace Herring Bone Page 42 of 73 Omega h. Plating and coatings i. Rhodium Plating With modern alloys, how do jewellers achieve a really white colour? The answer to that question is rhodium plating. A quality rhodium plated finish should be standard procedure on all white gold mountings but this leads to another frequently asked question, how does one get a good rhodium plated finish? To answer that question let's begin with the basic principles. First and foremost the piece needs to be polished to a bright finish. If the piece is not clean, it will not plate. Rhodium plating procedure 1. Polish to a brilliant high finish 2. Clean thoroughly in an ultrasonic cleaner 3. Rinse in distilled water 4. Steam clean 5. Electro clean: 120°F, 4 volts for 2 minutes in a stainless beaker with the positive lead attached to the beaker, negative attached to the piece being plated. OR 120°F, 4 volts for 2 minutes in a glass beaker with a stainless steel anode, positive lead attached to the stainless anode, negative attached to the piece being plated 6. Rinse in clean distilled water 7. Activator: room temp, no voltage, 30 seconds 8. Rinse in clean distilled water 9. Dip in fresh distilled water (When plating silver, use nickel mirror or palladium solution 120°F, 2 volts, for 2 minutes using a nickel anode. Palladium is recommended due the large amount of people that have allergic reactions to nickel) 10. Rhodium plate: Room temperature, 4.5 volts, 20-30 seconds, negative lead attached to piece being plated, positive lead to platinized titanium anode. 11. Rinse in clean distilled water 12. Steam clean then dry. Try using a blow dryer to heat dry the piece. (Allow item to cool before handling if going this route) Helpful hints Critical issues Use a gold hook to suspend object Temperature control: Minor from alligator clip, never steel. changes = inconsistent and poor Suspend object in solution with results current ON Current control: Never more than Be sure voltage setting is constant 3.5 volts for Rhodium, 3.5 is better when actually plating piece Proper rinsing: Using distilled water for about a minute Safety Safety glasses are a must When skin contact occurs, neutralize with a paste of baking soda. Rinse with plenty of water. Protect skin and clothing with rubber gloves and neoprene apron. As rhodium plating may produce some acidic fumes, it is recommended to work under good ventilation and to wear a NIOSH approved mask when plating. Page 43 of 73 Troubleshooting Rhodium plates black Dark spots after rhodium plating Rhodium looks frosty Mounting is not clean Make sure the piece is clean Amperage is too high, reduce to Current is set to high, try lowering Air bubbles are sticking to 1.5 amps amperage 1.5-2 amps and longer mounting, gently agitate to dislodge times 1 - 2 minutes for best results air bubbles Rhodium solution is contaminated. Give your bath a carbon treatment Suggested equipment 10 amp rectifier Platinized titanium anode Stainless steel anode 3 - 600ml pyrex beakers 3 lip covers An immersion thermometer A double burner Activator Electrocleaner Recommended ventilation for plating Solder pure with rhodium filter Ductless fume hood For gold plating, add the following Pyrex beaker 24ct gold anode 14ct yellow gold plating solution For plating of two-tone, yellow and white gold jewellery, add the Following Masking Lacquer Lacquer stripper ii. Gold plating Gold plating is a method of depositing a thin layer of gold onto the surface of another metal, most often copper or silver (to make silver-gilt), by chemical or electrochemical plating. There are five recognized classes of gold plating chemistry: 1. 2. 3. 4. 5. Alkaline gold cyanide, for gold and gold alloy plating Neutral gold cyanide, for high-purity plating Acid gold plating for bright hard gold and gold alloy plating Non-cyanide, generally sulphite or chloride-based for gold and gold alloy plating Miscellaneous Gold plating of silver is used in the manufacture of jewellery. Like copper, silver atoms diffuse into the gold layer, causing slow gradual fading of its colour and eventually causing tarnishing of the surface. This process may take months and even years, depending on the thickness of the gold layer. A barrier metal layer is used to counter this effect. Copper, which also migrates into gold, does so more slowly than silver. The copper is usually further plated with nickel. A gold-plated silver article is usually a silver substrate with layers of copper, nickel, and gold deposited on top of it. Page 44 of 73 i. Watches/Clocks Term Alarm clock Analogue quartz time keeping instrument Automatic chronograph braille watch or clock Carrousel watch Chronograph Chronometer Complication Cuckoo clock Desk or Table clock Digital quartz time keeping instrument Electric time keeping instrument Hall clock Marionette or Carillon clock Mechanical time keeping instrument Multi-function time keeping instrument Pocket watch Radio controlled watch or clock Satellite radio controlled watch and/or clock Skeleton watch or clock Solar-powered watches or clock Solar cell time keeping instrument Stopwatch Talking watch or clock Definition Clock with alarm function. Quartz timepiece whose indicating devices (dial, hands, etc.) have a mechanical construction. Chronograph equipped with an automatic winding device. Timepiece that can tell time using voice or by touching it with the fingers. Watch with a mechanism similar to the tourbillon but with the cage rotating around the third wheel instead of the fourth wheel. Timepiece that can measure time besides the time indication function. Name of a mechanical watch whose precision has been tested and which has been certified by an official body managed by the Chronometer Control International Council (CICC). The test program and minimum requirements are defined by ISO 3159 - Wristchronometers with spring balance oscillator. A is an additional indication which differs from the simple timekeeping function. The chronograph, striking-mechanisms, repeaters, perpetual calendars, phases of the moon and multiple time-zones are all examples of complications. Clock that indicates each hour or fixed times through the song of a bird. Stationary clock placed on a desk or a table. Quartz timepiece with electronic display. (LCD, LED, etc.) Timepiece using electrical power source but mechanical time source elements and indicating devices. Note: Some timepieces use utility power for power source and time source. Large and tall clock for indoor use. Clock that plays a melody and activate the dial or a marionette at fixed hours. Timepiece whose power source, time source elements and indicating devices have a mechanical construction. Timepiece equipped with functions such as time counter or alarm besides time display. Note: Mechanical watches with many functions are also called complicated watch. Portable watch that can be put on the clothes or in a pocket. Watch or clock equipped with a function to automatically adjust the time and date using standard time radio signals. Watch or clock equipped with a function to automatically adjust the time and date using radio signals received from a GNSS including GPS. *GPS: Global Positioning System Watch or clock whose movement's skeleton can be seen through the case or the dial. Timepiece equipped with solar cells to use the energy of light as power source. Portable time counter. Watch or clock that uses audio messages to indicate time, etc. Page 45 of 73 Tourbillon watch Wall clock Wristwatch Watch whose escapement and the regulator at its center are placed in a rotating cage. The escape wheel pinion rotates around the fixed fourth wheel. The cage generally rotates one turn per minute and adjusts to minimize changes in the vertical position. Clock that is fixed to a wall or a column. Watch worn on the wrist using a band. Watch part names An example of a typical analogue watch with a leather strap An example of a digital watch with a metallic band Mechanical watch and quartz watch The Swiss watch industry produces essentially two types of watch: electronic quartz watches and mechanical watches. Three in every four watches are electronic. Despite being produced in smaller numbers, mechanical watches are extremely important in value terms, since they represent more than 75% of total value. Page 46 of 73 Quartz watch In a quartz watch, the heart of the watch consists of the integrated circuit. The division of time is effected by a quartz oscillator, vibrating under the effect of electrical energy supplied by a battery. The energy source takes the form of a miniaturised battery with a lifespan of several years. The division of time is effected by a quartz oscillator which transforms energy from the battery into vibrations. Quartz watches are extremely accurate thanks to a high frequency of vibration (32 kHz). Their annual variation is consequently very low: in the order of one minute per year, i.e. less than a second a day. Quartz watches come with two types of display. The most common is the analogue display, i.e. with hands. Watches with a digital display contain liquid crystals, which receive the impulses they need to display the time directly from the integrated circuit. Therefore, there is no mechanical transmission of energy. These two types of display can be combined to provide a range of indications, such as the time of day and short, measured times, for example. Diagram of a quartz watch 1. Battery 2. Integrated circuit 3. Quartz 4. Trimmer regulating the frequency 5. Stepping motor 6. Gear-train 7. Analogue display Mechanical watch A standard mechanical watch has around 130 components assembled in three subassemblies, namely the energy source, the regulating parts and the display. The number of components is naturally higher for watches with complications (chronograph, calendar, phase of the moon, fly-back hand, etc). The energy supplied by the spring is transmitted by the gear-train. The escapement transmits impulses, while the balance divides the time. Winding, either manual or automatic via the rotor, tightens the spring. Diagram of a mechanical watch 1. Mainspring 2. Gear-train 3. Escapement 4. Oscillating balance 5. Winding stem 6. Rotor 7. Analogue display Page 47 of 73 Automatic quartz watch Swiss watchmakers have overcome the challenge of combining these two types of technology. They have created a watch movement which operates as a quartz movement but recharges like a mechanical movement, thereby obtaining an automatic watch with the accuracy of quartz. Its operating principle is simple but nonetheless revolutionary: an automatic recharging mechanism (oscillating weight) tightens the mainspring which, when released, starts up a mini-generator able to convert mechanical energy into electrical energy. This energy is accumulated in a capacitor. Thereafter the system behaves like a traditional quartz watch, with the integrated circuit controlling the distribution of energy and providing the impulses required to drive the stepping motor. What is the lifetime of a watch battery? Generally the lifetime of a watch battery is between two and five years. Its longevity depends on the type of watch, its dimensions and the amount of energy required by the different functions. For example, a chronograph will have a higher energy consumption than a watch that only indicates hours, minutes and seconds. Some watches are equipped with a battery power indicator: when the seconds-hand jumps in intervals of several seconds, it is time for the battery to be replaced. Some special lithium-iodine batteries have a theoretical lifespan of up to 10 years. What are the jewels of a watch? A mechanical movement contains watchmaker’s stones that reduce friction, and hence wear, to a minimum. The rubies that were originally used have long since been replaced by synthetic sapphires. These jewels, as they are still called, are turned, polished and drilled to serve as bearings for the different gears of a watch. In general, a standard mechanical watch displaying hours, minutes and seconds should in principle contain at least fifteen jewels located in the places most subject to wear caused by friction. It must be fitted with a shock-absorbing system on the balance, containing a jewel. What is a unidirectional bezel? A bezel is a ring fitted over the case band of the watch case. It is used to record additional data, such as the duration of a phenomenon for example. It can rotate in both directions. The unidirectional bezel on the other hand, as its name implies, only turns one way. This technical constraint prevents any danger when measuring a diving time for example, since even if the bezel is knocked and moved it will simply indicate the diver has less air or decompression time rather than more. What types of water-resistant watches are there? Water Resistant is a quality specification for water-resistant watches based on the description of JIS (Japan Industrial Standards) and ISO (International Organization for Standardization). "WATER RESIST” and "W.R.” are the abbreviated forms of "WATER RESISTANT.” The water resistance for daily use is indicated by "bar” (atmospheres) and the water resistance for diving is indicated by "m” (meters). Page 48 of 73 It is important to read carefully the instruction manual to understand the handling instructions and precautions before use regardless of the degree of water-resistance of the watch. The various types of water-resistant watches and their basic precautions are outlined in the table below. Examples of water-resistant indications shown in the table below are indicated either on the dial or on the case back. Name Specifications Watch for mixedgas diving 200m - 1000m Water resistant Watch diving 100m - 200m AIR DIVER'S 100m Water resistant for air Enhanced water resistant watch for daily use Water resistant to 20 bars Water resistant to 10 bars Water resistant to 5 bars Water resistant watch for daily use Water resistant to 2-3 bars Examples of water-resistant indications HE-GAS DIVER'S 300m WATER RESIST 20 BAR WATER 20BAR RESIST W.R.20BAR WATER RESIST 10 BAR WATER 10BAR RESIST W.R.10BAR WATER RESIST 5 BAR WATER 5BAR RESIST W.R.5BAR WATER RESIST W.R. Uses/precautions in handling The water resistance is as high as it can withstand diving to the depth of water indicated (example: 300m). This watch equipped with devices required for measuring the diving time and decompression time, such as a rotating bezel, can be used for deep-sea diving (mixed-gas diving) using the mixed gas of helium and oxygen for respiration. The water resistance is as high as it can withstand the pressure to the depth of water indicated (example: 100m) and longtime underwater use. This watch equipped with devices required for measuring the diving time and decompression time, such as a rotating bezel, can be used for shallowwater diving (scuba diving, etc.,) using compressed air in a cylinder for respiration. This cannot be used for mixed-gas diving. This can be used by people who do water sports (swimming, sailing, fishing, etc.,) and skin diving. Do not use it for mixed-gas diving or air diving. This can be used by people who often touch water (fishery, agriculture, car washing, restaurants, etc.,) and who do water sports (swimming, sailing, fishing, etc.). Do not use it for skin diving, mixed-gas diving, or air diving. Even if the water resistance is 5 bars or more, avoid directly showering or applying tap water to it under high pressure. This can withstand perspiration, face washing water drops, rain, etc., in daily life, but cannot be used for water-using works, water sports, skin diving, and other types of diving. Do not use it under conditions in which the water Page 49 of 73 Non-water resistant watch pressure changes sharply. In the case of NO marking of water resistant on the case back, avoid direct contact with water. Care for your watch Since manufacturers are obliged to provide instructions for use and detailed warranty conditions, make sure you obtain all necessary information from your reseller. Bear in mind also that only a professional is capable of correctly replacing the battery of your watch without impairing its water-resistance. How should I care for my watch? Ideally, mechanical watches should be inspected and cleaned every 3 to 5 years to ensure correct operation. The moving parts of quartz watches also need to be inspected when the battery is replaced; even the tiniest speck of dust can prevent the watch from running as it should. The battery should be replaced as soon as the watch stops or when the power-reserve indicates the end of its lifetime. This is a very fast, routine operation. Maintenance of water-resistant watches may be less frequent. However, water-resistant seals must be replaced if the watch is opened. Water-resistance can be checked by a specialist reseller. It should be borne in mind that frequent exposure of the watch to chemicals or seawater for example can also damage straps, bracelets and plated cases. The same is true of perfumes and certain cosmetics when applied directly. At all events, a timepiece manufactured from appropriate materials and fitted with a suitable strap or bracelet will help to prevent any inconvenience. Pay attention to surrounding electrical appliances because time indicated on timepieces may become incorrect if they are affected by magnetism. Many products in our environment generate magnetism, such as electrical appliances (speakers of audio equipment, etc.), mobile phones, magnetic necklaces, and magnets in furniture or bags. If your timepiece suddenly stops, or loses or gains time, it may be affected by magnetism. Magnetism resistant watches designed to minimize the effect of magnetism are commercially available. What should I be careful about daily care and use? Watch bodies and bands (metallic or leather) may cause stain on sleeve edges due to dirt and/or rust, or skin irritation due to allergic reactions for those who have sensitive skins. Keep watches clean. In addition, if rust forms in pins used in adapters that connect a watch body and a band or in metallic band links, the band may loosen, the watch body may fall off the band, or it even cause injury in rare cases. Adjust the band to allow a little clearance with your wrist to ensure airflow. When wearing the watch, leave enough room to insert a finger between the band and your wrist. Do not use solvents including benzine and paint thinner, chemicals, or bleach for cleaning. Moisture, sweat or dirt may cause rust on metallic bands including stainless steels and gold plating if they are left for a long time. Page 50 of 73 Because some titan bracelets use pins made of high-intensity stainless steels, rust may form in the stainless steel parts. Wipe off moisture or sweat with a soft and hygroscopic cloth and keep watches in a place that allows ventilation to dry them well. Wash bands with diluted neutral detergent or soapy water using a soft brush occasionally. Keep the watch body away from water if your watch is rated as "non-water resistant." For leather bands, wipe off moisture or sweat with a soft and hygroscopic cloth and keep watches in a place that allows ventilation to dry them well. A deteriorated leather band needs to be replaced. A leather band is susceptible to deterioration gradually even though the watch is unused. Synthetic rubbers such as polyurethane and plastic bands may crack, break, or deteriorate. Wash bands with diluted neutral detergent or soapy water using a soft brush occasionally. When a band becomes less flexible, have the band replaced with a new one. If you continue to use the band as it is, it may crack or become brittle over time. Be sure to observe the following when handling common watch batteries. Replacement of watch batteries requires professional knowledge and skill. For battery replacement, contact a watch store near you. Do not leave watches with dead batteries for a long time because it may cause a malfunction. Monitor batteries are incorporated in watches since shipping from a factory, so the first battery life may be shorter than the period described in instruction manuals. Page 51 of 73 3. INFORMATION FOR JEWELLERY RETAILERS a. Gemstone Specifications and Care Chart Agate - Blue Lace Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Blue background with white bands 7 None Translucent to opaque Lustre Waxy - dull Ultrasonic Steam Clean Special advice Gemstone family Type Quartz Ornamental Agate - Cameo Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Blue background with white foreground 7 Dyed Opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Quartz Ornamental Alexandrite Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Blue-green to red 8.5 1.745 – 1.759 3.71 – 3.75 None Transparent to near opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Colour Moh’s Hardness Refractive Index Specific Gravity Honey brown 2–3 1.539 – 1.545 1.02 – 1.12 Lustre Ultrasonic Steam Clean Special advice Usual treatment Transparency Often heat treated Transparent to opaque Gemstone family Type Vitreous Usually safe Usually safe Chysoberyl Precious Amber Resinous Usually safe Never Soft material – wear with care Organic Ornamental Page 52 of 73 Amethyst Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Purple 7 1.544 – 1.553 2.65 Heat treated Transparent to semitransparent Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Usually safe Never Colour Lustre Vitreous Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Bi-colour: purple and yellow 7 1.544 – 1.553 2.65 Heat treated Transparent Ultrasonic Steam Clean Special advice Gemstone family Type Usually safe Never Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Blue 7.5 – 8 1.563 – 1.582 2.68 – 2.80 Heat treated Transparent to opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Unsafe Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Green 7 Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous, waxy Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Translucent red/orange 6.5 Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Usually safe Quartz Precious Ametrine Quartz Precious Aquamarine Beryl Precious Aventurine Quartzite None Translucent, opaque Quartz Ornamental Carnelian Heat treated, maybe dyed Transparent to near opaque Quartz Ornamental Page 53 of 73 Chrome Diopside Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Green 5.5 – 6 1.664 – 1.721 3.22 – 3.39 None known Transparent, translucent Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous to dull Never Never Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Minty apple green 6.5 – 7 1.530 – 1.540 Vitreous to waxy Usually safe None known Translucent to opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Yellow to golden yellow 7 1.544 – 1.553 2.65 Heat treated Transparent Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Usually safe Never Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Red, pink 3.5 – 4 1.486 – 1.658 2.6 – 2.7 None known Transparent to opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous, waxy Never Never Avoid chemicals Organic Ornamental Adamantine – diamond Lustre Usually safe Usually safe Precious Chrysoprase Heating can affect colour Quartz Ornamental Citrine Quartz Precious Coral Diamond Colour Red, pink Lustre Moh’s Hardness Refractive Index Specific Gravity Usual treatment 10 2.42 3.51 Laser drilling, fracture filled, heat treatment Transparent to opaque Ultrasonic Steam Clean Special advice Gemstone family Transparency Type Diamond Precious Page 54 of 73 Emerald Colour Moh’s Hardness Refractive Index Specific Gravity Green 7.5 – 8 1.585 – 1.6 2.67 – 2.76 Lustre Ultrasonic Steam Clean Special advice Vitreous Never Never Avoid sudden temperature change Beryl Precious Usual treatment Transparency Oiled Transparent to opaque Gemstone family Type Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Deep red 7.0 – 7.5 1.750 – 1.830 3.95 – 4.30 None Transparent to opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Usually safe Never Colour Light yellowish to dark green 6.5 – 7.5 1.888 – 1.940 3.70 – 4.10 None known Transparent to opaque Lustre Vitreous, diamond-like, adamantine Usually safe Never Lustre Vitreous Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Yellow-orange, redorange 7.0 – 7.5 1.742 – 1.748 3.65 None Transparent to opaque Ultrasonic Steam Clean Special advice Gemstone family Type Usually safe Never Colour Moh’s Hardness Refractive Index Specific Gravity Rose to lavender 7.0 – 7.5 1.745 – 1.780 3.79 – 3.95 Lustre Ultrasonic Steam Clean Special advice Usual treatment Transparency None Transparent to opaque Gemstone family Type Vitreous Usually safe Never Avoid sudden temperature change Garnet Precious Garnet – Almandine Garnet Precious Garnet – Demantoid Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Ultrasonic Steam Clean Special advice Gemstone family Type Garnet Precious Garnet – Hessonite Colour Garnet Precious Garnet – Rhodolite Page 55 of 73 Garnet – Tsavorite Colour Moh’s Hardness Refractive Index Specific Gravity Bright green 7.0 – 7.5 1.738 – 1.745 3.57 – 3.68 Lustre Ultrasonic Steam Clean Special advice Usual treatment Transparency None Transparent to opaque Gemstone family Type Vitreous Usually safe Never Avoid sudden temperature change Garnet Precious Hematite Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Black, black-grey, brownred 6 – 6.5 2.940 – 3.220 None known Opaque Lustre Metallic Ultrasonic Steam Clean Special advice Gemstone family Type Never Usually safe Metallic Ornamental Iolite Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Blue, purple-blue 7 – 7.5 1.537 – 1.551 2.58 – 2.66 None known Transparent, translucent Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Never Never Colour Brown, blackish, violet, green, white, red, yellow 6.5 – 7 1.64 – 1.68 3.30 – 3.58 Bleached, dyed, Opaque, translucent Lustre Waxy, greasy Ultrasonic Steam Clean Special advice Gemstone family Type Never Never Precious Jade - Jadeite Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Jade Ornamental Jade - Nephrite Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Green, white, grey, yellow, red, brown, often spotted 6 – 6.5 1.600 – 1.627 2.90 – 3.02 Often untreated but can be dyed, coated or impregnated Translucent, opaque Lustre Vitreous Ultrasonic Steam Clean Special advice Gemstone family Never Never Type Ornamental Jade Page 56 of 73 Jasper Colour Lustre Dull, vitreous Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency All colours, mostly striped or spotted 6.5 – 7 1.540 2.58 – 2.91 None known Opaque Ultrasonic Steam Clean Special advice Gemstone family Type Quartz Ornamental Colour Moh’s Hardness Refractive Index Specific Gravity Pink, violet 6.5 – 7 1.600 – 1.681 3.15 – 3.21 Lustre Ultrasonic Steam Clean Special advice Usual treatment Transparency Irradiated Transparent Gemstone family Type Vitreous Never Never Avoid strong light due to colour fade Spodumene Precious Colour Lustre Vitreous, greasy to dull Moh’s Hardness Refractive Index Specific Gravity Lazur blue, violet, green-blue with light blue colour streak 5–6 1.500 2.50 – 3.0 Ultrasonic Steam Clean Special advice Usual treatment Transparency None known Opaque Gemstone family Type Never Never Avoid chemicals, soft material – wear with care Rock Ornamental Kunzite Lapis Lazuli Malachite Colour Light-green to black-green, banded 3.5 – 4 1.655 – 1.909 3.25 – 4.10 None known Translucent, opaque Lustre Weak vitreous, matt Ultrasonic Steam Clean Special advice Gemstone family Type Never Never Avoid chemicals Carbonate Ornamental Lustre Vitreous to pearly Moh’s Hardness Refractive Index Specific Gravity Colourless, yellow, pale sheen 6 – 6.5 1.522 – 1.530 2.56 – 2.58 Ultrasonic Steam Clean Special advice Usual treatment Transparency None known Transparent to translucent Gemstone family Type Never Never Sensitive to pressure – wear with care Feldspar Ornamental Page 57 of 73 Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Moonstone Colour Onyx Colour Lustre Vitreous to pearly Moh’s Hardness Refractive Index Specific Gravity Colourless, yellow, pale sheen 6 – 6.5 1.522 – 1.530 2.56 – 2.58 Ultrasonic Steam Clean Special advice Usual treatment Transparency None known Transparent to translucent Gemstone family Type Never Never Sensitive to pressure – wear with care Feldspar Ornamental Opal – white, black, matrix, boulder, harlequin, jelly, crystal, girasol Colour All colours. Moh’s Hardness 5.5 – 6.5 Refractive Index 1.370 – 1.52 Specific Gravity 1.98 – 2.50 Lustre Ultrasonic Steam Clean Special advice Waxy to resinous Never Never Avoid heat, chemicals and water – wear with care Opal Precious Usual treatment Transparency None known Transparent to opaque Gemstone family Type Colour Orange-yellow Lustre Moh’s Hardness Refractive Index Specific Gravity 5 – 6.5 1.370 – 1.45 2.15 Ultrasonic Steam Clean Special advice Usual treatment Transparency None known Transparent to opaque Gemstone family Type Sub vitreous to waxy, resinous Never Never Avoid heat, chemicals and water – wear with care Opal Precious Colour Lustre Pearly Ultrasonic Steam Clean Never Never Specific Gravity White, pink, silver, cream, golden, blue, black 2.5 – 4.5 1.520 – 1.660 Black: 1.530 – 1.690 260 – 2.85 Special advice Usual treatment Transparency Bleached Translucent to opaque Gemstone family Type Avoid chemicals and household items – wear with care Organic Precious Opal – Fire Pearl Moh’s Hardness Refractive Index Page 58 of 73 Pearl - Mother of Pearl Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency White, grey, silver, yellow, blue-green, brown, pink, red, black, bronze, banded 2.5 – 4.5 1.53 – 1.69 260 – 2.87 None known Translucent to opaque Lustre Pearly Ultrasonic Steam Clean Special advice Gemstone family Type Never Never Organic Ornamental Pearl - Paua Shell Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Blue-green iridescent 3.5 None known Translucent to opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Pearly Never Never Organic Ornamental Peridot Colour Moh’s Hardness Refractive Index Specific Gravity Green, yellow-green 6.5 – 7 1.635 – 1.710 3.3 – 3.4 Lustre Ultrasonic Steam Clean Special advice Usual treatment Transparency None known Transparent Gemstone family Type Vitreous, greasy Never Never Avoid harsh chemicals and thermal shock Quartz Precious Colour Yellow-green, brownyellow 6 – 6.5 1.611 – 1.669 2.82 – 2.94 None known Transparent to opaque Lustre Vitreous to pearly Ultrasonic Steam Clean Special advice Gemstone family Type Never Never Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Usually safe Never Prehnite Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Ornamental Quartz – Lemon Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Pastel yellow, pastel green 7 1.544 – 1.553 2.65 Irradiated, heat treated Translucent Quartz Precious Page 59 of 73 Quartz – Prasiolite, mint, green Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Pale green 7 1.540 – 1.550 2.65 Irradiated, heat treated Transparent Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Usually safe Never Quartz Ornamental Quartz – Rose Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Pink 7 1.544 – 1.553 2.65 Sometimes dyed Translucent Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Usually safe Never Colour Clear to smoky with rutile needles (golden, black, red-pink) 6 – 6.5 1.54 – 1.55 2.63 – 2.70 Lustre Vitreous Ultrasonic Steam Clean Special advice Gemstone family Type Quartz Ornamental Quartz Precious Quartz – Rutilated Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Transparent to translucent Quartz – Smokey Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Brown to black, smokey grey 7 1.544 – 1.553 2.65 Often dyed Transparent to translucent Lustre Vitreous Ultrasonic Steam Clean Special advice Gemstone family Type Usually safe Never Quartz Precious Ruby Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Red 9 1.760 – 1.778 3.80 – 4.05 Often heat treated Transparent to opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Usually safe Usually safe Corundum Precious Page 60 of 73 Sapphire Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Blue 9 1.760 – 1.774 3.99 – 4.01 Often heat treated Transparent to opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Usually safe Usually safe Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Blue 5.5 – 6 1.480 2.24 Often dyed Transparent to opaque Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous to greasy Never Never Dyed material may fade Colour Black, blue, pink, purple, red, violet 8 1.712 – 1.762 3.54 – 3.63 None known Transparent to opaque Lustre Vitreous Ultrasonic Steam Clean Special advice Gemstone family Type Usually safe Usually safe Corundum Precious Sodalite Ornamental Spinel Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Spinel Ornamental Tanzanite Colour Moh’s Hardness Refractive Index Specific Gravity Deep blue 6–7 1.692 – 1.700 3.35 Lustre Ultrasonic Steam Clean Special advice Usual treatment Transparency Often heat treated Transparent Gemstone family Type Vitreous Never Never Soft and brittle material – wear with care Zoisite Precious Tiger’s Eye Colour Moh’s Hardness Refractive Index Specific Gravity Brown with golden bands 7 1.550 2.58 – 2.64 Lustre Ultrasonic Steam Clean Special advice Usual treatment Transparency None known Opaque Gemstone family Type Silky Never Never Soft and brittle material – wear with care Quartz Ornamental Page 61 of 73 Topaz - Blue Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency Light to dark blue 8 1.619 – 1.627 3.53 Irradiated, heat treated Transparent, translucent Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Never Never Avoid thermal shock Topaz Precious Colour Moh’s Hardness Refractive Index Specific Gravity Rich golden yellow 8 1.629 – 1.637 3.50 – 3.54 Lustre Ultrasonic Steam Clean Special advice Usual treatment Transparency None known Transparent, translucent Gemstone family Type Vitreous Never Never Cleavage planes – wear with care Topaz Precious Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency White 8 1.609 – 1.620 3.56 – 3.57 None known Transparent, translucent Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous Never Never Avoid thermal shock Topaz Precious Shades of green 7 – 7.5 Lustre Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous to slightly resinous Never Never Avoid thermal shock Tourmaline Precious Topaz - Golden Topaz - White Tourmaline – Chrome, green Colour Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency 3.06 None known Transparent, translucent, opaque Tourmaline – Pink Colour Shades of green Lustre Moh’s Hardness Refractive Index Specific Gravity Usual treatment Transparency 7 – 7.5 1.614 – 1.666 2.82 – 3.32 None known Transparent, opaque Ultrasonic Steam Clean Special advice Gemstone family Type Vitreous to slightly resinous Never Never Avoid thermal shock Tourmaline Precious Page 62 of 73 Turquoise Colour Moh’s Hardness Refractive Index Specific Gravity Turquoise 5–6 1.610 – 1.650 2.60 – 2.9 Lustre Ultrasonic Steam Clean Special advice Usual treatment Transparency None known Translucent, opaque Gemstone family Type Waxy, matt Never Never Avoid hot water and household chemicals Aluminium Phosphate Ornamental Colour Lustre Vitreous to brilliant sheen Moh’s Hardness Refractive Index Specific Gravity Colourless, yellow, brown, orange, red, green, blue, violet 6.5 – 7.5 1.810 – 2.024 3.93 – 4.73 Ultrasonic Steam Clean Special advice Usual treatment Transparency Sometimes heat treated Transparent to translucent Gemstone family Type Usually safe Never Brittle material – wear with care Zircon Precious Zircon Note: All gemstones need to be checked for treatments, traditional, permitted and disclosable. All crystalline quartz stones must be worn with care as knocking the stone may cause chipping or breakage. b. How to Use a Jewellers Loupe The standard loupe for the jewellery and gem industry is a 10 x magnification triplet loupe which is corrected for colour (described as achromatic) and spherical aberration (aplanatic). Spherical aberration results in objects being out of focus at the edge of the field of vision. Buy the best quality you can afford, especially if you plan to use your loupe to later study gemmology. Most manuals recommend a loupe with a black housing to prevent reflected light causing a distraction when examining a gemstone or diamond. How to hold the loupe: 1. Establish which your dominant eye is. Most people usually see better through one eye than the other. The right eye of most right handed people is usually their dominant eye. Use your dominant eye for viewing through the loupe but remember to keep both eye open to prevent fatigue and eye strain. With practice you will become experienced in focusing through the eye with the loupe only. It may feel odd in the beginning but persevere. 2. Grip the loupe between your thumb and forefinger, though some texts suggest putting your finger through the loupe cover. Do what feels comfortable to you. 3. Bring the loupe up close to your dominant eye. If you wear glasses you can even rest the loupe against your spectacles. Rest your hand against your cheek or nose to form a stable platform. The focal point of a 10 x loupe is about 2.5 centimetres from the front of the lens. 4. To establish the working area of your loupe, look at a piece of graph paper through the loupe. Less expensive lower quality lenses will show distinct bending at the edges. (often only the central 80% of the lens is usable.). The lens may also show colour distortion at the edge if not corrected. Page 63 of 73 5. When viewing a stone held in a tweezers, bring the top of hand holding the tweezers to rest against the bottom of the hand holding the loupe so as to bring the item into focus. (The same goes when viewing a piece of jewellery without the tweezers). 6. You can now use the lower hand to “swivel” back and forth (with a wrist action) to bring the stone in the tweezers into clear focus - think of this as the fine adjustment. If the fingers of the two hands do not touch the item being viewed will move about and not stay optimally focused. Correct viewing position Close up view of hand positions Stable ergonomic work position Lighting position Note: Loupe hand held close to eye, supported against cheek. Tweezer hand held against loupe hand to create stable platform. When viewing a large number of items it is best to be seated at a workbench where you can support your elbows on the bench top to help form a stable position and to prevent muscle strain and fatigue. If you are viewing an item in the standing position, tuck your arms in to your sides for support and stability. Remember bring the object being checked to the loupe. Keeping a stable viewing platform is essential. The light source Use an adjustable desk lamp with a solid shade as your light source. It is important that the light from the lamp does not shine directly into your eyes. You want the light to angle into the side of the stone to illuminate the internal features so that they appear brightly lit and clearly visible against the dark background of the stone. This creates what is known as a dark field illumination. Page 64 of 73 c. Finger Size Comparison Chart Australian/UK/South Africa A B USA C 1 Europe 38 1.5 39 2 40 41 Inside diameter (mm) 12.07 12.10 12.34 12.41 12.46 12.73 12.75 12.85 13.05 13.16 Outside diameter (mm) 37.90 38.00 38.75 38.97 39.12 39.97 40.04 40.35 40.98 41.32 D E F 2.5 G 3 42 43 H 3.5 44 4 45 46 13.25 13.37 13.56 13.64 13.69 13.97 14.01 14.03 14.32 14.38 14.42 14.64 14.78 14.82 41.61 41.98 42.58 42.83 42.99 43.87 43.99 44.05 44.96 45.15 45.28 45.97 46.41 46.53 I J 4.5 5 47 48 49 K L 5.5 6 50 51 M 6.5 52 53 14.96 15.19 15.22 15.28 15.60 15.61 15.92 16.00 16.23 16.40 16.55 16.79 16.82 16.87 46.97 47.70 47.79 47.98 48.98 49.02 49.99 50.24 50.96 51.50 51.97 52.72 52.81 52.97 N O 7 54 P 7.5 55 Q 8 56 R 8.5 57 58 17.18 17.19 17.22 17.51 17.58 17.63 17.83 17.97 18.03 18.14 18.36 18.45 18.46 18.76 53.95 53.98 54.07 54.98 55.20 55.36 55.99 56.43 56.61 56.96 57.65 57.93 57.96 58.90 S 9 59 T U 9.5 60 V 10 61 10.5 62 63 64 18.78 18.87 19.10 19.15 19.28 19.42 19.55 19.74 19.76 19.94 20.05 20.17 20.33 20.37 58.97 59.25 59.97 60.13 60.54 60.98 61.39 61.98 62.05 62.61 62.96 63.33 63.84 63.96 W 11 X Y 11.5 65 Z 12 66 12.5 67 13 68 69 20.60 20.69 20.73 21.01 21.12 21.33 21.41 21.51 21.65 21.82 21.91 21.96 22.23 64.68 64.97 65.09 65.97 66.32 66.98 67.23 67.54 67.98 68.51 68.80 68.95 69.80 Page 65 of 73 d. Repair Take in Procedure 1. Record customer details, such as clients email address (so you can add to database), contact numbers and address. Also, with a mobile number you can text when the job is ready. 2. Confirm ownership. For example, is this your ring? 3. Do a thorough visual inspection. Use a loupe to check the conditions of the item and make the client aware of any defects you observe and write your findings on the take in document. If an item has a large build-up of dirt it should be noted that a full inspection is not possible. Following is a list of things to look for when noting the condition of the item. What you should look for: a. loose stones - usually found by gently prodding the stones with a pointed tip instrument b. chipped or abraded stones c. broken stones d. missing stones e. wear on claws f. claw tips that are missing g. broken or missing claws h. cracks in the ring shank - possible from previous sizing i. cracks in lower bezel of settings j. wear and damage to support rails of channel set stones k. general wear due to ageing - things that could affect serviceability of item l. worn links on chains and bracelets m. on pendants check the bails (loops) for wear n. any jump rings on an article need inspection for wear e.g. safety chain on a brooch or bracelet o. on items with a box snap, check the tongue for tension 4. Describe the piece. a. Identify the metals and stones by colour only – yellow or white metal, red or white stones – do not say gold or ruby and diamonds. If the client insists you note the metal or stone type, preface it with ‘client states stones are rubies’ etc. An example of a description is a yellow metal ring with a white metal 6 claw basket setting containing a round white stone with a total of 12 channel set round white stones in the shoulders. Ring is stamped ‘9ct’. b. Remember to note: i. Any hallmarks on the item ii. Record the finger size of a ring iii. The style of setting and the number of stones iv. For strands of pearls, record the number of pearls, length, size and clasp description. With graduated strands record the largest and smallest pearl sizes too. v. For chains, record the style, weight, length, colour and any stamped markings on the catch/clasp or individual links. Remember that your sketch and description will be used by the bench jeweller to ensure the right piece goes back into the packet after the polishing and cleaning which are usually done in a batch. The more information included the less chance of any confusion. 5. Record what the client wants to have done. Be precise so your bench jeweller is clear on what is required. If you have found several problems and a client is not having all the work done, record that they have declined your suggestion as this will protect you from a spurious warranty claim. Page 66 of 73 6. Do a sketch of the item. If you have facilities take a photo also. 7. Establish when the client needs the job back. This may affect the amount quoted depending on your stores policy. 8. Give an estimate of the costs involved. 9. Have your client check the information on the packet and sign acknowledging the description, what to be completed and quote, if one has been noted. Provide the client with a copy of the take in document and ask the client to copy of the docket back when collecting the left item which must be signed for on collection. Note: A large magnifier at the take in counter will help show the client any wear and damage. It is a good idea to work over a soft cloth to protect items against accidental damage from dropping. e. Refunds and returns We are not required to provide a refund or replacement if you change your mind. However, you can choose a refund or exchange if an item has a major problem. This is when the item: • Has a problem that would have stopped someone from buying the item if they had known about it • Is unsafe • Is significantly different from the sample or description • Doesn’t do what we said it would, or what you asked for and can’t be easily fixed. Alternatively, you can choose to keep the item and we will compensate you for the drop in value. If the problem is not major, we will repair the item within a reasonable time. If it is not repaired in a reasonable time you can choose a refund or a replacement. Please keep your proof of purchase e.g. your receipt f. Lay-by and Special Order Procedures Special Order Terms and Conditions 1. Special orders are subject to a 50% deposit. The balance is payable on collection of goods. 2. Cancellation due to change of mind is subject to a 50% cancellation fee. I agree to the Terms and Conditions as specified above: Lay-by Agreement Terms and Conditions 1. The ownership of the Lay-by items will not pass to the consumer until the total price has been paid and the terms and conditions of the Lay-by contact have been fulfilled. 2. This contract is subject to an initial deposit, subsequent regular payments and a maximum Lay-by period as specified below. 3. Should the consumer fail to make payments when they fall due or meet any other conditions of the Lay-by contract the contract will be deemed to have been cancelled by the consumer. 4. It is the responsibility of the consumer to inform the retailer of any change of address or contact details. 5. Lay-by Cancellation by the Consumer. Page 67 of 73 A consumer can cancel the Lay-by agreement at any time before delivery of the goods. In such cases the retailer must refund all amounts paid by the consumer, less any Lay-by cancellation fee as specified below. If the consumer’s Lay-by payments do not cover the termination charge, the retailer can recover the outstanding amount as a debt. 6. Lay-by Cancellation by the Retailer. A retailer can only terminate a Lay-by when: • The supplier is no longer engaged in trade or commerce or • The goods are no longer available due to circumstances outside the retailer’s control 7. A retailer who cancels the Lay-by agreement cannot charge a termination fee. 8. Lay-bys of more than one item can be separated only if full payment for the item/s handed to the consumer have been received and the appropriate deposit is still left on the remaining item/s. g. Special Care Guide Be careful with light and heat Just as the sun’s harmful rays can damage our skin, light and heat can affect a coloured gemstone’s durability and colour. Over time, and in excess, they can also fade or damage some gemstones, such as amethyst, kunzite, topaz and shell cameos. Pearls and other delicate materials, such as ivory, will bleach under extreme exposure to light. Other gems, especially amber, can darken over time when exposed to too much light. Excessive heat and sudden temperature changes may also fracture some gems. Heat can easily remove the natural moisture these gems need to keep their beauty. Pearls, for instance, can dry out, crack and discolour. Opals can turn white or brown, develop tiny cracks, and might lose their play-of-colour. Keep your jewellery away from chemicals Exposure to chemicals can damage or discolour precious metals – gold, silver and platinum – and may harm some coloured gems. Even everyday substances like hairspray, lotion, perfume or other cosmetics can contain chemicals that will permanently damage the surface of your pearls and other delicate or porous gems (like turquoise). Fine jewellery should be removed before diving into a chlorinated swimming pool or before using household cleaners. Many of these cleaners contain ammonia, which can be too harsh for delicate gems or vintage jewellery. Chlorine bleach, another common household solvent, can pit or damage gold alloys. Give treated gems special care Many coloured gemstones are routinely treated to improve the appearance of colour and clarity. These treatments can be negatively affected by heat, solvents, steam and ultrasonic cleaners. Knowing whether a gem has been treated is the first step to knowing how to care for it. Refer to 3.a Gemstone Specifications and Care Chart for more information. Page 68 of 73 Use ultrasonic cleaners with caution Be aware that not all gems and jewellery can be safely cleaned in an ultrasonic cleaner. Ultrasonic cleaners should not be used to clean: 1. Gemstones with surface-reaching breaks that have been filled with a substance such as oil, resin or a glass-like material 2. Organic gem materials such as pearls, coral, ivory, or amber 3. Gems that have been coated with a non-permanent substance like plastic or wax 4. Some heat-treated gemstones 5. Gems that are susceptible to heat and temperature changes whether they are treated or not. Some of these gems include tanzanite, feldspar (sunstone and moonstone), fluorite, iolite, kunzite, lapis lazuli, malachite, opal, topaz, turquoise, zircon and others 6. What’s more, the vibration generated by the machine can sometimes shake gems loose or chip gems that are set with their girdles touching. Refer to 3.a Gemstone Specifications and Care Chart for more information. Safest cleaning methods Most coloured gems can be cleaned with warm water, mild dish soap (no detergents) and a soft brush. A pulsed-water dental cleaning appliance and a soft, lint-free cloth can also be used. Be sure to rinse jewellery in a glass of water to remove cleaning solutions since there is a risk of losing loose stones – or even an entire piece of jewellery - if it is rinsed directly in the sink. Soft gems, such as pearls, on the other hand, can easily scratch. Use a new, clean makeup brush and warm, soapy water to softly clean them. Lay a strand of pearls on a towel to dry. The wet silk thread can stretch and attract dirt− so don’t touch the strand until it is completely dry. Pearls worn often should be restrung once a year. Safely store jewellery Proper jewellery storage is often overlooked. Jewellery should never be tossed into a drawer or on top of a dresser as there is a higher risk of scratches and damaged gems. Most jewellery pieces come in a box or pouch from the store, which is a perfect place to keep them. Sterling silver, for example, should be kept in an anti-tarnish bag or cloth. Jewellery boxes that feature individually padded slots for rings and posts for hanging necklaces and bracelets are also ideal. Pearls and opals draw moisture from the air, so storing opal or pearl jewellery in a dry area, such as a safe deposit box, can sometimes do more harm than good. When traveling, protect jewellery pieces from scratches or other impact damage by padding it in a separate box or case. Jewellery should be checked every six months and cleaned frequently. Page 69 of 73 4. OTHER INFORMATION a. Specific Gravity Chart Weight Conversion between metals (To find the weight of an article in a metal different from that in which it is now) ITEM IN YOUR HAND METAL YOU WANT TO MAKE Wax Silver 9ct 14ct 18ct 22ct Wax x 1.00 x 10.49 x 11.30 x 12.90 x 15.10 Silver x 0.10 x 1.00 x 1.08 x 1.23 9ct x 0.09 x 0.93 x 1.00 14ct x 0.08 x 0.81 18ct x 0.07 22ct (fine) Platinum x 17.60 x 19.32 x 21.45 x 1.44 x 1.68 x 1.84 x 2.04 x 1.14 x 1.34 x 1.56 x 1.71 x 1.90 x 0.88 x 1.00 x 1.17 x 1.36 x 1.50 x 1.66 x 0.69 x 0.75 x 0.85 x 1.00 x 1.16 x 1.28 x 1.42 x 0.06 x 0.60 x 0.64 x 0.73 x 0.86 x 1.00 x 1.10 x 1.22 (fine) x 0.05 x 0.54 x 0.58 x 0.67 x 0.78 x 0.91 x 1.00 x 1.11 Platinum x 0.04 x 0.49 x 0.53 x 0.60 x 0.70 x 0.82 x 0.90 x 1.00 24ct How to use this table: Formula: 1. Weight the item in your hand 2. Find the metal of the item in your hand in the left column 3. Find the number in the same horizontal row under the vertical column of the metal you want to make 4. Multiple the weight of the item you hold, by the number Example: 24ct You have a 9ct ring weighing 8 grams. What will it weigh in 18ct? 1. Along the horizontal row marked “9ct”, and in the vertical column under the heading “18ct” we find the factor 1.34 2. 8 grams x 1.34 = 10.72grams in 18ct b. Mohs Hardness Table The Mohs scale of hardness was an attempt by an Austrian mineralogist to set up a comparative scale of scratch resistance. Low numbers are soft whilst high numbers are harder. The scale is not linear and all that can be said is that higher numbers are harder than all the numbers lower down the scale. An example of this is that a diamond, which is 10 on the Mohs scale, is in fact 4 times as hard as corundum (ruby and sapphire), which is a 9 on the Mohs scale. The minerals chosen were selected on the basis that there is only minor differences between various samples due to slight chemical differences. Hardness 1 2 3 4 5 Mineral Talc Gypsum Calcite Fluorite Apatite Gemstone Gem Hardness Pearl Coral 3.5 3.75 Sphene Window glass (not a gemstone) 5 5.5 Page 70 of 73 6 Orthoclase Feldspar 7 Quartz 8 Topaz 9 Corundum 10 Diamond Opal Silica glass Turquoise Lapis-Lazuli Peridot Nephrite (Jade) Chalcedony Tourmaline Jadeite Garnet (most types) Zircon (most types) Beryl Spinel Chrysoberyl Synthetic cubic zirconia Ruby Sapphire 5.5 6 6 6 6.5 6.5 6.5 7 7 7.0 7.0 7.0 8 8.5 8.5 9 9 – 6.0 – 7.5 – 7.5 – 7.5 Note: A scratch test should never be performed on a cut gem as it will damage its surface. The scale does provide a guide as to the suitability of using a gem in a piece of jewellery. Page 71 of 73 b. Birthstones Tradition has it that each month has a colour that some people believe is lucky for people born during that month. Myths and legends have grown up over the years that make claims for these stones having special “healing powers”. It is believed that the origin of this tradition goes back to biblical times and is associated with the twelve stones that the Bible tells us were affixed to the breast plate of Aaron, the High Priest, one for each of the twelve tribes. January February March April May June c. Garnet Amethyst Aquamarine Diamond Emerald Pearl or Alexandrite July August September October November December Ruby Peridot Sapphire Opal or Tourmaline Topaz or Citrine Tanzanite, Zircon or Turquoise Wedding Anniversary stones 1st 2nd 3rd 4th 5th 6th 7th 8th 9th 10th d. Gold Garnet Pearls Blue Topaz Sapphire Pink Tourmaline Amethyst Onyx Tourmaline Lapis Lazuli 11th 12th 13th 14th 15th 16th 17th 18th 19th 20th Diamond Turquoise Jade Citrine Ruby Peridot Watches Cat’s Eye Aquamarine Emerald 21st 22nd 23rd 24th 25th 30th 35th 40th 45th 50th Iolite Spinel Imperial Topaz Tanzanite Silver Pearl Emerald Ruby Sapphire Gold 55th 60th 65th 70th 80th Alexandrite Diamond Blue Spinel Sapphire Ruby Valuations What is a valuation? A jewellery valuation (also known as a valuation certificate) is a document that describes an item of jewellery in detail and also states the value of the item in question. Why is a valuation needed? While there are a number of reasons why consumers may require a valuation certificate when buying an item of jewellery, the most common reason is for Retail Replacement purposes and the vast majority of valuations that are produced for jewellery are required for insurance purposes. Unspecified Jewellery Items Most insurance companies will insure unspecified jewellery items up to a total value of approximately $5,000 and a maximum value of each item of approximately $1,500, as part of a home and contents policy. When a loss is suffered and a claim is lodged, the insurance company in question will request proof of purchase and proof of the value. (Inexplicably insurance companies do not usually request this at the time a policy is first issued.) Proof of value will not necessarily require Page 72 of 73 a formal valuation certificate but a sales docket from the retailer giving a detailed description of the piece concerned and the price paid should be provided. Most jewellery claims fall under the unspecified jewellery category and consumers are strongly advised to ensure they can provide proof of purchase and value. This means keeping a copy of the sales docket in a safe place. Consumers should photograph their jewellery items as close up as possible as the photographs can be used to assess proof of purchase and the value, should the sales docket be lost. Specified Jewellery Items Most insurance companies insist on a valuation certificate and proof of purchase for items of jewellery valued above $1,000 to $2,000 (depending on the insurance company involved) before issuing insurance cover. Valuation Certificates Consumers should be aware of the fact that there is no legal obligation for a jeweller to issue a valuation certificate when an item of jewellery is purchased. However, most professional jewellers will often offer to provide a valuation certificate, particularly for items above $1,000. Please note that some jewellers may charge a fee for producing a valuation certificate. When a new item of jewellery is purchased from a jewellery retailer, a valuation certificate from the retailer is acceptable as long as a full and detailed description of the jewellery item appears on the certificate and, most importantly, the valuation figure that appears on the certificate is the same as the price actually paid. A valuation certificate for insurance purposes is supposed to reflect the market price of the item and the price paid is by definition the market price. The only exception to this is when a retailer who has one or two genuine clearance sales per year sells a product at a genuine discounted price and where that retailer believes that it would not be able to replace the item for the price actually paid. For pre-owned jewellery we recommend consumers use a Registered Valuer to value their jewellery or check that the person valuing your jewellery has the appropriate qualifications for assessing jewellery. Please visit www.ncjv.com.au for a listing of available valuers in your state. Page 73 of 73
