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- --------------ifl.~·~···CD-~,,. . !!P SAILING. THE THIRTEENTH CHESAPEAKE SAILING YACHT SYMPOSIUM Development of Proposed ISO 12217 Single Stability Index for Mono-Hull Sailing Craft Dr. Peter van Oossanen, Van Oossanen & Associates, Wageningen, The Netherlands ABSTRACT states, technical standards exist, not backed by national legislation, thereby not creating obstacles to trade but, since these are not enforced, no guarantee exists against the production and the sale of potentially dangerous boats and yachts. For more than 5 years now, Working Group 22 of Technical Committee 188 of the International Standards Organization (ISO) has been developing a standard for the assessment and categorization of the stability of pleasure craft with a length up to 24 m. This work became necessary when the European Union decided to issue a Directive on Pleasure Craft, facilitating the export and import of pleasure craft to and from the various countries comprising the European Union. All newly-built pleasure craft up to 24 m in length, to be marketed in the European Union, must comply with the stability standard being developed, and some 50 other ISO standards, covering all aspects of structure, materials, equipment, etc, as of June 1998. For these reasons, the International Council of Marine Industry Associations (ICOMIA), in 1988, decided to propose to the European Commission that a Directive on Recreational Boats be prepared, to remove existing barriers to trade and to ensure that all recreational craft comply with certain technical requirements. This Directive on Recreational Boats was completed in 1994 and passed by the European Parliament in 1996. It requires that as of June 1998, all recreational boats that are to be marketed in the European Union must comply with the requirements set therein and in the associated technical standards being developed by various working groups of Technical Committee (TC) 188 of the International Standards Organization (ISO), or acceptable alternatives thereto. As of June 1996, recreational boats may already be certified in accordance with these requirements. To support the work of Working Group 22, The Netherlands carried out a comprehensive study for Part 2 of ISO 12217, covering the stability of mono-hull sailing craft. Together with the French, Swedish and UK delegates, this work finally lead to the development of a single stability index. Working Group 22, in September 1996, unanimously agreed to adopt this concept for the assessment and categorization of the stability of mono-hull sailing vessels. This paper gives a description of some of the work that was carried out by the Netherlands in this regard and gives a description of the single STability Index (STIX) concept and the way the STIX value is determined from the various stability and buoyancy properties of sailing vessels. 1. Working Group 22 (WG 22) of TC188 is preparing ISO Standard 12217 on stability and buoyancy. This Standard is of particular importance among the 50-plus standards presently being developed for use in conjunction with the European Directive on Recreational Craft as it will, for the first time in many countries of Europe, indicate specific safety measures that will have to be met with regard to both stability and flotation. ISO 12217 is divided into 3 parts. Part 1, ready to be issued as a Committee Draught (CD) at the time of finalizing this paper, addresses non-sailing vessels of over 6 m in length. Part 2 addresses sailing vessels of over 6 m in length, and Part 3 addresses all boats under 6 m in length. INTRODUCTION In Europe, effective barriers to trade exist due to the fact that some countries impose technical requirements based on national legislation, involving approval of all recreational craft. Particularly France and Italy impose such regulations. In other member 97 In ISO 12217-2, sailing vessels are divided into 3 types, viz: Sailing vessels (mono-hull and multi-hull) reliant on the use of crew weight for capsize recovery; Mono-hull sailing vessels; Multi-hull sailing vessels. The technical content of this paper covers the work carried out up to October 1996, the results of which have all been made available to Working Group 22. This paper should not be taken as representing the final content of ISO 12217-2. Further discussions in the working group during the coming months will no-doubt lead to changes to some parts of the formulae and requirements as described here. 2. BASIC CONCEPTS ADOPTED IN THE WORKING DRAUGHT OF ISO 12217-2 WITH RESPECT TO SAILING CRAFT various countries in Europe will divide geographical regions into categories based on wave height and wind speed. It would not be logical, for example, to sub-divide geographical regions based on the highest wave height or highest wind speed ever recorded in a region. It would be more logical to calculate the significant wave height and wind speed over a number of years, based on records which exclude the highest 2% or 5%. This percentage is arbitrary and must be chosen carefully to arrive at logical conclusions. After consultation with the National Meteorological Institute, the authorities in the Netherlands decided that the lakes, canals and rivers in the Netherlands constitute Category D water, while the IJsselmeer and the Scheide estuaries constitute Category C water. Likewise, the North Sea, IO miles or more from the coast, constitutes category B water. These sub-divisions are based mainly on recorded wave height, with 5% of the highest values discarded. This latter topic will not be considered here in any further detail as it is mainly the subject of the socalled Notified Bodies responsible for the certification process in the various countries. In the stability (and other) standards, a specific set of design conditions are associated with a specific set of requirements without further discussion of which geographical regions are implied. The requirements set out in the Standard depend on the so-called Stability Category to be assigned to a vessel. Stability Category I, intended for vessels that can sail anywhere in the world, demands that the highest values are met, while Stability Category IV, intended for vessels sailing in restricted waters such as small lakes and rivers, requires that relatively low values are met for the various requirements. Table 1. Stability categories as defined in the present draught of ISO Stability Standard 12217. No specification is given in the Draught Standard with respect to the geographical areas that pertain to Stability Category I through IV. Instead, design criteria are given for values of the significant wave height and wind speed that vessels in each category are expected to be able to endure without impairing the safety of the vessel. These categories are defined in Table 1. Stability/Design Category These stability categories were chosen by Working Group 22 to coincide with the so-called Design Categories in the European Directive. Design category A (termed "Ocean" in the Directive), calls for a design wind force in excess of 8 Beaufort and a significant wave height in excess of 4 meters (4 to 8 meters in the stability standard). Hence stability category I in the stability standard coincides with design category "A" in the Directive. Similarly, stability category II coincides with design category "B" in the Directive, III with "C", and IV with "D". Significant Wave Height in meter Wind Speed in m/sec I/A 0 to 8 25 11/B 0 to 4 21 111/C 0 to 2 17 IV/D 0 to 0.5 13 For sailing vessels reliant on the use of crew weight for capsize recovery, requirements have to be met with respect to flotation and stability in the swamped condition. For other sailing craft, a major division is made between vessels that are susceptible to swamping and vessels that are not susceptible to swamping. Fully decked vessels having recesses of These design criteria have been the subject of considerable discussion, since it is not clear how the 98 3. limited (small) size, or vessels with selfdraining cockpits/recesses as specified in ISO 11812, are distinguished from vessels that are not fully decked or vessels that have moderate to large non-selfdraining cockpits/recesses. The latter type of vessel cannot be assigned stability category I or II (see also Paragraph 6.6). OUTLINE OF STUDY CARRIED OUT BY THE NETHERLANDS IN SUPPORT OF THE WORK OF WORKING GROUP 22 To support the work of Working Group 22, the Netherlands carried out a study of the stability characteristics of mono-hull sailing vessels. This study, supported by the Government, the National Association of Water Sports Industries (HISWA) and some 70 individual companies involved in the design and building of recreational craft in the Netherlands, was aimed at analyzing the characteristics of so-called stability casualties and the characteristics of craft with a well-proven performance record. A further general requirement is stipulated with respect to mono- and multi-hull vessels with a limited range of positive stability (less than 90 degrees). These vessels can only be assigned stability category I and II when the subject vessel will not sink after a knock-down or an inversion (from which such a vessel cannot recover). Such vessels are required to posses 20% more volume in the hull, fittings, and equipment than the loaded displacement volume, not including trapped air (apart from air in air tanks and in watertight compartments). In the first instance, in 1993 and 1994, stability data was collected for about 115 sailing vessels of all types. Particular attention was focussed on vessels that suffered a knock-down from which they did not recover, an inversion (usually referred to as a capsize), a sinking, or some other stability-oriented casualty. Next, the resulting data base was analyzed with a view to obtaining insight as to the range of values of various stability parameters associated with a stability casualty and with a well-behaved vessel in this respect. It was found that particularly important parameters are the value of the angle of vanishing positive stability, the value of the righting lever at 90 degrees of heel, and the area under the righting moment curve up to the angle of vanishing stability. It was also found that the downflooding angle, i.e. the heel angle at which a critical amount of water enters the non-selfdraining part of the hull, is a dominant factor playing a decisive role in the righting behaviour of a yacht after a knock-down or an inversion. Apart from the specific requirements with respect to the stability characteristics of a vessel, requirements are also imposed on the minimum freeboard or the so-called minimum downflooding height. This is the least height in meter above the waterline to any point at which water begins to enter the interior or non-selfdraining part of the vessel (whether cockpit or bilge) when it is floating upright, fully loaded in calm water, except for the following which is not to be considered in this respect: Selfdraining recesses complying with ISO 11812; Drains from watertight recesses with a combined volume less than 0.025Lhull· Bhun·FM, in which Lhull and Bhull are the length and beam of the hull according to ISO 8666, and FM the freeboard amidships; Non-opening appliances which are watertight to degree 2 of ISO 11812 or ISO 12216; Openings in the sides of outboard engine wells in certain cases. During 1994 and 1995, the Netherlands work was focussed on defining minimum values of each of the important parameters, for each of the 4 stability categories. The results thereof were presented to WG 22 at various meetings and thoroughly discussed. Generally, the minimum downflooding height is Lhuuf 17 with absolute minimum values of 0.5 m for stability category I, 0.4 m for stability category II, 0.3 m for III and 0.2 m for IV. Alternatively, a rigorous method may be adopted, explained in an annex, to calculate the absolute minimum required downflooding height for a specific vessel. Late in 1995 and in the beginning of 1996 it became apparent to all members of WG 22 that unanimous agreement on the required minimum values for each of the important stability parameters was unattainable. Where one country, for example, wanted to require a moderate minimum value of the angle of vanishing stability and a high minimum value of the downflooding angle, another country wished to impose a relative high minimum value of the angle of vanishing stability and a moderate minimum value of the downflooding angle. It was Finally, specific requirements are also set with respect to the value of the minimum downflooding angle. 99 accurate values. Using such refined values of LPS and RM90, it should be possible to use an IMS stability calculation as a basis for a first estimate to determine whether or not the requirements imposed by ISO Standard 12217-2 are met. then decided to appoint a small group of experts to devise a system in which a high value of one parameter could be traded-off against a low value of another parameter, wherever possible. This group worked through the summer of 1996, resulting in the concept of a single stability index presented in Paragraph 6. At the meeting of WG 22 held in Paris in September 1996, it was unanimously decided to adopt this method for the assessment and categorization of stability for mono-hull sailing vessels. 4. Some of the casualty data was supplied on the basis that these be used in a statistical sense only, i.e. that the name or type of yacht, its designer and builder, not be mentioned in a report or paper. The information given in this paper in this respect is therefore only representative. No effort has been made to provide a full set of pertinent sailing vessel data. COLLECTION OF ST ABILITY DAT A Requests for stability data on mono-hull sailing vessels of all kind were requested from more than 65 sources world-wide. In particular, information was requested on sailing craft that had experienced a serious knockdown, an inversion, a sinking or some other stability-oriented casualty. Together with data collected by other members of Working Group 22, 115 sets of stability data for sailing craft were collected over a period of about 8 months. About 30 sets of data involved vessels that had suffered a stability-oriented casualty of one kind or another. Although many sailing craft were identified as having been knocked down and inverted, the necessary particulars were only actually obtained for about 30 sailing vessels. Table 2 lists particulars of some of these casualties. Table 3 lists the particulars of the 30 category I sailing craft in the compiled data bank with the lowest angle of vanishing stability. Stability category I sailing craft (in this study) are those with a long operational history without any stability-oriented problems. The category I designation was given by the designer and/or the builder. That is, the respective designer and/or the builder considers these vessels to be suitable to sail anywhere in the world. It is explicitly noted here that Table 3 gives a list of those 30 vessels that have the lowest value of the angle of vanishing positive stability and/or the lowest value of the righting lever at 90 degrees of heel. The data base includes data for 55 other vessels with greater stability values. All of the stability data collected constituted socalled "rigorous" data, obtained by taking into consideration deck camber, deck houses and structures, and floodable recesses such as cockpits. During the course of this study significant discussion ensued concerning the error involved in considering a flush deck, without taking into account the effect of deck camber, deck structures and cockpits. The reason for this is that the Offshore Racing Council (ORC), responsible for the International Measurement System (IMS), has on file stability information of thousands of yachts based on inclining experiments, which could have been made available for this stability study through the Chief Executive of ORC (also a member of WG 22). This stability information however does not include the effects of deck camber, deck structures or cockpits. The outcome of these deliberations was to request ORC to carry out a systematic series of stability calculations for a number of IMS yachts with deck camber, systematically-varied deck structures and cockpits, and sealed masts. The results of these calculations, discussed in Paragraph 5.1.3, has allowed the development of approximate expressions for the effect of deckhouses, cockpits, etc, on the vanishing angle of positive stability and the righting lever at 90 degrees of heel. With these approximate expressions the respective IMS stability entities (referred to as LPS and RM90) can be refined to obtain more The data collected was for the so-called "minimum sailing" condition. In this condition all tanks are considered 10% full with sails hoisted and a minimum crew on-board. For a sailing vessel this is generally considered to be the condition in which stability is least. During the course of collecting this data it became clear that serious knockdowns and capsizes happen more frequently than often supposed. Detailed information was obtained from the Royal National Lifeboat Institution (RNLI) in Dorset, England, revealing that every year the services by RNLI lifeboats to sailing yachts that have suffered a capsize, number at least 20. A similar number of capsizes are reported by the equivalent Netherlands Institution. In all, it was not difficult to pin-point more than 100 recent stability-oriented casualties. It was 100 extremely difficult, however, to obtain the required rigorous stability data of most of these vessels to render them suitable for analysis. 5. been discerned. The analysis of the 1979 Fastnet race casualties (see the list of references) has shown that in the same adverse conditions the smaller boats were generally more vulnerable, as could be expected. It stands to reason therefore that stability requirements for small vessels must be relatively harsher than for larger vessels. ANALYSIS OF STABILITY DAT A 5.1 Minimum Angle of Vanishing Stability 5.1.1 Differentiation Between "Good" Vessel Data Casualty and In connection with this last observation, it should be noted that the requirement of a lower value of the angle of vanishing positive stability for larger vessels is not because these vessels recover from an inversion more easily, but rather because a larger excitation force is required to cause a knockdown in the first place. If the premise for developing stability criteria were to be such that an inversion has to be avoided irrespective of the chance of getting knocked down, the only correct criterion to be applied would be one demanding a specific minimum vanishing angle of positive stability for all vessels, irrespective of their size. On the basis of accepting a specific, small risk in setting safeguard criteria, the adopted approach of requiring a lower angle of vanishing stability for larger vessels, in connection with being able to recover from an inversion, as adopted here and in the past, can be defended. A plot of the angle of vanishing positive stability (<l>v) against overall length L0 ., for all vessels specified in Tables 2 and 3, is shown in Figure I. The lines shown herein approximately divide the points for most of the casualties (indicated by pluses) from those for "good" category I vessels (indicated by squares). On the basis of Figure I and Table 2 it is possible to make a number of important observations, as follows: Three casualties are located amongst the socalled "good" category I vessels. A study of the particulars given in Table 2 for case studies 5, 8 and 14, reveals that these three yachts experienced an inversion in high seas and recovered, with extensive damage. Although the sailing craft associated with case studies 2, 4, 6 and 9 also recovered, the sea conditions in these latter cases were nothing like the extreme conditions associated with cases 5, 8 and 14. It is not possible, on the basis of the plot in Figure 1 alone, to define a boundary for the minimum required angle of vanishing positive stability. The line drawn provides insufficient latitude between the so-called casualties and "good" category I vessels. Other presentations of this data was therefore investigated. The stability characteristics of the sailing craft associated with case studies 5, 8 and 14 in Table 2, are as good as those of the "good" category I vessels (see Table 3). Accordingly, it stands to reason that the "good" category I vessels could also have been knocked down in conditions experienced by these three vessels. It also follows that a high value of the vanishing angle of positive stability will therefore not prevent a knockdown from occurring but will ensure that the vessel is capable of righting itself, even after having been totally inverted. The energy associated with a knockdown is probably more dependent on the mass of the vessel than on the length of a vessel. Accordingly, a plot of vanishing angle against displacement mass is presented in Figure 2. In this figure a significantly greater latitude is seen to exist between the casualty data and the data for the "good" category I vessels, due to the fact that the so-called casualties mostly constitute sailing craft with a small displacement. A less arbitrary line can now be defined to distinguish between the casualties and the "good" boats considered. This line is shown. Accordingly, it was decided to develop a proposal for the minimum value of the angle of vanishing positive stability based on the results of Figure 2. This is further discussed in Paragraph 5.1.2. The minimum required value of the angle of vanishing positive stability is clearly dependent on the size of the vessel. For overall length values in excess of about 22 meters, the minimum value of <Pv would seem to be in the order of about I 00 degrees. For lengths of I 0 meters and less, this value would seem to be about 130 degrees. This trend with size has previously 101 Table 2. Particu lars of sailing craft that have suffered stability-orien ted casualties. # LOA BoA BwL Tc D 4101 GM GZ 90 cl>v #1 6.50 2.85 2.15 0.25 1.20 1.50 0.85 0.34 I IO #2 7.0I 2.70 2.I8 0.35 1.10 1.82 0.88 0.17 103 #3 7.32 2.72 0.30 1.03 1.70 0.1 I 99 #4 7.49 2.74 2.22 0.39 1.23 2.30 0.8I 0.20 II2 #5 8.08 3.20 2.79 0.4I 1.37 4.55 1.35 0.56 133 #6 8.56 2.96 2.44 0.42 1.36 3.1 I· 0.88 0.28 II2 #7 9.I4 3. I4 2.47 0.44 I .4I 3.77 0.85 0.27 II7 #8 10.l 3.40 2.76 0.49 1.50 4.5I 1.33 0.58 132 #9 10.5 3.58 2.85 0.50 1.50 5.30 1.08 0.28 109 #IO 11.1 3.59 3.10 0.70 1.58 12.2 1.15 <O 68 #lI 14.3 3.83 3.22 0.45 1.58 7.92 1.75 0.33 114 #12 17.4 3.60 3.54 0.41 1.45 14.7 1.89 <O 65 #13 18.0 0.26 98 #I4 I9.7 4.96 #15 19.8 #I6 14.3 4.58 1.01 2.41 30.3 1.45 0.59 122 5.94 64.9 1.86 <O 75 26.7 7.01 136 <O 57 #17 27.3 7.0I #I8 28.0 6.40 Notes #I #2, 4, 6 and 9 #3 #5 #7 #8, I4 #10, I2 #I I #I3 #15,16, 17, 18 6.78 2.2I 3.22 124 1.86 <O 88 I67 0.6I <O 57 Knocked down/inverted and sank with loss of life (various vessels); Knocked down in moderate to high seas and recovered with minor damage (more than one vessel in each class); Knocked down/inverted: most vessels recovered with minor damage : some were swamped (various vessels); Rolled 360 degrees in extreme seas: recovered with loss of rig; Knocked down, inverted and recovered after about 45 minutes: subsequ ently sank with loss of life (various vessels of same type were subject of similar casualti es); Knocked down and inverted in extreme seas: recovered with extensiv e damage; Capsized and sank in shallow water due to wind gust (vessels were retrieved); Knocked down & inverted: after one hour righted and swamped, and subsequently sank with loss of life; Capsized and sank; Capsized and sank with loss of life. 102 Table 3. Particulars of saili11 g craft designated as category I by their designers/builders, with a long operational history without : my stability-oriented problems. # LoA BoA BwL Tc D alot GM GZ90 <Pv #1 7.99 2.80 2.28 0.35 1.37 2.50 1.07 0.58 135 #2 9.00 3.20 0.44 128 #3 9.40 3.37 #4 10.5 3.60 #5 10.5 #6 10.7 3.49 #7 11.5 3.81 #8 12.0 3.89 #9 12.7 #10 3.10 2.82 4.32 0.99 0.53 132 6.96 1.20 0.56 131 6.25 1.31 0.54 130 6.21 0.88 0.62 135 8.67 1.39 0.54 129 8.41 1.19 0.44 121 4.07 10.7 1.31 0.65 132 13.l 4.16 12.l 1.44 0.58 129 #11 14.1 4.20 2.50 18.5 0.90 0.55 130 #12 15.5 4.17 2.94 31.8 0.63 0.28 126 #13 16.1 4.80 18.6 1.38 0.65 126 #14 16.9 4.33 27.3 1.00 0.40 124 #15 17.0 4.70 3.25 42.4 0.98 0.32 123 #16 17.5 4.47 3.87 1.23 2.31 21.4 0.86 0.40 118 #17 17.7 5.05 4.30 1.02 2.43 30.6 1.36 0.53 121 #18 18.5 5.25 0.52 119 #19 19.9 4.96 #20 20.5 5.26 4.65 #21 21.1 5.22 4.70 #22 21.5 5.49 #23 21.6 #24 21.7 5.71 5.55 1.69 #25 22.l 5.75 5.14 #26 22.8 5.30 #27 23.l 6.00 #28 24.0 6.07 #29 28.1 6.80 #30 28.2 6.48 2.85 3.28 3.72 0.48 1.43 0.56 1.69 1.73 0.58 0.94 26.7 2.95 77.2 0.87 0.14 107 1.10 2.44 41.1 1.33 0.54 122 1.25 2.17 42.2 1.24 0.23 104 3.03 87.4 1.13 0.10 102 48.7 1.28 0.19 101 3.18 74.9 1.03 0.50 102 1.06 2.51 40.6 1.89 0.65 118 4.42 1.26 2.55 38.1 1.10 0.22 102 4.91 0.91 2.51 45.0 1.53 0.15 97 1.02 2.88 56.6 1.32 0.32 111 6.37 1.46 3.00 98.6 1.75 0.37 106 5.89 1.48 3.00 85.9 1.21 0.25 103 103 5.1.2 On the basis of considerable consultation with various designers, builders and experts, a proposal was prepared and forwarded to Working Group 22, consisting of minimum criteria for vanishing angle of positive stability, for each of the four stability categories, as follows: Proposals for Minimum Value of the Vanishing Angle In Paragraph 5. l.l a summary is presented of the work that was carried out using the 115 sets of rigorous stability data to derive a meaningful trend for the value of the vanishing angle of positive stability with vessel particulars. An account is there presented of how a sufficiently useful demarkation between the casualty data and the "good" category I data can be obtained, using only the mass of the vessel. This is an important result since the mass of a sailing vessel is always available or easily determined. $v > 130 - 0.750A.,,, for A.,, < 40 (category I) $v > 120 - 0.625A.,,, for A.,, < 40 (category II) $v > 110 - 0.500A.,,, for A.,, < 30 (category III) Here, the results of Paragraph 5 .1.1 are further elaborated to derive a set of proposed criteria for vanishing angle of positive stability for the different stability categories. $v > 95, for all A.,, (category IV) $v > 100, for 11m > 40 (category I) $v > 95, for 11m > 40 (category II) $v > 95, for 11m > 30 (category III) • "goc>cP: calegory I ...... - .....- - .......-- -·' -- - - - --- -~ -- .... -- .... -*-~~ -~:- ..... 140 "":. I I ...... 100 I I • I • • I I I I I I I I -.. ---.. . _: _-.. . ---.. . ~ -.+. . --~ :- -~-. . . . ._.. ._. ---.. -_:_ . --·- ---*.~ -.. --.. . -..:.. --.. --.. . -~' ---.. I I I I ....... •• I ....... I • I I ....... • • I • I I I I I I I ~ . +-.... . . -. -... -_: _-. --+ ±:.+ .. ±· - ~. - - - .. - .-::::--....... - .. - ; . - - - .... -~- - . - - .. - . ~ - - . .:• . . .:'........ . .: ' .: .: +.: : ~d8Gr:) ·: ---.. --+ :· --... --. ·: --.. -.... :· -..-f ... : .. !t' :.:..:_ ~ ~ ~ -~ ~ ~~ ~ ~ I o O ...... I I 110 --.. --._:_. ---.-.-~ --.. : : : : ;. . . . . -l- • : --.. . --.. _: . -.. -~ _. . _ . . -'" -.. ~ +1 . -~ -~ --.-.. --:. . -.. . ----:-.. --.. . -.. .:-.. . ------:--....... 130 120 ' I I I I I I I I I I I ...... ..... ...... • IO . --.. . --·: ·. ---.. . -·:· . ---.. . --·: . ---.. . --·:· --.. --.. . . . . . -.. . --.. .:. -.. -.. . ·+: --.. - IO - - - - • - - -, • • - - - • - - - r - - - • • - - - ... - - - ... - - - - - ,- - • - ... - • - - 70 -.. . -.. --·:.. . . --.. . -.. . .. . . --..+ .. . . -.. . ---:.- -.+. . . --.. . :.-.. -.. -.. ---:.- --------' . -- I I I I I I I • I I I I ~ I I I I T - - - • - - - .... , - .. - - "' .. - • .. r "' • "' - I ~ ~ ~ eo I I I I I I I f I I I I I I I I ++ L iA(m)' _~~ ..._~...._~_._~_._~___.~~---~...._~~~__. IO.__~...._~~~__._~__.~~..._~. 0 4 8 12 18 20 28 Figure 1. Plot of the angle of vanishing positive stability against overall length for stability-oriented casualties (pluses) and "good" category I vessels (squares) - (93-020-1.chJ/hpp). 104 In which: cl>v ~ 5.1.1, was used as the boundary between stability category I and II. This is a well-defined boundary. The boundaries between categories II and III, and between Ill and IV, are less well-defined. These boundaries are based, in part, on information provided by designers, builders and other experts concerning the category of various well-known yachts of which the stability particulars were available. For example, different experts considered that the J24, at best, is a category III yacht. Angle of vanishing I ositive stability in degrees; Mass of sailing vess1 :I in tons of I 000 kg, in the minimum saili1 tg condition. The minimum angle of vanist ing stability according to this proposal is shown in Figure 3. It should be noted that the v 1lue of cl>v is the rigo- rous value, including deck c< mber, cockpits, masts and deck houses. Extruded, i.e. non-solid masts are not to be considered as wate1 tight as this is hardly ever the case. The specific ( ffect of deck camber, cockpits, masts and deck hou ;es on cl>v is discussed in Paragraph 5 .1.3. During the meetings of Working Group 22 in which the above proposal was discussed, a suggestion was made to reduce these minimum criteria to account for the case that a vessel possesses a relatively low stability in the inverted position. It was proposed to adopt an expression based on the value for the vanishing angle as given in the above formulae but corrected for the value of GM in the inverted position, in the form: The demarkation between "gc od" category I sailing craft and casualty data, as p1 esented in Paragraph 140 . - - - - - - - - - - - - - - - . . . . . - - - - - - - - - - - - - - - - - - - -.... • "aoocr cataaory I Wlllall + 130 ~lly~ I '. +" . . - ---: •-t 120 '' :rl" : t I I I I : : : : : ~~. i - - . - -~ . . . . - - - ~. - - - - .. ~ . . . . . - . -:- - - - - - - - ~ - - . - - - - ~ - - - - - - - -:- . - ' ' ' ' ' ' ' ' +.. - ..'". - ..... ,. - . - . - ..... - - - . - . - . - - - ...,... - ....•... - ....... - - - - ., - - - 110 'I I "\ ~ I ' : I ' ' ' : • .. I I I I I I I I ' ' ' ' ' ' I •• I I I I . : .. • ' ' ' ' - . - ...... - . - .'. ""·:...... - - ... - .... -:- - - . - - - . ' - .. - . - . - '..... - - . -' - . - - - . - .... - 100 +: : : : : : "1>v(degr.): - . - ... , - . - . - . - -·- .... - . - • - - ..... , .. - - .. - -·-. - - . - . - ·- .. - - - - - , . - - - - - - -·- - :+ I IO I ~. :~---~----~----~----~----~----~-I I I I I I 80 - - - - - - - - ...... -·· - - - - - - - ...... - - - - - - - - . - -·- . - - . - . - .... - - - ... - - . - - - .. - - - - 70 . -+· . ;- . -.. -.. . ":" . --.. ---;:+----.. . . . -.. --.. -·:· --.. -.. . . ;. . . . -.. . .............. ·:· . . . I I I I I I ~ + IO I I ~ I I I I I I I I I I I I I I I I - - - - - - -·I .. - - - ....... -·- - - - - - .. I ~ ... - - - - - - JI ............ - - -·- - - - - - - ·- - - - - - - ~ - - - - - - - .. • .. - .. I I +:· I ' ' ' ' A(tonna) · :+ , I0,__.._.._.._..__..__..__..._.__1.__.__.__.__1.__.__.__.__1.__.__.__.__1.__.__ .__.__1.__.__.__.__1.__..__..__..__1___. 0 20 40 IO 80 100 120 140 180 Figure 2. Plot of the angle of vanishing positive stability against displacement mass. Here, a welldefined demarkation exist 1 between the casualties and the "good" category I vessels (93-0202.ch3/hpp). 105 ~v > ~vrarmula A study of this concept revealed that for most vessels, the numerical value of GM 180 is difficult to determine from existing GZ curves because of the rapid rate of change of GZ near a heel angle of 180 degrees. Also, when the inverted vessel is rolling through a heel angle of up to 30 degrees or so in waves, the use of the minimum value of GZ, i.e. the minimum lever in the negative stability part of the GZ curve, is often more meaningful than the use of GM 180. The value of GZmin is easily determined from a GZ curve based on calculations at, say, 5 degree intervals, whereas the determination of GM 180 requires calculations at 1 degree intervals from, say, 17 5 to 180 degrees of heel. c/GM1so - In which: Angle of vanishing positive stability; Required value of the angle of vanishing positive stability according to the initial proposal; A constant to be determined; Metacentric height of the intact hull in the inverted position (at a heel angle of 180 degrees). ~Vformula This proposal is based on the fact that recovery from an inversion (which is the hazard that is addressed here), is dependent on the degree of stability in the inverted position, for example, as depicted by the value of GM 180 • 130 I • ... • - - - • J I - - - - - J ... - ....... I I - - .. - ' i : I I I I I I : : .......... J - .... - - - J - - - ... - - -· ... - - - - .. -· - - .. - - .. -· - - - ...... - • - - - - - - I • I • I I I I I. - - .!! - 1 • •gobd" cat8g'ary I V8IMll + 81alt111ty cuUnlee : : .-t-~ : GZmin nearly always varies from 0 to -1 meter. The following table lists some typical values for some well-known yachts: ' 120 ' ' ' ' •••• _!_ - - - ..... i - ........ - - -. - - - - - .. -. - - - - - - -. - - ... - .. - -.- - - - - .. -.- - - - - - 110 .. .I - ........ - .I ' ... Stabll.,~1 : :" : :• . .. - - - .. - ... - - - - ......... - .. . .. • '!! - .......... - .. - -· - - - .. - ......... - - - - -•- - ........... ' ' 100 ' "'1"' : : •: • • ' IO IO - - .... - 1 .. I - - - - .I I - - - - - J I - - - - - -· .. - - - - - -· .. - - .... - -· - - - - - - -· - ........... -·- I I I I I - - - .... • ........... - I + -----:+·---:------:--.. . . . :·. . . . . ·: ·-----·:- -.. -.. . ·: ·. ----·:· . . . . . ·:· ----- 70 ..............._......... I I I + , , I I I I I I I I I I I I I I I , , . ·(IDnne) , , , ...................._._........._,__........._,__..........................................................................................................._._......._._...._._._...._.~ 100 IO IO IO IO 70 40 ....._~...........~...........~ o 10 2G Figure 3. Initial proposal forwarded to Working Group 22 for the minimum value of the angle of vanishing positive stability as a function of displacement mass, for stability categories I through IV (93-020-4.ch3/hpp). 106 Yacht name Swan 55 Oyster 68 Auklet 9 Trekker 42 Contessa 32 Moody 346 Moody 44 CNB 23 Dufour 48 Taka 124 Sigma 33 OOD Oyster 55 Fastnet 1/2 ton Jongert 2200 Jongert 21S of this type. GZminJm.l -0.22 -0.39 -0.34 -0.08 -0.12 -0.25 -0.32 -0.81 -0.50 -0.30 -0.50 -0.40 -0.37 -0.87 -0.65 -0.44 5.1.3 Effect of Deck Camber, Cockpit and Deck Houses on the Angle of Vanishing Stability The work carried out to investigate the effect of deck camber, cockpit and deck houses on the righting moment reveals that it is essential to include these effects in the calculation of GZ. The impact thereof is significant. The value of the angle of vanishing positive stability generally increases when these factors are taken into account. Together with ORC and US Sailing, a systematic study was carried out comprising the calculation of the righting moment curves for the following cases: Case A: Comprised a calculation of the righting moment curve for 4 different types of mono-hull sailing yachts with a flat deck (similar to the calculations carried out to determine LPS as given on IMS rating certificates). For each of these 4 types of yachts the following additional variations were studied; It is important to note that "1 'aka" (one of the con- sidered casualties) has a GZm" of -0.3 meter. Since this yacht remained inverted for about 1 hour in high waves, It is appropriate to not adopt a credit for values of GZmin less thar about -0.3, but only for values greater than -0.3, i.e. closer to 0. Accordingly, a proposal was fc rwarded to Working Group 22 to only modify the original formulae when GZmin > -0.3. The form1 la proposed was: Case B: Deck camber equal to 7.5% of local beam. This was found to increase <l>v by between 3 and 8 degrees, depending on the type of vessel; <l>v > <l>vronnula - 4 / [O.l+i'.BS(GZmin)] + 10 Case C: Deck camber equal to 15% of local beam. This was found to increase <l>v by between 7 and 21 degrees, depending on the type of vessel; which is only to be applied w lien GZmin > -0.3. In this formula, ABS indic: 1tes that the absolute value of the relative expres. :ion (GZm;n) is to be taken. Case E: A small deck house with a width equal to 40% of local beam, with a horizontal roof, a height of 15% of maximum beam at the location of lowest freeboard on the sheerline. and a length equal to 50% of hull length. This was found to increase <l>v by between 2 and 9 degrees depending on the type of vessel; The result of this formula is t iat when GZmin = -0.3, the required value of the angl ~ of vanishing positive stability remains unchanged. When GZmin = -0.2, the required value of the angl ~ of vanishing positive stability is decreased by 3. l degrees, and when GZmin = -0.1, the decrease is 0 degrees. Case F: A moderate deck house with a width equal to 70% of local beam, with a horizontal roof. a height of 15% of maximum beam at the location of lowest freeboard on the sheerline. and a length equal to 50% of hull length. This was found to increase <l>v by between 6 and 13 degrees depending on the type of vessel; It should be noted that if sm :h a proposal is adop- ted, the GZ requirement at 9) degrees of heel (see Paragraph 5.2) becomes even more important than it already is. This is because i vessel with a small negative GZmin value will si 1metimes also have a small value of GZmax and, h~ nee, a small value for GZ 90 • In such a case, consic .erable credit is given for good recoverability from an inversion (in terms of allowing the vessel to have a smaller value of the angle of vanishing positive stability) while the ability to withstand a knock-c own in the first place, is extremely low. Yacht D, h Figure 4, is a vessel Case G: A large deck house with a width equal to 100% of local beam. with a horizontal roof. a height of 15% of maximum beam at the location of lowest freeboard on the sheerline, and a length equal to 50% of hull length. This was found to increase <l>v by between 8 and 15 degrees depending 107 (lowest) freeboard, and a length of 20% of hull length. This was found to reduce ~v by between I and 3 degrees depending on the type of vessel; on the type of vessel; Case K: A large cockpit with a width equal to 87.5% of local beam, a depth equal to 62.5% of the (lowest) freeboard, and a length of 20% of hull length. This was found to reduce ~v by between 2 and 5 degrees depending on the type of vessel; Case J: A small cockpit with a width equal to 52.5% of local beam, a depth equal to 37.5% of the (lowest) freeboard, and a length of 20% of hull length. This was found to reduce ~v by between 0 and 2 degrees depending on the type of vessel. Case I: A moderate cockpit with a width equal to 70% of local beam, a depth equal to 50% of the . . : ~7--:for .~--SO· .....- . •• L A ' • • • • • • • 1• • • • • • • • 1 • ., • ., . . . . . . -' . . . . . . . . . . . . .. A - - .... - - - - - - ·- - - - .... - -·- - - - - - - J ...... - - - - ;B_ - .... -- .. ------ .. --- ........... ------- .. ----I I I I I I . . I I c : GZmlnfor ·:·: - .... - - .. ---- .. - ~ Vanls~ing p~sltlve ~Hity tor·c -· ~ -··· · -·: ·0.5 ;:·:· · •1'----'---''---'---'~-'----'-~...L......:::....J....-=--.i......=--'---=..&~-'---'-~.....__--........F----'-----' 0 20 40 100 120 140 180 180 Figure 4. Righting arm (GZ) curves for 4 yachts. Curve A is for the Contessa 32, while curves B, C and D are for hypothetical sailing craft. Yacht A is an ideal yacht from a transverse stability point of view. It possesses a high resistance against knock-down (i.e. a high value for GZ 90) and low stability in the inverted condition (a small negative value for GZmin and a high value for the angle of vanishing positive stability). Yacht B has a high resistance against knock-down (a high value for GZ90 ) and high stability in the inverted condition (i.e. a large negative value for GZmin and a moderate value for the angle of vanishing positive stability). Yacht C is a bad yacht from a stability point of view. It possesses a low resistance against knock-down (a low value for GZ90) and high stability in the inverted condition (a large negative value for GZmin and a low value for the angle of vanishing positive stability). Yacht D also possesses undesirable stability characteristics. Although it possesses low stability in the inverted condition (a low negative value for GZmin and a moderate value for the angle of vanishing positive stability), it will be easily knocked down - (93-0206.hpp/ch3). 108 5.2 Minimum Value of the Righting Moment at 90 Degrees of Heel 5.2.1 Differentiation Bel ween "Good" Vessel Dab. Casualty defined line can be drawn to distinguish between the casualties and the "good" category I sailing craft. Accordingly, it was decided to develop a proposal for the minimum value of the righting moment at 90 degrees of heel based on the results of Figure 5. and The value of the righting levc r at 90 degrees of heel (GZ90 ) was studied in a sh 1ilar way as was the angle of vanishing stability. Here, a plot of the righting lever against length or displacement was found not to provide a mear ingful relationship, as only a "cloud" of points ei ·olved. A plot of the actual righting moment at 90 degrees of heel however is seen to result in a ' ery meaningful trend. Figure 5 gives this plot of the value of the righting moment against overall Ieng th. This righting moment is calculated from ~.C iZ90 , where ~ is the mass of displacement in the minimum sailing condition, in tons of 1000 kg. J. .gain a relatively well- 5.2.2 Proposals for the Righting Moment at 90 Degrees of Heel In Paragraph 5.2.1 a summary is presented of the work that was carried out using the 115 sets of rigorous stability data to derive a meaningful trend for the righting moment at 90 degrees of heel with vessel particulars. An account is there presented of how it was possible to define a sufficiently useful demarkation between the casualty data and the "good" category I data, using only the overall length of the vessel. • "goacP catego y I vaaell: _______ + 8t8blllly ~- ___, • .... -- - .. --- - ~ - .... - .... --- .... ·- -- -- ..... -.... --·- .. -.... -. -- ...... •............... -----·- ............ -... -- 21 I I I I I •• IO - ............ - ...... p ... - ................ - p - ........... - - ...... ~ ...... - .... - . ................ ... - ............. , ................ • + • 11 • - - - - • .. - - ........ - - - ~ ...... - - - .......... :- - - ........ - - ...... :- ...... - .... - ...... -:- .......... - - ...... -:- ................ - - : I 10 I I I •• • . •• • ~ ...... - - - ........ ~ - ........ - - ........ ~ - - .................. ~ .............. - .... -:- ... -.- .......... - .. :· .................. .. • I • •• I f ::- • ..:---+ + .+ ----+: ..!--f+' " :-=F° . ..... I _ __. !-- · I ......... - - ........ i ....... - - ...........- - .. -.- ...... - - .... .......... - : ·..:;. I • : ·- -~ ... ......... - - - - - - - ... I,.. - .......... - - - - LQA(m) oi.--.....:=-_.___,__.___._" "'Ffs::..i...--'-_..__.__,.__, __..__.__.....__.__.__.__._ __,___.__,.__,__..__.__... __..___._..... 0 I 10 11 20 21 • Figure 5. A plot of the r ghting moment (in ton.m) against overall length for the same vessels considered in Figures 1, 2 and 3. Here, also, a well-defined line can be drawn, differentiating between the casualties and th,~ "good" category I vessels (93-020-3.ch3/hpp). 109 On the basis of considerable consultation with various designers, builders and experts, a proposal was prepared and forwarded to Working Group 22 for the righting moment at 90 degrees of heel, for each of the four stability categories. The required demarkation between category I and II was again deduced from the boundary between the casualty data and the category I vessels. The demarkation between categories II and III, and between III and IV was again based on the opinion of various designers and builders about the category of specific vessels. RM90 = gi\i.GZ90 > 3.50+1.5(Lhun-7) (category III) (category IV) When Lhun is less than 7 meter: (category I) (category II) (category III) (category IV) In analytical form it was proposed that when Lhull is greater than 7 meter: RM90 = gi\i.GZ90 > 10.5+4.5(Lhun-7) (category I) RM90 = gi\i.GZ90 > 7.00+3.0(Lhun-7) (category II) In these expressions: Righting moment in kNewton.m at 90 degrees of heel; Acceleration due to gravity; g • "good• oatagory I vwel.: lltablllly ~ + • • .......... .- ........... .- ........... .- ....... ... .- .. I 11 I I I ~ . .GZ90 ~m) . I ~ ~- i ... . .• . "! • .•• . -- - .............. " -- -- .......... -- --- .... -.... _._ ..... --- ................. ._ .......... -.. - ...... .·- --- 10 . \. •• . I .................... r ..................... 0 I . -~ • •• . .................... 10 .. "'t"' 11 ID 21 Figure 6. Initial proposal forwarded to Working Group 22 for the minimum value of the righting moment at 90 degrees of heel as a function of over-all length, for stability categories I through IV (93-020-S.ch3/h pp). 110 Lhun Displacement mass of vessel in minimum sailing condition, m tons; Length of h 111 as defined in ISO 8666. (category IV) 5.3 Minimum Value of the Area Under the Righting Moment Curve 5.3.1 Graphs according to these ex11ressions are shown in Fig. 6, in which the rightin~ moment is given in ton.m, not in kNewton.m. 1'"ote again that the 3 casualties referred to in Paragraph 5.1.1 (number 5, 8 and 14 of Table 2) are again situated above the lines depicting the boundary >etween stability categories I and II. Some mono-hull sailing craft have little or no ballast in the keel or in the hull. These vessels depend almost entirely on hull form for stability. Accordingly, they usually posses an insufficient range of positive stability. When knocked down by wind or waves to an angle of heel near 90 degrees, they are usually unable to recover. In this respect, this class of vessel is similar to multi-hulls, which also have a restricted range of positive stability. In order for these vessels to attain stability categories I and II, ISO 12217-2 will require that such vessels have sufficient buoyancy when swamped or inverted, so that they do not sink. Subsequent validation studies carried out in Japan and England revealed that f< 1r small boats with a length of hull less than 7 m, the required righting moment at 90 degrees of bet I, as specified by the above formulae, is too harsh For a typical MiniTransat design with Lhun = 6.0 J meter, at a displacement mass of 1.5 ton, . these: formulae lead to a required GZ 90 value of 0.61 ! meter (for stability category I), where actual values are closer to 0.3 meter. (It can be argued hm fever that such small boats should not be crossing oceans at all.) Further study revealed that, if an ab! olute minimum value of the righting moment is to be imposed, this should be done for lengths of 6 m and less, not for 7 m and less. During early discussions in Working Group 22, a majority of the members were of the opinion that the only requirement these vessels need to adhere to, in addition to the buoyancy requirement mentioned above and the general requirements mentioned in Paragraph 2, is a specific area under the righting moment curve up to the heel angle at which the maximum righting moment occurs, to ensure that these vessels have sufficient stability to withstand a sufficiently high wind strength. Such a criterium is often referred to as the "heeling energy required to capsize". Since many traditional Dutch sailing barges (in Dutch referred to as "rond- en platbodem jachten) fall into tpis category, the stability study in the Netherlands also included a study of this minimum area under the righting moment curve for this class of sailirig vessel. At the same time, an indept ndent working group consisting of Netherlands-base l naval architects and yacht designers carried out i 1 validation study revealed similar results. On rn :onsidering all of the available data it was decided to prepare a new proposal, utilizing a quadratic fr nction of hull length. This led to the following final proposal: For Lhull greater than 6 meter: RM9o=gA,,,.GZ90 > 0.3125(Lhun>2 - 7.25 (category I) RM90=gA,,,.GZ90 > 0.2083(Lhun> 2 - 4.83 (category II) RM90=gA,,,.GZ90 > 0.1042(Lhun '2 - 2.42 (category III) Reasons for Requiring a Minimum Value of the Area Under the Righting Moment Curve 5.3.2 Proposals for the Area Under the Righting Moment Curve To derive criteria for mono-hulls, a detailed list of stability particulars for Dutch sailing barges and similar sailing vessels with little or no ballast and with a good track record with respect to stability, was collected. On plotting the area under the righting moment curve up to the heel angle at which the maximum righting moment occurs, a well-defined relationship with displacement weight was obtained. For vessels sailing on the IJsselmeer for example (which need to comply with the requirements of stability category III) according to the (category IV) When Lhun is less than 6 mete1 : (category I) (category II) (category III) 111 prevailing wave height and wind speed), all of the points for the different vessels considered are positioned above a curve with the following formula: 6. 6.1. DEVELOPMENT OF SINGLE STABILITY INDEX Introduction A1oGZmax = gl\,,(12.9 - 0.0 l 7g<'.lm) Late in 1995 and early in 1996 it became apparent to all members of Working Group 22 that unanimous agreement on the required minimum values for each of the important stability parameters, as given in the preceding paragraphs, was unattainable. Where one country, for example, wanted a moderate minimum value of the angle of vanishing stability and a high minimum value of the downflooding angle, another country wanted a relative high minimum value of the angle of vanishing stability and a moderate minimum value of the downflooding angle. It was then decided to appoint a small group of experts to study and, if possible, develop a system in which a high value of one parameter could be traded-off against a low value of another parameter, wherever possible. This group worked through the summer of 1996, resulting in the concept of a single STability Index (STIX). At the meeting of WG 22 in Paris on 9 September 1996, it was unanimously decided to adopt this STIX concept for the assessment and categorization of the intact stability and buoyancy of mono-hull sailing craft with a (hull) length between 6 and 24 m. The sub-working group was composed of the French, Netherlands, Swedish and UK delegates to WG 22. This method will form the basis of ISO 12217-2 for mono-hulls. Use of this method resulted in the correct stability categorization of every yacht and sailing vessel selected from the data bases provided by France, The Netherlands, Sweden and the UK. No other method devised by WG 22 in the past gave such good results. In this formula gl\,, is the weight of the vessel in kNewton, in the minimum sailing condition. For displacement values greater than 40 tons, no further reduction in the area under the GZ curve with increasing displacement (the part of the expression in brackets) is noticeable. On using the same differences in righting moment requirements between the various stability categories as for ballasted mono-hulls, it was possible to develop the following proposed requirements: For L\,, < 40 tons: A1oozmax > gl\,,(38.6 - 0.05lg<'.lJ (category I) A1o GZmax > gl\,,(25.7 - 0.034g<'.lm) (category II) A1o GZmax > gl\,,(12.9 - 0.017g<'.lm) (category III) A1o GZmax > gl\,,( 6.4 - 0.008g<'.lm) (category IV) For L\,, > 40 tons: Ato GZmax > l 8.2gl\,, (stability category I) Alo GZmax > 12 .1 gl\,, (stability category II) (stability category III) (stability category IV) On applying these values to ballasted mono-hulls such as the J24, usually the same stability category is assigned as would be assigned using Paragraph 5 .1.2. The following example illustrates this. 6.2. The Factors Involved The following factors were defined for incorporation into the calculation of the STIX value: The J24 has a value for <l>v of about 115 degrees and when using Paragraph 5.1.2 is assigned stability category III according to the proposed criteria. The value for gllm is about 16. 7 kN and the area under the positive part of the righting moment curve, up to the heel angle where the maximum righting moment occurs, is approximately equal to 224 kN.m.deg. According to the above formulae, the minimum requirement for category III is equal to gl\,,(12.9 - 0.017 x 16.7) which equals 210.7 kN.m.deg. Hence, here also, stability category III is assigned. Base Size Factor (FBS). The Base Size Factor is based on length. The size of a vessel is considered as the single most important factor in resisting the excitation forces on a vessel; Area under the righting moment curve or Righting Energy Factor (FRE). This factor is particularly important for vessels with mainly form stability. It is based on the area under the righting moment curve up to the angle of vanishing stability or the downflooding angle in the case the downflooding angle is less than 90 degrees and less than the angle 112 thus determined (conservative) value is insufficient to obtain the wanted stability category, it is necessary to carry out the full set of calculations however, requiring the actual GZ curve as a function of heel angle, at least up to the angle of vanishing stability, or 90 degrees, whichever is greatest. of vanishing stability; Inversion Recovery Factor (FIR). This factor accounts for the recoverability "rom an inversion and is based on the value of the ''anishing angle, or the downflooding angle in the case the downflooding angle is less than 90 degrees ;md less than the angle of vanishing stability; In all, 7 factors need to be evaluated when the downflooding angle is greater than 90 degrees, and 8 factors need to be evaluated when the downflooding angle is less than 90 degrees. Knock-Down Recovery Fact< 1r (FKR). This factor accounts for the recoverabilit:, after a knock-down. Rather than base this factor )n a righting moment or a righting arm (GZ) value at 90 degrees alone, it was decided to base this fact >r on the value of the righting moment at 90 degrees, divided by the area of the sailplan times a lever. The resulting value is indicative of the ability of f vessel to spill water out of the sails after being ( otally) knocked down to about 90 degrees of heel; 6.3 Downflooding Openings In the calculation of some of the factors described above, the value of the downflooding angle plays an important role, particularly in the case the downflooding angle is less than 90 degrees. This downflooding angle is the heel angle at which a critical amount of water downfloods into the nonselfdraining part of the vessel. The combined crosssectional area of openings causing critical downflooding (after a knock-down for example), is considered to be greater than that defined in ISO 12217-2 in the context of determining the minimum Specifically, downflooding through freeboard. hatches and companion ways are the causes of dangerous downflooding during a typical knockdown. Accordingly, it was agreed that openings with a cross-sectional area of 0.18 m 2 or greater constitute openings for the calculation of the downflooding angle (not the downflooding height) in the context of the calculation of the STIX value. In the calculation of the downflooding angle for the evaluation of the various factors as described in Paragraph 6.4 below, the above definition of downflooding openings is utilized. Displacement Length Factor 1 FDL). Since the Base Size Factor is based on lengt 1 only, it is necessary to include a factor which ace· mnts for the displacement since a heavy yacht fo1 a given length has a greater resistance to being kn• •eked down; Beam-Displacement Factor ( ~BD). This factor accounts for the beam and the degree of top-sides flare (i.e. the ratio between 3hull and BwL). This is considered necessary since ;1 vessel with a large value of BhuufBwL• when l roadside to breaking waves, experiences a greater 1 langer; Wind Moment Factor (FWM) In the case of vessels with a downflooding angle le: :s than 90 degrees it is necessary to determine the w nd speed at which the vessel attains a heel angle equal to that of the downflooding angle (without reefing the sails). If such a heel angle occurs at 1JW values of the wind speed, the vessel is at great1 :r risk than when this occurs at high wind speeds; 6.4 Formulation of the Individual Factors The formulae involved in the evaluation of each of these factors are as follows: Downflooding Angle Factor (FDF). The danger of downflooding is largely dep~ ndent on the value of the downflooding angle. 6.4.1 Base Size Factor (FBS) This factor is based on a weighted average of the length of the vessel, as follows: For some of the above factor; an approximate value or expression is being de• 'eloped which allows approximate and conservativ1: evaluation thereof in those cases the detailed riE hting moment or GZ curve is not available. Accodingly, it is possible to determine a conservative vah e of the stability index without any difficulty (i.e. w thout actually carrying Liis = (2LwL + ~un)/3 where: Base size length; on the waterline in the out a calculation of the rig 1ting lever GZ - as a Length function of heel angle). Wh :n it is found that the minimum sailing condition in m; 113 Length of hull as defined in ISO 8666 in m. bility in degrees; Downflooding angle in degrees; Base value of the angle of vanishing stability in degrees. This is the minimum value of <l>v considered desirable for stability category I. <l>o <l>v(base) The Base Size Factor is defined as: FBS = 3Les = (2LwL + Lhu11) 6.4.2 Righting Energy Factor (FRE) The formula for <l>v(base) is: This factor is defined as: <l>v(base) = 125 - 0.625~ < 40) 40) in which Am is the displacement in tons, in the minimum sailing condition. The minimum and maximum values of FIR that may be adopted in the calculation of the STIX value, are 0.5 and 1.5 respectively. 6.4.4 Knock-Down Recovery Factor (FKR) This factor is defined as: If FR> 1.5: The base value of the area under the righting moment curve is: FKR = 0.875 + 0.125F R/FR(base) If FR < 1.5: when Am< 40 The knock-down recovery coefficient FR is defined as: and when Am > 40 ERM(base) = 250~ In which ~ is the displacement in tons, in the minimum sailing condition. and the base value of the knock-down recovery coefficient FR(base)> considered as the minimum value of FR desirable for stability category I, is equal to 1.5. It follows that: The minimum and maximum values of FRE that may be adopted in calculating the final STIX value, are 0.5 and 1.5 respectively. 6.4.3 ~ (for~> <l>v(base) = 95 where ERM is the area under the righting moment curve in kN.m.deg, up to the angle of vanishing stability if the downflooding angle is equal or greater than 90 degrees or when the downflooding angle is greater than the angle of vanishing stability. If the downflooding angle is less than 90 degrees and also less than the vanishing angle, the area under the righting moment curve up to the downflooding angle is taken. ~(base) is the base value of the area under the righting moment curve in kN .m.deg. This is the minimum value for ERM considered desirable for stability category I. (for 0.875 + 0.0833FR If FR> 1.5: FKR If FR< 1.5: FKR = 0.5 + 0.333F R = Inversion Recovery Factor (FIR) This factor is defined as follows: Here: When <l>o > 90 degrees or when <l>o > <l>v: Righting moment in N .m at 90 degrees of heel for the minimum sailing displacement condition; Projected profile area of all sails that may be set at one time when sailing to windward, as defined in ISO 8666, in m 2 ; Distance between the centre of buoyancy and the top of the sail plan, for a heel angle of 90 de- and if <l>o < 90 degrees, when <l>o < <l>v: FIR = <l>J<l>v(base) where: <l>v Angle of vanishing (positive) sta- 114 grees, i.e. hs = Else: HBI + (I+P+BA ~)/2 - VCG - GZ 90 FBD Height of I >ase of I above the water surfact in m at zero heel; Vertical hois: of genoa or jib in m; Height of be om above sheerline in m at zero he :I; Hoist of mainsail above boom in m; Height of vertical centre of gravity above water! ne in m at zero heel; Righting le' er at 90 degrees of heel in m. I BAS p VCG l .25BwdBhun Where: where: HBI = Maximum beam of hull according to ISO 8666 in m; Maximum beam of hull on the waterline in m; Displacement of vessel in minimum sailing condition, in tons. The minimum and maximum values of FBD that may be adopted in the calculation of the STIX value, are 0.75 and 1.25, respectively. 6.4. 7 Wind Moment Factor (FWM) If the downflooding angle is less than 90 degrees the Wind Moment Factor must be calculated. When the downflooding angle is equal or greater than 90 degrees, the value of this factor is 1.0 and FWM does not need to be calculated. In the case of vessels with 1nore then I mast, the weighted average of the value of hs for each mast is to be used. For 2 masts this h : The Wind Moment factor is defined as: Here, also, the minimum anc maximum values for FKR that may be adopted in the calculation of the STIX value, are 0.5 and 1.5, 1espectively. 6.4.5 FWM = 0.6 + 15000L\,.F J :Las3 (333 - 8Les)) where Minimum sailing displacement mass in tons; Base size ler gth in m. FWM = VAw/17 The value of VAW is to be calculated from: The mm1mum and maximum values for FDL that mat be adopted in the cal~ :ulation of the STIX value, are 0.75 and 1.25, resp•:ctively. 6.4.6 VAWNAW(base) in which V Aw is the steady apparent wind speed in m/sec required to heel the vessel to the downflooding angle ~ 0 when carrying the full sail plan (i.e. without reefing) when sailing to windward. The value of VAW(bas•> is the base value of VAW• i.e. the minimum value for VAW• considered desirable for stability category I. This value is 17 m/sec. It follows that: Displacement Lengtl 1 Factor (FDL) This factor is defined as: FDL = VAw = (13000L\,.GZ0 /(A 5 P.lever(cos(~ 0)) 13 ))05 where: Beam-Displacement Factor (FBD) The FBD factor is defined as: If Fe > 2.20 then: If Fe< 1.45 then: lever 115 Displacement of vessel in minimum sailing condition, in tons; Righting lever in m at a heel angle equal to the downflooding angle; Projected (unreefed) profile area of all sails that may be set at one time when sailing to windward, as defined in ISO 8666, in m 2 ; Vertical distance between the geometric centres of the above-water and below-water profiles of the vessel, including sails, masts and hull, with centerboards, daggerboards and leeboards in the lowered position, when the vessel is upright; Downflooding angle. <l>o The minimum and maximum values for FWM that may be adopted in the calculation of the STIX value, are 0.5 and 1.0 respectively. Stability category IV: STIX = 5 to 14; Stability category III: STIX = 14 or higher. The total volume of non, selfdrainable recesses is moderate or large when the factor k defined below is greater than 0.025, viz: Downflooding Factor (FDF) 6.4.8 if the value of the resulting value of STIX is sufficiently great. In that case the vessel is susceptible to swamping. These vessels can only be assigned stability category III or IV. In this case the stability categories are assigned as follows: The Downflooding Factor is defined as: FDF = total volume of non-selfdrainable recesses in m 3 k <l>ol<l>D(base) = --------------------------------------- -------------------- LwL ·BwL·FM where <l>o is the downflooding angle in degrees and <l>D(base) the base value of the downflooding angle, i.e. the minimum value considered desirable for stability category I. This value is 90 degrees. It follows that: FDF = where FM is the freeboard amidships according to ISO 8666. From the formula for STIX and the above limits, it follows that for vessels with a value of k (according to the above formula) less than 0.025: <j>J90 The minimum and maximum values of FDF that may be adopted in calculating of the STIX value, are 0.5 and 1.25, respectively. When (2LwL+Lhun) is greater than 100.84 m the vessel is always a category I vessel, except when the total volume of non-selfdrainable recesses is moderate or large; 6.5 Calculation of the Stability Index (STIX) When (2LwL+Lhun) is greater than 73.95 m the vessel is always at least a category II vessel, except when the total volume of non, selfdrainable recesses is moderate or large; The value of the stability index (STIX) is determined from: STIX = FBS(FRE.FIR.FKR.FDL.FBD.FWM.FDF) OJ When (2LwL+Lhun) is greater than 47.06 m the vessel is always at least a category III vessel; It should be noted that in the calculation of any of the factors described above, it is at all times permissible to simply adopt the minimum value of one or more of these factors without any calculation. When (2LwL+Lhuu) is greater than 16.81 m the vessel is always at least a category IV vessel. 6.6 Assignment of Stability Category This follows from the fact that the minimum value of the product of the individual, non-dimensional factors, to the power 0.3, is 0.2975, i.e.: The stability categories are assigned as follows: Stability category IV: STIX = 5 to 14; Stability category III: STIX = 14 to 22; the minimum value of: (FRE.FIR.FKR.FDL.FBD.FWM.FDF)03 Stability category II: STIX = 22 to 30; Stability Category I: STIX = 0.2975. 6.7 Validation = 30 or higher. The above method was validated independently in 4 countries, viz: in France, in the UK, in Sweden and in the Netherlands. Some 50 different, well-known yachts and sailing vessels were selected and given a In the case the total volume of non-selfdrainable recesses of a vessel is moderate or large, the vessel cannot be assigned stability categories I or II, even 116 stability category according to what the designer, builder and experts involve i thought was appropriate for those vessels ac1 :ording to the known stability characteristics and t ie experience obtained therewith over the years. 1 hese rather subjective assignments of stability catt gory were thoroughly discussed until finally the ~xperts involved were unanimous in their opinion 011 the stability category. N.m at 90 degrees of heel for the minimum sailing displacement condition. In the calculation of FWM: An expression for GZo: the righting lever in m at a heel angle equal to the downflooding angle; An expression for "lever": the vertical distance between the geometric centres of the above-water and below-water profiles of the vessel, including sails, masts and hull, with centerboards, daggerboards and leeboards in the lowered position, when the vessel is upright. After each of the yachts a 1d sailing vessels involved were assigned a stability category, the STIX stability index was calcula ed according to the above calculation scheme. l was then found that almost without exception the wanted stability category could be obtained by se1 ting the STIX value at 5, 14, 22 and 30 for the vru ious categories as explained above. The only ni 1table case the STIX value did not pin-point the l ppropriate category is the case of "Taka", the casm .lty discussed in Paragraph 4, for which STIX is well in excess of 30, indicating that this yacht is I ossibly indeed a category I yacht, as had been contended by various experts and the designer. Th is would seem to indicate that either the stabilit) information given in the report prepared by the J .iippon Ocean Racing Club (see the list of referen :es) is not correct or some other factor (such as a structural failure) also played a role in the sinking o · the yacht - a point of view adhered to by various Jeople. Table 4 gives the main results of the validat on study. In the calculation of FDF: An expression for <j> 0 : the downflooding angle in degrees (from the height and off-centre distance of the downflooding location). 7. The subject matter dealt with in this paper, in the context of ISO Standard 12217-2, is still in development. All of the developed criteria, presented here, will remain subject of discussion in the Working Group until mid-1997 when the voting procedure on this standard will commence. Once the Working Group has presented its so-called Committee Draught (CD) version of the Standard, this will be sent to all ISO member countries for formal consideration. It is quite likely that proposals will be forthcoming recommending modifications, additions and deletions. As such, this paper should be considered as a presentation of the current state of affairs with respect to the development of the Standard as it applies to mono-hull sailing vessels. Furthermore, the opinions and remarks presented here are not necessarily those of' Working Group 22, but those of the Netherlands delegation only. 6.8 Approximate Formulae. Approximate formulae are 1urrently being developed for the following variab es: In the calculation of FRE: An expression for Eiut: the lfea under the actual righting moment curve in kN.1 n.deg, up to the angle of vanishing stability (<l>v) a 1d the downflooding angle (<j> 0 ). 8. In the calculation of FIR: An expression for <l>v: the tive) stability in degrees; an~ FINAL REMARKS LIST OF REFERENC ES Final Report on Safety from Capsizing", Report of the Directors of the Joint United States Yacht Racing Union and Society of Naval Architects and Marine Engineers Committee, 1985. le of vanishing (posi- An expression for <j> 0 : the d >wnflooding angle in degrees (from the height and off-centre distance of the downflooding location). Claughton, A.R. and Handley, P., "An Investigation Into the Stability of Sailing Yachts in Large Breaking Waves", Wolfson Unit Report, 1984. In the calculation of FKR: Dahle, I.E.A. and Myrhaug, D., "Risk Analysis Applied to Capsize of Smaller Vessels in Breaking An expression for RM 90 : the righting moment in 117 Waves", Spring Meeting of the Royal Institution of Naval Architects, 1993. Sailing Vessels and their Response to Gusts", 10th Chesapeake Sailing Yacht Symposium, Society of Naval Architects and Marine Engineers, 1991. Deakin, B., "Methods of Assessing the Safety of Cruising Yachts in Terms of Stability", Paper Presented at the Conference on "The Seaworthy Cruising Yacht", Royal Institution of Naval Architects, November 1991. Forbes, H., Laing, M. and Myatt, J., "1979 Fastnet Race Inquiry", Royal Yachting Association & Royal Ocean Racing Club, 1979. Deakin, B. "Model Test Techniques Developed to Investigate the Wind Heeling Characteristics of Nippon Ocean Racing Club, "Report on Marine Accident Involving the Yachts 'Marine Marine' and 'Taka' in the Japan-Guam Race 1992". Table 4. Main results of the validation study of the STIX single stability index concept. FBS FRE FIR FKR FDL FBD FWM FDF STIX Category given Category wanted Muscadet 17.3 0.64 0.99 1.07 0.92 1.11 1.00 1.17 16.2 III III Gib Sea 242 CB 19.7 0.50 0.96 0.96 0.95 1.08 1.00 1.17 16.5 III III Gib Sea 242 K 19.7 0.62 1.06 1.05 0.93 1.13 1.00 1.17 18.7 III III Sangria 19.6 0.71 1.00 1.16 1.04 1.04 1.00 1.18 19.8 III III Ecume de mer 18.8 0.85 1.05 1.16 1.00 1.02 1.00 1.17 20.2 III III Folie Douce 22.5 0.82 0.99 1.18 1.07 1.08 1.00 1.22 24.6 II II Super Challenge 22.8 1.09 1.28 1.31 0.94 0.99 1.00 1.17 28.1 II II Comet 910 23.6 0.70 1.01 1.13 1.03 1.05 1.00 1.17 23.7 II II First 310 26.5 0.74 0.95 I.OJ 0.90 0.99 1.00 1.22 24.6 II II Neptune 940 25.0 0.90 1.03 1.12 0.97 I.OJ 1.00 1.20 26.5 II II Feeling 326 Di 25.9 0.69 0.89 1.03 0.97 1.02 1.00 1.17 23.6 II II Sun Rise K 27.0 0.98 0.99 1.09 0.93 0.91 1.00 1.17 27.4 II II Romanee 26.7 1.02 0.99 1.14 1.01 0.75 1.00 1.17 26.9 II First 35 (79) 28.8 0.87 0.97 I.I I 1.01 1.07 1.00 1.17 30.2 I I Selection 29.5 0.82 0.96 1.02 0.86 1.00 1.00 1.17 27.7 II II Sun Odyss 371 31.0 0.82 0.92 1.03 0.96 0.99 1.00 1.17 29.6 II I/II Gin Fizz 30.1 1.00 0.99 1.19 1.10 1.07 1.00 1.17 34.9 I I Sun Fast 39 31.8 1.13 1.03 1.12 0.99 1.02 1.00 1.17 36.1 I I Sun Charm 39 31.5 0.94 0.98 1.08 0.98 1.00 1.00 1.17 32.7 I I Maracudja 32.7 0.68 0.85 I.OJ 1.17 1.06 1.00 1.17 31.l I I First 41S5 31.9 0.95 1.00 1.08 1.00 0.99 1.00 1.17 33.6 I I First 45 F5 36.3 1.42 1.06 1.16 0.97 1.03 1.00 1.17 44.9 I I Meridien 38.0 1.03 0.89 1.04 I.I I 1.13 1.00 1.17 42.1 I I Emeraude 40.4 1.20 1.05 1.16 1.10 I.I I 1.00 1.17 50.5 I I First 53F5 43.4 1.50 1.03 1.10 0.92 1.04 1.00 1.17 52.5 I I Name 118 FBS FRE FIR FKR FDL FBD FWM FDF STIX Category given Category wanted First 210 17.8 1.50 0.91 0.97 0.82 0.75 1.00 1.17 17.5 III III Mini Transat 19.5 1.19 0.93 0.94 0.78 0.75 1.00 1.17 17.6 III JOD 35 28.9 0.98 0.98 1.04 0.86 0.78 1.00 1.17 26.9 II II Group Sceta 54.3 1.50 0.88 0.74 0.76 0.75 1.00 1.17 47.5 I I Generali Concordi 54.3 1.50 0.87 0.77 0.81 0.75 1.00 1.17 48.9 I I BOC 50 45.3 1.50 0.84 0.66 0.75 0.75 1.00 1.17 37.8 I I First Class 8 21.6 0.73 0.96 0.97 0.82 0.89 1.00 1.20 18.4 III III Noirmoutrin 15.3 0.50 0.50 0.50 I.I I 1.13 0.50 0.50 5.8 IV IV Drascombe Lugger 14.6 0.50 0.50 0.50 0.77 0.75 0.80 0.58 5.2 IV IV Squib 16.2 0.50 0.50 0.50 0.79 0.75 1.00 0.65 6.5 IV IV Duette 17.6 0.91 1.06 1.23 0.95 0.79 1.00 1.25 18.1 III III J24 21.1 1.00 1.00 1.10 0.80 0.75 1.00 1.25 19.9 III III J24 21.1 0.76 0.93 1.05 0.83 0.75 1.00 1.21 17.7 III III J24 21.1 0.88 0.93 1.05 0.80 0.75 1.00 1.21 18.3 III III Westerly Centaur 29.9 0.99 1.46 1.14 1.05 1.15 1.00 1.25 27.6 II II Sigma 33 25.9 0.84 0.72 1.21 0.96 0.95 1.00 0.97 22.8 II II Sigma 33 25.9 0.92 0.72 1.26 0.97 0.95 1.00 0.98 23.8 II II Moody 33 27.7 1.46 1.09 1.44 0.99 1.14 1.00 1.00 36.8 I I Victoria 34 27.9 1.27 1.13 1.16 0.98 1.09 1.00 1.00 33.0 I I Bowman 57 44.7 1.16 0.78 1.26 1.04 1.14 1.00 0.98 48.4 I I Oyster 67 53.2 1.50 0.83 1.36 1.17 1.07 1.00 0.93 65.3 I I Nordic Folkboat 19.9 0.50 0.53 0.50 0.98 0.99 0.90 0.72 9.3 IV IV Intern. Folkboat 19.9 0.81 I.I I 1.23 0.98 0.99 1.00 1.25 21.8 III III Dragon 20.2 0.50 0.50 0.50 0.93 1.09 0.80 0.64 9.1 IV IV Island Packet 27 22.9 1.19 l.Q9 1.34 1.12 I.I I 1.00 1.22 30.7 I I Dehler 34 26.8 1.27 1.03 1.19 0.95 1.03 1.00 1.22 32.3 I I Taka 39.4 1.03 0.95 1.03 0.83 1.05 1.00 1.00 37.9 I I/II 17 m Schokker 44.2 ' 0.57 0.61 0.50 1.25 1.23 0.50 0.67 21.6 III III 17 m Schokker + selfdraining cockpit 44.2 0.58 0.67 0.50 1.25 1.23 1.00 1.00 30.7 I I/II Name 119
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