第一篇：船舶与海洋工程专业英语

船舶与海洋工程英语

目录

Part 1.船舶与海洋工程英语

1.The Naval Architect…………………………………………….……….….....1 2.Definitions, Principal Dimensions……………………………….….………....3 3.Merchant ship Types………………………………………………..…………10 4.Ship Design…………………………………………………………………16 5.General Arrangement……………………………………………………....…20 6.Ship Lines……………………………………………………..…………...…25 7.Ship Equilibrium, Stability and Trim………………………………………..28 8.Estimating Power Requirements………………………………………….….33 9.Ship Motions, Maneuverability………………………………………………37 10.The Function of Ship Structural Components……………………………………….....40 11.Structural Design, Ship Stresses…………………………………………………….......43 12.Classification Societies…………………………………………………...…48 13.Shipyard, Organization, Layout…………………………………..….....…..53 14.Planning, From Contract to Working Plans……………………………...….56 15.Lines Plan and Fairing, Fabrication and Assembly………………………....58 16.Launching and Outfitting…………………………………………………....61 17.Sea Trials……………………………………………………………………64 18.Marine Engines………………………………………………………………………...66 19.Marine Electrical Equipment…………………………………………..……71 20.Unattended Machinery Spaces……………………………………….……..76 21.Mobile Drilling Platforms……………………………………………………………...81 22.Examples of Offshore Structures……………………………………….…..85 23.Oceanographic Submersibles…………………………………………….…91 24.Application of Engineering Economics to Ship Design……………..……..94 25.Computer Development and the Naval Architect………………………..…98 Part2.26.船舶英语实用词汇手册……………………………………………………………..101 27.船舶英语缩略语…………………………………………………………………...…129

Lesson One

The Naval Architect A naval architect asked to design a ship may receive his instructions in a form ranging from such simple requirements as ―an oil tanker to carry 100 000 tons deadweight at 15 knots‖ to a fully detailed specification of precisely planned requirements.He is usually required to prepare a design for a vessel that must carry a certain weight of cargo(or number of passengers)at a specified speed with particular reference to trade requirement;high-density cargoes, such as machinery, require little hold capacity, while the reverse is true for low-density cargoes, such as grain.Deadweight is defined as weight of cargo plus fuel and consumable stores, and lightweight as the weight of the hull, including machinery and equipment.The designer must choose dimensions such that the displacement of the vessel is equal to the sum of the dead weight and the lightweight tonnages.The fineness of the hull must be appropriate to the speed.The draft------which is governed by freeboard rules------enables the depth to be determined to a first approximation.After selecting tentative values of length, breadth, depth, draft, and displacement, the designer must achieve a weight balance.He must also select a moment balance because centres of gravity in both longitudinal and vertical directions must provide satisfactory trim and stability.Additionally, he must estimate the shaft horsepower required for the specified speed;this determines the weight of machinery.The strength of the hull must be adequate for the service intended, detailed scantlings(frame dimensions and plate thicknesses)can be obtained from the rules of the classification society.These scantings determine the requisite weight of hull steel.The vessel should possess satisfactory steering characteristics, freedom from troublesome vibration, and should comply with the many varied requirements of international regulations.Possessing an attractive appearance, the ship should have the minimum net register tonnage, the factor on which harbour and other dues are based.(The gross tonnage represents the volume of all closed-in spaces above the inner bottom.The net tonnage is the gross tonnage minus certain deductible spaces that do not produce revenue.Net tonnage can therefore be regarded as a measure of the earning capacity of the ship, hence its use as a basis for harbour and docking charges.)Passenger vessels must satisfy a standard of bulkhead subpision that will ensure adequate stability under specified conditions if the hull is pierced accidentally or through collision.Compromise plays a considerable part in producing a satisfactory design.A naval architect must be a master of approximations.If the required design closely resembles that of a ship already built for which full information is available, the designer can calculate the effects of differences between this ship and the projected ship.If, however, this information is not available, he must first produce coefficients based upon experience and, after refining them, check the results by calculation.Training

There are four major requirements for a good naval architect.The first is a clear understanding of the fundamental principles of applied science, particularly those aspects of science that have direct application to ships------mathematics, physics, mechanics, fluid mechanics, materials, structural strength, stability, resistance, and propulsion.The second is a detailed knowledge of past and present practice in shipbuilding.The third is personal experience of accepted methods in the design, construction, and operation of ships;and the fourth, and perhaps most important, is an aptitude for tackling new technical problems and of devising practical solutions.The professional training of naval architects differs widely in the various maritime countries.Unimany universities and polytechnic schools;such academic training must be supplemented by practical experience in a shipyard.Trends in design The introduction of calculating machines and computers has facilitated the complex calculations required in naval architecture and has also introduced new concepts in design.There are many combinations of length, breadth, and draft that will give a required displacement.Electronic computers make it possible to prepare series of designs for a vessel to operate in a particular service and to assess the economic returns to the shipowner for each separate design.Such a procedure is best carried out as a joint exercise by owner and builder.As ships increase in size and cost, such combined technical and economic studies can be expected to become more common.(From ―Encyclopedia Britannica‖, Vol.16, 1980)

Technical terms

1.naval architect 造船工程（设计）师 32.scantling 结构（件）尺寸

naval architecture造船（工程）学 33.frame 肋骨 2.instruction 任务书、指导书 34.classification society 船级社 3.oil tanker 油轮 35.steering 操舵、驾驶 4.deadweight 载重量 36.vibration 振动 5.knot 节 37.net register tonnage 净登记吨位 6.specification 规格书，设计任务书 38.harbour 港口 7.vessel 船舶 39.dues 税收 8.cargo 货物 40.gross tonnage 总吨位 9.passenger 旅客 41.deductible space 扣除空间 10.trade 贸易 42.revenue 收入 11.machinery 机械、机器 43.docking 进坞 12.hold capacity 舱容 44.charge 费用、电荷 13.consumable store 消耗物品 45.bulkhead 舱壁 14.light weight 轻载重量、空船重量 46.subpision分舱（隔）、细分 15.hull 船体 47.collision 碰撞 16.dimension 尺度、量纲、维（数）48.compromise 折衷、调和 17.displacement 排水量、位移、置换 49.coefficient 系数 18.tonnage 吨位 50.training 培训 19.fineness 纤瘦度 51.fluid mechanics 流体力学 20.draft 吃水 52.structural strength 结构强度 21.breadth 船宽 53.resistance 阻力 22.freeboard 干舷 54.propulsion 推进 23.rule 规范 55.shipbuilding 造船 24.tentative 试用（暂行）的 56.aptitude（特殊）才能，适应性 25.longitudinal direction 纵向 57.maritime 航运，海运 26.vertical direction 垂向 58.polytechnical school 工艺（科技）学校 27.trim 纵倾 59.academic 学术的 28.stability 稳性 60.shipyard 造船厂 29.shaft horse power 轴马力 61.electronic computer 电子计算机 30.strength 强度 62.owner 船主，物主 31.service 航区、服务 63.encyclop(a)edia 百科全书

Additional Terms and Expressions 1.the Chinese Society of Naval Architecture and Marine Engineering(CSNAME)中国造船工程学会

the Chinese Society of Navigation中国航海学会

“Shipbuilding of China‖ 中国造船 Ship Engineering 船舶工程

“Naval 安定Merchant Ships” 舰船知识

China State Shipbuilding Corporation(CSSC)中国船舶工业总公司

China offshore Platform Engineering Corporation(COPECO)中国海洋石油平台工程公司

Royal Institution of Naval Architects(RINA)英国皇家造船工程师学会

Society of Naval Architects and Marine Engineers(SNAME)美国造船师与轮机工程师协会

10.Principle of naval architecture 造船原理 11.ship statics(or statics of naval

architecture)造船静力学 12.ship dynamics 船舶动力学

13.ship resistance and propulsion 船舶阻力

和推进

14.ship rolling and pitching 船舶摇摆 15.ship manoeuvrability 船舶操纵性 16.ship construction 船舶结构

17.ship structural mechanics 船舶结构力学 18.ship strength and structural design 船舶

强度和结构设计

19.ship design 船舶设计

20.shipbuilding technology 造船工艺

21.marine(or ocean)engineering 海洋工程 2.3.4.5.6.7.8.9.Note to the Text

1.range from A to B 的意思为“从A到B的范围内”，翻译时，根据这个基本意思可以按汉语习惯译成中文。例：

Lathe sizes range from very little lathes with the length of the bed in several inches to very large ones turning a work many feet in length.车床有大有小，小的车床其车身只有几英寸，大的车床能车削数英尺长的工件。

2.Such that 可以认为是such a kind/value 等的缩写，意思为“这样的类别/值等……以至于……”。译成中文是，可根据具体情况加以意译。例：

The depth of the chain locker is such that the cable is easily stowed.锚链舱的深度应该使锚链容易存储。

Possessing an attractive appearance, the ship should have the minimum net register tonnage,the factor on which harbour and oyher dues are based.Possessing an attractive appearance现在分词短语，用作表示条件的状语，意译成“船舶除有一个漂亮的外形……”。一般说，如分词短语谓语句首，通常表示时间、条件、原因等。

The factor on which…are based中的the factor是前面the minimum net register tonnage的铜谓语，而on which…are based是定语从句，修饰the factor。

4.Electronic computers make it possible to prepare series id designs for a vessel to operate in a particular service and to assess the economic returns to the shipowner for each separate design.句中的it是形式宾语，实际宾语为不定式短语 to prepare series of designs …和to assess the economic returns …

Lesson Two

Definitions, Principal Dimensions Before studying in detail the various technical branches of naval architecture it is important to define chapters.The purpose of this chapter is to explain these terms and to familiarise the reader with them.In the first place the dimensions by which the size of a ship is measured will be considered;they are referred to as ‗principal dimensions‘.The ship, like any solid body, requires three dimensions to define its size, and these are a length, a breadth and a depth.Each of these will be considered in turn.Principal dimensions Length There are various ways of defining the length of a ship, but first the length between perpendiculars will be considered.The length between perpendiculars is the distance measured parallel to the base at the level of the summer load waterline from the after perpendicular to the forward perpendicular.The after perpendicular is taken as the after side of the rudder post where there is such a post, and the forward perpendicular is the vertical line drawn through the intersection of the stem with summer load waterline.In ships where there is no rudder post the after perpendicular is taken as the line passing through the centre line of the rudder pintals.The perpendiculars and the length between perpendiculars are shown in Figure 1.The length between perpendiculars(LBP)is used for calculation purposes as will be seen later, but it will be obvious from Figure 1 that this does not represent the greatest length of the ship.For many purposes, such as the docking of a ship, it is necessary to know what the greatest length of the ship is.This length is known as the length of the extreme point at the after end to a similar point at the forward end.This can be clearly seen by referring again to Figure 1.In most ships the length overall will exceed by a considerable amount the length between perpendiculars.The excess will include the overhang of the stern and also that of the stem where the stem is raked forward.In modern ships having large bulbous bows the length overall LOA may have to be measured to the extreme point of the bulb.A third length which is often used, particularly when dealing with ship resistance, is the length on the waterline LWL.This is the distance measured on the waterline at which the ship is floating from the intersection of the stern with the waterline to the length is not a fixed quantity for a particular ship, as it will depend upon the waterline at which the ship is floating and upon the trim of the ship.This length is also shown in Figure 1.6 Breadth The mid point of the length between perpendiculars is called ‗amidships‘and the ship is usually broadest at this point.The breadth is measured at this position and the breadth most commonly used is called the ‗breadth moulded‘.It may be defined simply as the distance from the inside of plating on one side to a similar point on the other side measured at the broadest part of the ship.As is the case in the length between perpendiculars, the breadth moulded dose not represent the greatest breadth the breadth extreme is required(see Figure 2).In many ships the breadth extreme is the breadth moulded plus the thickness of the shell plating where the strakes of shell plating were overlapped the breadth extreme was equal to the breadth moulded plus four thicknesses of shell plating, but in the case of modern welded ships the extra breadth consists of two thicknesses of shell plating only.The breadth extreme may be much greater than this in some ships, since it is the distance from the extreme overhang on one side of the ship to a similar point on the other side.This distance would include the overhang of decks, a feature which is sometimes found in passenger ships in order to provide additional deck area.It would be measured over fenders, which are sometimes fitted to ships such as cross channel vessels which have to operate in and out of port under their own power and have fenders provided to protect the sides of the ships when coming alongside quays.Depth The third principal dimension is depth, which varies along the length of the ship but is usually measured ant amidships.This depth is known as the ‗depth moulded and is measured from the underside of the plating of the deck at side amidships to the base line.It is shown in Figure 2(a).It is sometimes quoted as a ‗depth moulded to upper deck‘ or ‗depth moulded to second deck‘, etc.Where no deck is specified it can be taken the depth is measured to the uppermost continuous deck.In some modern ships there is a rounded gunwale as shown in Figure 2(b).In such cases the depth moulded is measured from the intersection of the deck line continued with the breadth moulded line.Other features

The three principal dimensions give a general idea of the size of a ship but there are several other features which have to be considered and which could be different in two ships having the same length, breadth and depth.The more important of these will now be defined.Sheer Sheer is the height of the deck at side above a line drawn parallel to the base and tangent to the length of the ship and is usually greatest at the ends.In modern ships the deck line at side often has a variety of shapes: it may be flat with zero sheer over some distance on either side of amidships and then rise as a straight line towards the ends;on the other hand there may be no sheer at all on the deck, which will then be parallel to the base over the entire length.In older ships the deck at side line was parabolic in profile and the sheer was quoted as its value on the forward and after perpendiculars as shown in Figure 1.So called ‗standard‘ sheer was given by the formulae:

Sheer forward(in)=0.2Lft+20 Sheer aft

(in)=0.1Lft+10 These two formulae in terms of metric units would give:

Sheer forward

(cm)=1.666Lm+50.8 Sheer aft

(cm)=0.833Lm+25.4 It will be seen that the sheer forward is twice as much as the sheer aft in these standard formulae.It was often the case, however, that considerable variation was made from these standard values.Sometimes the sheer forward was increased while the sheer after was reduced.Occasionally the lowest point of the upper deck was some distance aft of amidships and sometimes departures were made from the parabolic sheer profile.The value of sheer and particularly the sheer forward was to increase the height of the deck above water(the ‗height of platform‘ as it was called)and this helped to prevent water being shipped when the vessel was moving through rough sea.The reason for the abolition of sheer in some modern ships is that their depths are so great that additional height of the deck above water at the fore end is unnecessary from a seakeeping point of view.Deletion of sheer also tends to make the ship easier to construct, but on the other hand it could be said that the appearance of the ship suffers in consequence.Camber Camber or round of beam is beam is defined as the rise of the deck of the ship in going from the side to the centre as shown in Figure 3(a).The camber curve used to be parabolic but here again often nowadays straight line camber curves are used or there may be no camber at all on decks.Camber is useful on the weather deck of a ship from a drainage point of view, but this may not be very important since the ship is very rarely upright and at rest.Often, if the weather deck of a ship is cambered, the lower decks particularly in passenger ships may have no camber at all, as this makes for horizontal decks in accommodation which is an advantage.Camber is usually stated as its value on the moulded breadth of the ship and standard camber was taken as one-fiftieth of the breadth.The camber on the deck diminishes towards the ends of the ship as the deck breadths become smaller.Bilge radius An outline of the midship section of a ship is shown in Figure 3(a).In many ‗full‘ cargo ships the section is virtually a rectangle with the lower corners rounded off.This part of the section is referred to as the ‗bilge‘ and the shape is often circular at this position.The radius of the circular arc forming the bilge is called the ‗bilge radius‘.Some designers prefer to make the section some curve other than a circle in way of the bilge.The curve would have a radius of curvature which increases as it approaches the straight parts of the section with which it has to link up.Rise of floor The bottom of a ship at amidships is usually flat but is not necessarily horizontal.If the line of the flat bottom is continued outwards it will intersect the breadth moulded line as shown in Figure 3(a).The height of this intersection above base is called the ‗rise of floor ‘.The rise of floor is very much dependent on the ship form.In ships of full form such as cargo ships the rise of floor may only be a few centimeters or may be eliminated altogether.In fine form ships much bigger rise of floor would be adopted in association with a larger bilge radius.Flat of keel

A feature which was common in the days of riveted ships what was known as ‗flat of keel ‘ or ‗flat of bottom ‘.Where there is no rise of floor, of course, the bottom is flat from the centre line to the point where the curve of the bilge starts.If there was a rise of floor it was customary for the line of the bottom to intersect the base line some distance from the centre line so that on either side of the centre line there was a small portion of the bottom which was horizontal, as shown in Figure 3(a).this was known as the ‗flat of bottom‘ and its value lay in the fact that a rightangle connection could be made between the flat plate keel and the vertical centre girder and this connection could be accomplished without having to bevel the connecting angle bars.Tumble home Another feature of the midship section of a ship which was at one time quite common but has now almost completely disappeared is what was called ‗tumble home‘.This is the amount which the side of the ship falls in from the breadth moulded line, as shown in Figure 3(b).Tumble home was a usual feature in sailing ships and often appeared in steel merchant ships before World War II.Ships of the present day rarely employ this feature since its elimination makes for ease of production and it is of doubtful value.Rake of stem In ships which have straight stems formed by a stem bar or a plate the inclination of the stem to the vertical is called the ‗rake‘.It may be defined either by the angle to the vertical or the distance between the intersection of the stem produced with the base line and the forward perpendicular.When ships have curved stems in profile, and especially where they also have bulbous bows, stem rake cannot be simply defined and it would be necessary to define the stem profile by a number of ordinates at different waterlines.In the case of a simple straight stem the stem line is usually joined up with the base line by a circular are, but sometimes a curve of some other form is used, in which case several ordinates are required to define its shape.Draught and trim The draught at which a ship floats is simply the distance from the bottom of the ship to the waterline.If the waterline is parallel to the keel the ship is said to be floating on an even keel, but if the waterline is not parallel then the ship is said to be trimmed.If the draught at the after end is greater than that at the fore end the ship is trimmed by the stern and if the converse is the case it is trimmed by the bow or by the head.The draught can be measured in two ways, either as a moulded draught which is the distance from the base line to the waterline, or as an extreme draught which is the distance from the bottom of the ship to the waterline.In the modern welded merchant ship to the waterline.In the modern welded merchant ship these two draughts differ only by one thickness of plating, but in certain types of ships where, say, a bar keel is fitted the extreme draught would be measured to the underside of the keel and may exceed the moulded draught of by 15-23cm(6-9in).It is important to know the draught of a ship, or how much water the ship is ‗drawing‘, and so that the draught may be readily obtained draught marks are cut in the stem and the stern.These are 6 in high with a space of 6in between the top of one figure and the bottom of the next one.When the water level is up to the bottom of a particular figure the draught in feet has the value of that figure.If metric units are used then the figures would probably be 10 cm high with a 10 cm spacing.In many large vessels the structure bends in the longitudinal vertical plane even in still water, with the result that the base line or the keel does not remain a straight line.The mean draught at which the vessel is floating is not then simply obtained by taking half the sum of the forward and after draughts.To ascertain how much the vessel is hogging or sagging a set of draught marks is placed amidships so that if da, d and df are the draughts at the after end amidships and the forward end respectively then

Hog or sag=

dadf-d

2When use is made of amidship draughts it is necessary to measure the draught on both sides of the ship and take the mean of the two readings in case the ship should be heeled one side or the other.The difference between the forward and after draughts of s ship is called the ‗trim‘, so that trim T=da-df, and as previously stated the ship will the said to be trimming by the stern or the bow according as the draught aft or the draught forward is in excess.For a given total load on the ship the draught will have its least value when the ship is on an even keel.This is an important point when a ship is navigating in restricted depth of water or when entering a dry dock.Usually a ship should be designed to float on an even keel in the fully loaded condition, and if this is not attainable a small trim by the stern is aimed at.Trim by the bow is not considered desirable and should be avoided as it reduces the ‗height of platform‘ forward and increases the liability to take water on board in rough seas.Freeboard Freeboard may be defined as the distance which the ship projects above the surface of the water or the distance measured downwards from the deck to the waterline.The freeboard to the weather deck, for example, will vary along the length of the ship because of the sheer of the deck and will also be affected by the trim, if any.Usually the freeboard will be a minimum at amidships and will increase towards the ends.Freeboard has an important influence on the seaworthiness of a ship.The greater the freeboard the greater is the above water volume, and this volume provides reserve buoyancy, assisting the ship to rise when it goes through waves.The above water volume can also help the ship to remain afloat in the event of damage.It will be seen later that freeboard has an important influence on the range of stability.Minimum freeboards are laid down for ships under International Law in the form of Load Line Regulations.(from ―Naval Architecture for Marine Engineers‖ by W.Muckle, 1975)

Technical Terms

1.principal dimension 主要尺度

2.naval architecture 造船（工程）学 3.造船工程（设计）师

4.length between perpendiculars(LBP)垂线间长 5.summer load waterline 夏季载重水线 6.forward/after perpendicular 首/尾垂线 7.rudder post 尾柱 8.stem 首柱

9.rudder pintle 舵销

10.length over all(LOA)总长

11.overhang（水线以上）悬伸部分 12.bulbous bow 球鼻艏

13.length on the waterline（LWL）水线长 14.amidship 船中

15.breath moulded 型宽 16.breath extreme 最大船宽 17.shell plating 船壳板 18.rivet 铆接 19.weld 焊接

20.strake（船壳板）列板 21.fender 护舷木

22.deck area 甲板面积（区域）23.cross channel vessel 海峡船 24.port 港口，船的左舷 25.side 舷侧（边）26.quay 码头

27.depth moulded 型深 28.plating of deck 甲板板 29.base line 基线 30.upper deck 上甲板 31.second deck 第二甲板

32.the uppermost continuous deck 最上层连续甲板 33.rounded gunwale 圆弧舷边顶部 34.moulded line 型线 35.sheer 舷弧 36.ends 船端

37.deck line at side 甲板边线 deck at side line 甲板边线 deck at side

甲板边线 38.profile

纵剖面（图），轮廓 39.sheer forward/aft 首/尾舷 40.platform

平台

41.rough sea

强浪，汹涛海面 42.seakeeping

耐波性

43.appearance

外形（观），出现 44.camber

梁拱

round of beam 梁拱 45.weather deck 露天甲板 46.drainage 排水

47.upright 正浮，直立 48.at rest 在静水中

49.accommodation 居住舱，适应 50.bilge radius

舭（部）半径 5.1 midship section 船中剖面 52.bilge

舭（部）53.rise of floor 船底升高 54.flat of keel 龙骨宽 55.flat plate keel平板龙骨 56.vertical center girder 中桁材

57.bevel

折射角，将直角钢改为斜角 58.connecting angle 联接角钢

59.tumble home 内倾 60.sailing ship 帆船

61.steel merchant ship 钢质商船 62.bar 棒，巴（气压单位）63.rake 倾斜

64.draught 吃水，草图，通风 65.even keel 等吃水，正浮

66.trimmed by the stern/bow 尾/首倾 67.moulded draught 型吃水 68.extreme draught 最大吃水 69.bar keel 棒龙骨 70.‖drawing‖“吃水” 71.draught marks 吃水标志 72.imperial unit 英制单位 73.metric unit 公制单位 74.spacing 间距 75.hogging 中拱 76.sagging 中垂 77.heel

横倾 78.dry dock 干船坞

79.fully loaded condition 满载标志 80.freeboard 干舷

81.seaworthiness 适航性

82.reserve buoyancy 储备浮力 83.range of stability 稳性范围

84.Load Line Regulations 载重线规范

Additional Terms and Expressions

1.form coefficients 船型系数 2.block coefficient 方型系数 3.prismatic coefficient 棱型系数

4.midship area coefficient 船中横剖面面积系数

5.waterplane area coefficient 水线面面积系数

6.vertical prismatic coefficient 竖向棱型系数 7.body section of U-form U形横剖面 8.V-shaped section V形横剖面

9.geometrically similar ships 几何相似船 10.base plane 基平面

11.center plane 中线面 12.midstation plane 中站面 13.moulded base line 基线 14.length breadth ratio 长度比 15.cruiser stern 巡洋舰型尾

16.principal coordinate planes 主坐标面 17.transom 方尾 18.soft chine 圆舭 19.hard chine 尖舭 20.counter 尾伸部 21.forefoot 首踵 22.aftfoot 尾踵

23.deadwood 尾鳍（呆木）

Notes to the Text

1.as will be seen later 和as is the case in the length between perpendiculars 中as 引出的从句为非限制性定语从句。关系代词as代替整个主句，并在从主语中作主语。as 也可在从句中作宾语，表语用。

2.A third length 序数字前面，一般用定冠词“the”，但当作者心目中对事物总数还不明确，或还不足以形成一个明确的序列时，序数字前面用不定冠词“a”。例：

will they have to modify the design a fourth time?(它们的设计究竟要修改多少次，心中无数，但依次下来已是第四次，所以用不定冠词“a”。)3.This is the distance measured on the waterline at which the ship is floating from the intersection of the stern with the waterline to the intersection of the stem with the waterline.这是一个符合据。其中at which the ship is floating 为定语从句，修饰the waterline.from the intersection of the stern(with the waterline为intersection 所要求的介词短语)to the intersection of the stern(with the waterline 为第二个intersection 所要求的介词短语）都属于介词短语，作状语用，说明测量的范围。

4.参见第一课注3.中的第二部分说明 5.quay 一般指与海岸平行的码头

pier 系指与海岸或呈直角面突出的码头

wharf 一般用于的码头

6.the deck line continued 和the stern produced 为过去分词作后置定语，分别修饰“the deck line 和the stern.都可译成“延长时”。

considerable variation was made from these standard values 和departures were made from the parabolic sheer profile 和（when）use is made of amidship draughts 这三句都属于主语的成分被位于动词隔离成两部分。这是英语句子结构平衡的需要中带有这种情况，阅读和翻译时需加以注意。

7.considerable variation was made from these standard values 和departures were made from the parabolic sheer profile 和（when）use is made of amidship draughts 这三句都属于主语的成分被位于动词隔离成两部分。这是英语句子结构平衡的需要中带有这种情况，阅读和翻译时需加以注意。Lesson Three

Merchant ship Types Break-bulk cargo ships

The inboard space in break bulk cargo ships is pided longitudinally by transverse bulkheads, spaced 40-70 ft apart, into a series of cargo compartments of approximately equal volume, generally seven for a ship of about 500 ft Lap.Vertically, the bulkheads are pided by one or two decks below the uppermost, continuous deck(main or strength deck).The space between the inner bottom and the lowest deck, called the hold, is limited to a height of about 18 ft(5.5m)to minimize damage to cargo through crushing.Usually the height of each space between decks termed between deck space)is 9-10ft(2.7-3.0m).In addition to the previously mentioned double-bottom tanks, the most break-bulk cargo ships have deep tanks used for fuel oil, water ballast, or liquid cargoes such as latex, coconut oil, or edible oils.The cargo is handled through large rectangular deck openings(hatches)over each cargo space.Mechanically operated hatch covers are used to close the openings.The hatch covers in the tween decks are strong enough to support cargo stowed on them.The topside hatch covers are watertight.The tween deck space is generally suitable for break-bulk or palletized cargo holds have had one hatch per deck, with of 35-50% the ship‘s breath and a length of 50-60% the hold length.The trend is toward widen hatches or multiple hatches abreast and often longer hatches, to increase cargo handling speed.A multiple hatch arrangement(triple hatch, for instance)is efficiently used for a partial load of containers stowed under deck.Break-bulk cargo handling between pier and ship is done usually by means of cargo booms installed on board.The booms are raised or lowered by adjustable wire rigging led from the mast or king post to the boom ends.A wire rope leads over sheaves from a winch to the outer end of each boom and terminates in a cargo hook.Cargo can be hoisted using one boom(customarily for very heavy loads of cargo, 10 tons or over)or for faster handling, by a pair of married booms, with one boom end over the hatch and the other over the pier.This cargo handling operation, called burtoning, is customary for loads up to 10 tons.Most break-bulk cargo ships fitted with booms have a pair of booms at each hatch end to expedite cargo handling.The cargo is often piled together in a large net which is emptied and returned for the next load.Packaged cargo of nearly uniform dimensions may be stacked on pallets which are hoisted aboard inpidually.The sling load is landed through the hatch opening.The pallets or nets are then unloaded, and each item is inpidually stowed by the hold gang.Any cargo stowed in the wings of the hold is manhandled unless it is on pallets and handled by a forklift truck.The use of forklift trucks is becoming common practice, and a number of these trucks may be carried on board if they are not available at cargo terminals.The amount of cargo which is manhandled onboard determines largely the ship turnaround and port expenses, and, the profitability of the transportation system.Most break-bulk cargo ships have provisions for a heavy lift boom of 30-100-metric ton capacity for occasional units of heavy cargo.An increasing number of break-bulk cargo ships are being fitted with revolving deck cargo cranes instead of masts, booms and winches.Container ships

Container ships are replacing the conventional break-bulk cargo ship in trade routes where rapid cargo handling is essential.Containers are weatherproof boxes(usually metal)strengthened withstand stacking and motion at sea.Containers are of standard size, the largest ones weighing up to about 30 metric tons when loaded.The use of standard containers facilitates ship-board stowage, land or waterway transportation, and rental or lease.A large container ship may be loaded or unloaded completely in about half a day, compared to several days for the same amount of cargo in break-bulk cargo ship.Generally, the shipper places the cargo in the container and，except for custom inspection, it is delivered unopened to the consignee.Highway trailers(most commonly), railroad cars, or barges transport containers to and from their land destination and are therefore apart of the same transportation system.For a given payload cargo capacity, container ships are larger and more costly to build than the traditional cargo ship, but both the cargo handling cost and the idle ship time in port are reduced considerably.Although in some ships containers are moved horizontally for loading and unloading, the predominant arrangement is that illustrated in Fig.1 where containers are stowed in vertical cells and moved vertically in and out of the vessel.Roll-on/Roll-off ships

With a broad interpretation all ships that are designed to handle cargo by rolling it on wheels can be considered under this heading.This would include trailer ships;sea trains(carrying railroad cars or entire carriers: ships carrying pallets handled by forklift trucks from and to shore;and so on, the following is a description of a ship of this type, which is intended primarily to operate as a trailer ship, although it may handle several types of wheeled vehicles.Roll-on/Roll-off ships require a high proportion of cubic capacity relative to the amount of cargo and are particularly suited to services with short runs and frequent loading and unloading.They need even shorter port time than container ships but their building cost is higher.Because fully loaded toll-on/roll-off ships can not carry enough cargo to immerse them deeply, their large freeboard allows the fitting of side ports above the waterline for handling of cargo on wheels by means of ramps.Usually, ships of this type have a transom stern(a square-shaped stern like that of a motorboat)fitted with doors for handling wheeled vehicles on an aft ramp.Roll-on/Roll-off ships have several decks, and the cargo is handled on wheels from the loading deck to other decks by elevators or sloping ramps.Both internal elevators and ramps occupy substantial volume in the ship.The need for clear decks, without interruption by transverse bulkheads, and tween decks for vehicle parking results in a unique structural arrangement.Barge-carrying ships

This type of ship represents a hold step in the trend toward cargo containerization and port time reductions.Cargo is carried in barges or lighters each weighing up to 1000 metric tons when loaded.The lighters are carried below and above deck and handled by gantry cranes or elevator platforms.These are among the fastest, largest, and costest ships for the carriage of general cargo.For their size, their payload capacity is less than that of the conventional break-bulk cargo ship.However, they can be loaded and unloaded much faster and with a considerable saving in man-hours.Because the lighters can be waterborne and operated as regular barges, these large ships can serve undeveloped ports advantageously.Using portable fixtures that can be erected quickly, barge-carrying ships can be adapted for the transport of varying amounts of standard containers in addition to or in plane of lighters.Bulk cargo ships

A large proportion of ocean transportation is effected by bulk cargo ships.Dry bulk cargo includes products such as iron ore, coal, limestone, grain, cement, bauxite gypsum, and sugar.Most oceangoing dry bulk carriers are loaded and unloaded using shore side installations.Many dry bulk carriers operating in the Great Lakes have shipboard equipment for the handling of cargo(self-unloaders), and an increasing number of oceangoing ships carrying this type of cargo are being fitted with self-unloading gear.By far the largest amount of liquid bulk cargo consists of petroleum products, but ocean transportation of other bulk liquid products is increasing in importance;for example, various chemicals, vegetable oils, molasses, latex, liquefied gases, molten sulfur, and even wine and fruit juices.Practically all liquid bulk carriers have pumps for unloading the cargo, usually have ship board pumps for unloading liquids.Practically all bulk carriers have the machinery compartment, crew accommodations, and conning stations located aft.An exception is the Great Lakes self-unloader with crew accommodations and bridge forward.The tendency in bulk carriers is toward larger ships, with speeds remaining about constant at moderate level(16-18 knots or 30-33 km/h for oceangoing ships, lower for Great Lakes vessels).The oceangoing ore carrier is characterized by a high double bottom and small volume of cargo hold because of the high density of the ore.Storing the cargo high in the ship decreases stability and prevents excessively quick rolling.The oceangoing combination bulk carrier permits low-cost transportation because of its flexibility.It is able to carry many types of bulk cargoes over a variety of sea lanes.This type of ship carries bulk cargoes, such as petroleum product, coal, grain, and ore.The double bottom in bulk carriers is shallow and the volume of cargo holds is large compared to the size of the ship.The tanker is the characteristic, and by far the most important, liquid bulk carrier both in numbers and tonnage.Tankers carry petroleum products almost exclusively.The very large tankers are used almost entirely for the transport of crude oil.A few tankers are built especially for the transportation of chemical products, and others are prepared for alter native loads of grain.Bulk liquid carriers, with standing, rectangular, cylindrical, or spherical cargo tanks separated from the hull, are used for the transportation of molten sulfur and liquefied gases, such as anhydrous ammonia and natural gas.Liquefied natural gas(LNG)is also carried in ships with membrane tanks, i.e., where a thin metallic linear is fitted into a tank composed of ship structural and load-bearing insulation.The transportation of molten surfur and liquefied gases requires special consideration regarding insulation and high structural soundness of cargo tanks, including the use of high grade, costly materials for their construction.(From ―McGraw-Hill Encyclopedia of Science and Technology‖, Vol.8.1982).Passenger-cargo ships

The accommodations for passengers in this type of ship are located to assure maximum comfort.Generally a passenger-cargo ship serves ports that have an appeal for the tourist trade and where rather special, high freight-rate cargo is handled.Because of the service needs of passengers, a ship of this type requires a much larger crew than a merchant ship of comparable size engaged exclusively in the carriage of cargo.The living accommodations for passengers consist of staterooms with 1-4 berths, each room with bath and toilet.A few rooms may be connected and suites may include a living room, dressing room, and even a private outdoor veranda.Public rooms for passenger use may include dining room, lounge, cocktail room, card and game room, library, shops, and swimming pool.Ships carrying more than 12 passengers must comply with the SOLAS regulations.These regulations deal with ship characteristics related to items such as the following:(1)lessening the risk of foundering or capsizing due to hull damage,(2)preventing the start and spread of fires aboard, and(3)increasing the possibility and safety of abandoning ship in emergencies.The ship in Fig.2 is an interesting example of a departure from the traditional break-bulk cargo ship in which cargo is handled almost exclusively by means of a ship board installation of masts and booms.This ship is provided with gantry cranes to handle containers, vehicles, and large pallets.The containers may be stored in cargo holds equipped with container cells or on deck.Large-size pallets and vehicles may be handled through side ports by means of an athwart-ship gear called a siporter.Wheeled vehicles can also be rolled on and off the ship through the side ports.Cargo may be carried to and from lower decks by cargo elevators, and, in addition, there are vertical conveyors for handling cargo such as bananas.The horizontal conveyors shown in the typical section receive cargo automatically, mostly on pallets, from the cargo elevators.This cargo is then stowed by manually controlled, battery operated pallet loaders.Cargo for the forward hold is handled by a 5-ton burtoning cargo gear and transferred to lower levels by a cargo elevator.(From ―McGraw – Hill Encyclopedia of Science and Technology‖, Vol.12, 1977)

Technical Terms

1.break-bulk cargo ship 件杂货船 26.king post 吊杆柱，起重柱 2.inboard 船内 27.wire rope 钢丝绳 3.compartment 舱室 28.sheave

滑轮 4.transverse bulkhead 横舱壁 29.winch 绞车 5.main deck 主甲板 30.cargo hook 吊货钩 6.strength deck 强力甲板 31.married booms 联合吊杆 7.inner bottom 内底 32.burtoning 双杆操作 8.hold(cargo hold)货舱 33.cargo handling 货物装卸 9.tween deck space 甲板间舱 34.packaged cargo 包装货 10.double bottom 双层底 35.pallet 货盘 11.deep tank 深舱 36.sling load

悬吊荷重 12.water ballast 水压载 37.hold gang 货舱理货组 13.latex 胶乳 38.wings 货舱两侧 14.coconut oil 椰子油 39.forklift truck 铲车 15.edible oil 食用油 40.terminal 码头，终端 17.hatch 舱口 41.turnaround 周转期 18.hatch cover 舱口盖 42.profitability 利益 19.palletized cargo 货盘运货 43.container ship 集装箱船 20.multiple hatch 多舱口 44.trade route 贸易航线 21.abreast 并排 45.weather proof 风雨密 22.container 集装箱 46.stacking 堆压 23.pier 码头 47.stowage 装载，贮藏 24.cargo boom 吊货杆 48.waterway 水路 25.wire rigging 钢索索具 49.rental 出租（费）50.lease 租借 51.shipper 货运主 52.custom 海关

53.consignee 收货人

54.highway trailer 公路拖车

55.payload 净载重量，有效载荷 56.cell 格栅，电池，元件 57.roll-on/roll-off ship 滚装船 58.heading 标题，航向 59.trailer ships 拖车运输船

60.sea trains ferry 海上火车渡船 61.truck 卡车 62.trailer 拖车

63.military vehicle carriers 军用车辆运输船

64.cubic capacity 舱容 65.ramp 跳板，坡道 66.transom stern 方尾

67.motor boat 机动艇，汽艇 68.clear deck 畅通甲板 69.parking 停车（场）

70.barge-carrying ship 载驳船 71.lighter 港驳船 72.barge 驳船

73.portable fixture 轻便固定装置

74.bulk cargo ship/bulk carrier 散装货船 75.dry bulk cargo 散装干货 76.limestone 石灰石 77.bauxite 矾土 78.gypsum 石膏

79.Great Lakes（美国）大湖 80.petroleum 石油

81.chemicals 化学制（产）品 82.molasses 糖浆

83.liquefied gas 液化气体 84.molten sulfur 熔态硫 85.conning station 驾驶室

86.ore hold 矿砂舱 87.空

88.engine room 机舱

89.liquid bulk carrier 液体散货船

90.combination bulk carrier 混装散货船 91.ocean-going ore carrier 远洋矿砂船 92.lane 航道（线）93.tanker 油船 94.crude oil 原油

95.anhydrous ammonia 无水氨 96.natural gas 天然气

97.passenger-cargo ship 客货船 98.tourist 旅游者 99.freight-rate 运费率

100.carriage 装（载）运，车辆 101.stateroom 客舱 102.suite 套间

103.living room 卧室 104.veranda 阳台 105.lounge 休息室

106.cocktail room 酒吧间

107.card and game room 牌戏娱乐室 108.foundering 沉没 109.capsizing 倾覆 110.abandoning 弃船 111.emergency 应急

112.installation 装置，运载工具 113.vehicle 车辆，运载工具 114.gantry crane 门式起重机 115.container cell 集装箱格栅 116.siporter 横向装卸机

117.rolled on and off 滚进滚出 118.side port 舷门

119.cargo elevator 运货升降机 120.conveyor 输送机

Additional Terms and Expressions 1.2.3.4.transport ship 运输船 general cargo ship 杂货船 liquid cargo ship 液货船 refrigerated ship 冷藏船

5.6.7.8.working ship 工程船

ocean development ship 海洋开发船 dredger 挖泥船

floating crane/derrick boat 起重船 9.salvage vessel 救捞船 10.submersible 潜水器 11.ice-breaker 破冰船 12.fisheries vessel 渔业船 13.trawler 拖网渔船

seine netter 围网渔船 14.harbour boat 港务船 15.supply ship 供应船 16.pleasure yacht 游艇

17.hydrofoil craft 水翼艇 18.air-cushion vehicle 气垫船

hovercraft 全垫升气垫船 19.catamaran 双体船 20.concrete ship 水泥船

21.fiberglass reinforced plastic boat 玻璃钢

艇

Notes to the Text

1.unless 连接词，作“如果不”，“除非”解释，例如：

An object remain at rest or moves in a straight line unless a force acts upon it.一个物体如无外力作用，它将继续保持静止或作直线运动。

In this book the word is used in its original sense unless(it is)otherwise sated.本书内，这个词按其意采用，除非另有说明。2.“to and from 名词”或“from and to +名词” 后面的名词委前面两个介词公用，可译作“来回于（名词）之间”。

3.with a broad interpretation 具有广泛的意思

under this heading 属于这个范畴

4.barge 和lighter 一般都可以译作驳船，但barge 往往指货物经过较长距离运输到达某一目的地，故译作“驳船”，而lighter 旨在港口或近距离内起到装卸货物的联络作用，故译作“驳船”。

5.in additional to or in place of lighters 是in addition to lighters or in place of lighters 的省略形式，翻译成中文时，不一定能省略。

6.“by far +形容词（或副词）的最高级或比较及”具有“远远，非常，最„，或„得多”的意思。例：

by far the fastest 最快的

by far faster than A 远比A快（比A 快得多）

By far the most common type of fixed offshore structure in existence today is the template, or jacket, structure illustrated in Fig 1.1.现今最普遍采用的固定平台型式是图1.1所示的导管架平台。

7.the SOLAS regulations 系指国际海上人命安全公约规则，几乎所有海运国家都要遵守这些规则。其中的“SOLAS”为“International Convention for the Safety Of Life At Sea‖的缩写。Lesson Four

Ship Design

The design of a ship involves a selection of the features of form, size, proportions, and other factors which are open to choice, in combination with those features which are imposed by circumstances beyond the control of the design naval architect.Each new ship should do some things better than any other ship.This superiority must be developed in the evolution of the design, in the use of the most suitable materials, to the application of the best workmanship, and in the application of the basic fundamentals of naval architecture and marine engineering.As sips have increased in size and complexity, plans for building them have became mare detailed and more varied.The intensive research since the period just prior to World War 2 has brought about many technical advances in the design of ships.These changes have been brought about principally by the development of new welding techniques, developments in main propulsion plants, advances in electronics, and changes in materials and methods of construction.All ships have many requirements which are common to all types, whether they are naval, merchant, or special-purpose ships.The first of such requirements is that the ship must be capable of floating when carrying the load for which it was designed.A ship floats because as it sinks into the water it displaces an equal weight of water, and the pressure of the water produces an upward force, which is called the buoyancy force is equal to the weight of the water displaced by the ship and is called the displacement.Displacement is equal to the underwater volume of the ship multiplied by the density of the water in which it is gloating.When floating in still water, the weight of the ship, including everything it carries, is equal to the buoyancy or displacement.The weight of the ship itself is called the light weight.This weight includes the weight of the hull structure, fittings, equipment, propulsion machinery, piping and ventilation, cargo-handling equipment and other items required for the efficient operation of the ship.The load which the ship carries in addition to its own weight is called the deadweight.This includes cargo, passengers, crew and effects, stores, fresh water, feed water for the boilers incase of steam propelling machinery, and other weights which may be part of the ships international load.The sum of all these weights plus the lightweight of the ship gives the total displacement;that is

Displacement = lightweight + deadweight

One of the first things which a designer must do is to determine the weight and size of the ship and decide upon a suitable hull form to provide the necessary buoyancy to support the weight that has been chosen.Owner’s requirements

Ships are designed, built, and operated to fulfill, the requirements and limitations specified by the operator and owner.These owner‘s requirements denote the essential considerations which are to form the basis for the design.They may be generally stated as(1)a specified minimum deadweight carrying capacity,(2)a specified measurement tonnage limit,(3)a selected speed at sea, or a maximum speed on trial, and(4)maximum draft combined with other draft limitations.In addition to these general requirements, there may be a specified distance of travel without refueling and maximum fuel consumption per shaft horsepower hour limitation, as well as other items which will influence the basic design.Apart from these requirements, the ship owner expects the designer to provide a thoroughly efficient ship.Such expectations include(1)minimum displacement on a specified deadweight carrying capacity,(2)maximum cargo capacity on a minimum gross tonnage,(3)appropriate strength of construction,(4)the most efficient type of propelling machinery with due consideration to weight, initial cast, and cost of operation,(5)stability and general seaworthiness, and(6)the best loading and unloading facilities and ample accommodations for stowage.Design procedure

From the specified requirements, an approach is made to the selection of the dimensions, weight, and displacement of the new design.This is a detailed operation, but some rather direct approximations can be made to start the design process.This is usually done by analyzing data available from an existing ship which is closely similar.For example, the design displacement can be approximated from the similar ship‘s known deadweight of, say, 11790 tons and the known design displacement of 17600 tons.From these figures, a deadweight-displacement ratio of 0.67 is obtained.Thus, if the deadweight for the new design is, for example, 10000 tons, then the approximate design displacement will 10,000/0.67 or 15000 tons.This provides a starting point for the first set of length, beam, and draft dimensions, after due consideration to other requirements such as speed, stability, and strength.Beam is defined as the extreme breath of a ship at its widest part, while draft is the depth of the lowest part of the ship below the waterline.Length and speed These factors are related to the hull form, the propulsion machinery, and the propeller design.The hull form is the direct concern of the naval architect, which the propulsion machinery and propeller design are concern.The naval architect has considerable influence on the final decisions regarding the efficiency, weight, and size of the propeller, as both greatly influence the design of the hull form.Speed has an important influence on the length selected for the ship.The speed of the ship is related to the length in term of the ratio V/

L, where V is the speed in knots and L is the effective waterline length of the ship.As the speed-length ratio increases, the resistance of the ship increases.Therefore, in order to obtain an efficient hull form from a resistance standpoint, a suitable length must be selected for minimum resistance.Length in relation to the cross-sectional area of the underwater form(the prismatic coefficient), is also very important insofar as resistance is concerned.Fast ships require fine(slender)forms or relatively low fullness coefficients as compared with relatively slow ships which may be designed with fuller hull forms.Beam and stability

A ship must be stable under all normal conditions of loading and performance at sea.This means that when the ship is inclined from the vertical by some external force, it must return to the vertical when the external force is removed.Stability may be considered in the transverse or in the longitudinal direction.In surface ship, longitudinal stability is much less concern than transverse stability.Submarines, however, are concerned with longitudinal stability in the submerged condition.The transverse stability of a surface ship must be considered in two ways, first at all small angles of inclination, called initial stability, and second at large angles of inclination.Initial stability depends upon two factors,(1)the height of the center gravity of the ship above the base line and(2)the underwater form of the ship.The center of gravity is the point at which the total weight of the ship may be considered to be concentrated.The hull form factor governing stability depends on the beam B, draft T, and the proportions of the underwater and waterline shape.For a given location of the center of gravity, the initial stability of the ship is proportional to B2/T.Beam, therefore, is a primary factor in transeverse stability.At large angles of heel(transeverse inclination)freeboard is also an important factor.Freeboard is the amount the ship projects above the waterline of the ship to certain specified decks(in this case, to the weatherdeck to which the watertight sides extend).Freeboard affects both the size of the maximum righting arm and the range of the stability, that is the angle of inclination at which the ship would capsize if it were inclined beyond that angle.5 Depth an strength

A ship at sea is subjected to many forces because of the action of the waves, the motion of the ship, and the cargo and other weights, which are distributed throughout the length of the ship.These forces produces stresses in the structure, and the structure must be of suitable strength to withstand the action.The determination of the minimum amount of material required for adequate strength is essential to attaining the minimum weight of the hull.The types of structural stress experienced by a ship riding waves at sea are caused by the unequal distribution of the weight and buoyancy throughout the length of ship.The structure as a whole bends in a longitudinal plane, with the maximum bending stresses being found in the bottom and top of the hull girder.Therefore, depth is important because as it is increased, less material is required in the deck and bottom shell.However, there are limits which control the maximum depth in terms of practical arrangement and efficiency of design.(From ―McGraw-Hill Encyclopedia of science and Technology‖, Vol.12, 1982)

Technical Terms

1.form 船型，形状，格式 22.distance of travel 航行距离 2.proportion 尺度比，比例 23.refueling 添加燃料 3.workmanship 工艺质量 24.consumption 消耗 4.basic fundamentals 基本原理 25.initial cost 造价 5.marine engineering 轮机工程 26.cost of operation 营运成本 6.intensive 精致的 27.unloading facility 卸货设备 7.propulsion plants 推进装置 28.cross sectional area 横剖面面积 8.naval ship 军舰 29.fineness 纤瘦度 9.special-purpose ship 特殊用途船 30.prismatic coefficient 菱形系数 10.buoyancy 浮力 31.slender 瘦长（型）11.fittings 配/附件 32.beam 船宽 12.piping 管路 33.inclined 倾斜的 13.ventilation 通风 34.external force 外力 14.cargo-handing equipment 货物装卸装35.surface ship 水面船舶

置 36.submarine 潜水艇 15.crew and effects 船员及自身物品 37.submerged condition 潜水状态 16.stores 储藏物 38.initial stability 初稳性 17.fresh water 淡水 39.weather deck 楼天甲板 18.feed water 给水 40.righting arm 复原力臂 19.boiler 锅炉 41.capsize 倾复 20.measurement(吨位)丈量，测量 42.stress 应力 21.trial 试航，试验 43.unequal distribution 分布不相等 44.longitudinal plane 纵向平面 45.hull girder 船体梁

AdditionalTerms and Expressions

1.tentative design 方案设计 2.preliminary design 初步设计 3.technical design 技术设计 4.working design 施工设计 5.basic design 基本设计

6.conceptual design 概念设计 7.inquire design 咨询设计 8.contract design 合同设计 9.detailed design 详细设计 10.finished plan 完工图

11.hull specification 船体说明书 12.general specification 全船说明书 13.steel weight 钢料重量

14.outfit weight（木作）舾装重量 15.machinery weight 机械重量 16.weight curve重量曲线

17.weight estimation 重量估计

18.cargo capacity 货舱容积

19.bale cargo capacity 包装舱容积 20.bulk cargo capacity 散装货容积 21.bunker capacity 燃料舱容积 22.capacity curve 容积曲线 23.capacity plan 容量（积）图 24.stowage factor 积载系数

25.homogenuous cargo 均质货物 26.gross tonnage 总吨位 27.net tonnage 净吨位

28.tonnage capacity 量吨容积 29.tonnage certificate 吨位证书

30.displacement length ratio 排水量长度比 31.accommodation 居住舱室 32.ice strengthening 冰区加强 33.drawing office 制图室 34.drafting room 制图室

Notes to the Text 1.A ship floats because as it sinks into the water it displace an equal weight of water, and pressure of the water produces an upward force which is called buoyancy.这是一个复合句。

从because开始至句末均属原因状语从句，它本身也是一个复合句，包含有以下从句：

as it sinks into the water 为整个原因状语从句中的时间状语从句;

it displaces an equal weight of water, and pressure of the water produces an upward 为整个原因状语从句中的两个并列的主要句子；

which is called buoyancy 为定语从句，修饰an upward force.2.In addition to 除……以外（还包括……）

例：In addition to these general requirements, … 除了这些一般要求外，还有……

而在The load which the ship carries in addition to its own weight is called the deadweight中的in addition to 应理解成“外加在它本身重量上的”，故应译为“本身重量除外（不包括本身重量）。

3.插入语，相当于 for example.一般在口语中用得比较多。

4.注意 ―ton‖, ―tonne‖, 和 ―tonnage‖ 三个词的区别。ton和tonne一般用来表示船舶的排水量和载重量，指重量单位。其中ton可分long ton(英吨)和 short ton(美吨)，而tonne为公吨；tonnage 是登记吨，表征船舶容积的一种单位。

5． …the angle of inclination at which the ship would cap