轮机英语课文

Lesson 1HOW DOES A MARINE DIESEL ENGINE WORK?The diesel engine is a type of internal combustion engine which ignites the fuel by injecting it into hot, high pressure air in a combustion chamber. The marine diesel engine is a type of diesel engine used on ships. The principle of its operation is as follows:A charge of fresh air is drawn or pumped into the engine cylinder and then compressed by the moving piston to very high pressure.When the air is compressed, its temperature rises so that it ignites the fine spray of fuel injected into the cylinder. The burning of the fuel adds more heat to the air charge, causing it to expand and force the engine piston to do work on the crankshaft which in turn drives the ship's propeller.The operation between two injections is called a cycle, which consists of a fixed sequence of events. This cycle may be achieved either in four strokes or two. In a four-stroke diesel engine, the cycle requires four separate strokes of the piston, i.e. suction, compression, expansion and exhaust. If we combine the suction and exhaust operations with the compression and expansion strokes, the four-stroke engine will be turned into a two-stroke one, as is shown in Figures l (a)-(d).The two-stroke cycle begins with the piston coming up from the bottom of its stroke, i.e. bottom dead centre (BDT), with the air inlet ports or scavenge ports in the sides of the cylinder being opened (Fig. 1 (a)). The exhaust ports are uncovered also. Pressurised fresh air charges into the cylinder, blowing out any residual exhaust gases from the last stroke through the exhaust ports.As the piston moves about one fifth of the way up, it closes the inlet ports and the exhaust ports. The air is then compressed as the piston moves up (Fig. 1 (b)).When the piston reaches the top of its stroke, i.e. the top dead center (TDC), both the pressure and the temperature of the air rise to very high values. The fuel injector injects a fine spray of fuel oil into the hot air and combustion takes place, producing much higher pressure in the gases.The piston is forced downward as the high pressure gases expand (Fig. 1 (c)) until it uncovers the exhaust ports. The burnt gases begin to exhaust (Fig. 1(d)) and the piston continues down until it opens the inlet ports. Then another cycle begins.In the two-stroke engine, each revolution of the crankshaft makes one power or working stroke, while in the four-stroke engine, it takes two revolutions to make one power stroke. That is why a two stroke cycle engine will theoretically develop twice the power of a four stroke engine of the same size. Inefficient scavenging and other losses, however, reduce the power advantage to about 1.8.Each type of engine has its application on board ship. The low speed (i.e. 90 to 120 r/min) main propulsion diesel operates on the two-stroke cycle. At this low speed the engine requires no reduction gearbox between it and propeller. The four-stroke engine (usually rotating at medium speed, between 250 to 750 r/min) is used for alternators and sometimes for main propulsion with a gearbox to provide a propeller speed of between 90 to 120 r/min.READING MATERIALWORKING CYCLESA diesel engine may be designed to work on the two-stroke or on the four-stroke cycle. Both of them are explained below.The Four-Stroke CycleFigure 2 shows diagrammatically the sequence of events throughout the typical four-stroke cycle of two revolutions. It is usual to draw such diagrams starting at TDC (firing) but the explanation will start at TDC (scavenge). Top dead centre is some times referred to as inner dead centre (IDC).Proceeding clockwise round the diagram, both inlet (or suction) and exhaust valves are initially open. (All modern four-stroke engines have poppet valves.) If the engine is naturally aspirated, or is a small high-speed type with a centrifugal turbocharger, the period of valve overlap, i.e. when both valves are open, will be short, and the exhaust valve will close some 10o after top dead centre (ATDC).Propulsion engines and the vast majority of auxiliary generator engines running at speeds below 1,000 r/min will almost certainly be turbocharged and will be designed to allow a generous throughflow of scavenge air at this point in order to control the turbine blade temperature. In this case the exhaust valve will remain open until exhaust valve closure (EVC) at 50-60o ATDC. As the piston descends to outer or bottom dead centre (BDC) on the suction stroke, it will inhale a fresh charge of air. To maximise this, balancing the reduced opening as the valve seats against the slight ram or inertia effect of the incoming charge, the inlet (suction) valve will normally held open until about 25-35o ABTC (145-155o BTDG). This event is called inlet valve closure (IVC). The charge is then compressed by the rising piston until it has attained a temperature of some 550o C. At about 10-20o BTDC (firing), depending on the type and speed of the engine, the injector admits finely atomised fuel which ignites within 2-7o (depending on the type again) and the fuel burns over a period of 30-50o, while the piston begins to descend on the expansion stroke, the piston movement usually helping to induce air movement to assist combustion.At about 120-150o ATDC the exhaust valve opens (EVO), the timing being chosen to promote a very rapid blow-down of the cylinder gases to exhaust. This is done: (a) to preserve as much energy as is practicable to drive the turbocharger, and (b) to reduce the cylinder pressure to a minimum by BDC to reduce pumping work on the 'exhaust' stroke. The rising piston expels the remaining exhaust gas and at about 70-80o BTDC the inlet valve opens (IVO) so that the inertia of the outflowing gas, plus the positive pressure difference, which usually exists across the cylinder by now, produces a through flow of air to the exhaust to ’scavenge’ the cylinder.If the engine is naturally aspirated the IVO is about 10o BTIDC. The cycle now repeats.The Two-Stroke CycleFigure 3 shows the sequence of events in a typical two-stroke cycle, which, as the name implies, is accomplished in one complete revolution of the crank. Two-stroke engines invariably have ports to admit air when uncovered by the descending piston. The exhaust may be via ports adjacent to the air ports and controlled by the same piston (loop scavenge) or via poppet exhaust valves at the other end of the cylinder (uniflow scavenge).Starting at TDC combustion is already under the way and the exhaust opens (EO) at 110-120o ATDC to promote a rapid blow-down before the inlet opens (IO) about 20-30o later (130-150o ATDC). In this way the inertia of the exhaust gases-- moving at about the speed of sound-- iscontrived to encourage the incoming air to flow quickly through the cylinder with a minimum of mixing, because any unexpelled exhaust gas detracts from the weight air entrained for the next stroke.The exhaust should close before the inlet on the compression stroke to maximise the charge, but the geometry of the engine may prevent this if the two events are piston controlled. It can be done in an engine with exhaust valves.At all events the inlet ports will be closed as many degrees ABDC as opened before it (i.e. again 130-150o BTDC) and the exhaust in the same region.Injection commences at about 10-20o BTDC depending on speed and combustion lasts 30-50o, as with the four-stroke.。

EnglishofMarineEngineering（轮机英语）English of Marine Engineering（轮机英语）Unit 1 ：Main Propulsion Plant（船舶主推进装置）一、船舶动力装置概述●船舶动力装置的组成和类型、热机的类型和应用二、船舶柴油机1)船舶柴油机基本参数、特性指标2)船舶柴油机的工作原理3)船舶柴油机的基本结构4)船舶柴油机的燃油系统5)船舶柴油机的润滑系统6)柴油机的冷却系统7)柴油机的启动系统8)船舶柴油机操纵和控制系统、柴油机的运行管理、故障诊断三、船舶推进装置●推进装置的传动方式Unit 2 ：Auxiliary Machinery（船舶辅助机械）一、船用锅炉1)船用锅炉的类型和结构特点2)船用锅炉的运行管理、故障分析和排除二、船用泵1)船用泵类型；常见船用泵的工作原理和结构特点；船舶通用泵系的布置原则和特点2)常见船用泵的运行管理和故障排除三、船舶制冷和空调装置1)船舶制冷原理和制冷循环2)船舶空调系统的组成及主要设备；船舶空调装置的运行管理、故障分析和排除四、船舶防污染设备1)油水分离器的工作原理及运行管理2)焚烧炉的工作原理及运行管理3)生活污水处理装置的工作原理及运行管理五、分油机和海水淡化装置1)分油机的工作原理及运行管理2)海水淡化原理、主要设备和运行管理六、船舶甲板机械1)起货机的结构特点及其故障分析和排除2)锚机、绞缆机的结构特点及其故障分析和排除3)液压泵、控制阀件和油马达的结构特点；液压系统管理Unit 3：Marine Electrization and Automatization（船舶电气和自动化）一、船用发电机1)船用发电机的结构特点2)船用发电机的并车和解列3)船用发电机的故障分析和排除二、船用配电板1)主配电板的分类及组成2)应急配电板；配电箱三、船舶电气设备●船舶电气设备：船舶电气设备概况；电气控制设备；电气设备运行管理Unit 4 ：Marine Engineering Management（船舶轮机管理）一、操作规程●备车；巡回检查；完车二、安全管理知识1)船舶防火防爆的措施及守则2)轮机部操作安全注意事项；安全知识；机舱应急设备的使用及管理三、油、物料和备件的管理●燃油的管理四、船舶修理和检验1)修理的类别；轮机坞修工程2)船舶检验的类别与作用五、防污染管理及PSC检查1)《油类记录簿》与IOPP证书的管理2)PSC检查中的明显理由与更详细检查；PSC检查报告和缺陷的纠正Unit 5 ：International Convention and Regulations（国际公约与规则）一、STCW公约1)STCW78/95公约中有关轮机值班的基本原则2)轮机员的基本职责和道德；机架联系制度二、MARPOL公约●MARPOL73/78公约中有关含油污水的排放规则；有关国家、港口的防污染规则三、SOLAS公约●SOLAS公约的基本精神和基本原则四、ISM、ISPS等规则和公约1)ISM规则简介2)ISPS规则简介3)其他最新公约和规则。

LESSON 1Diesel enginesThe majority of ships around the world continue to be powered exclusively by diesel engines.世界范围内大多数船舶都是采用柴油机作为动力。

The predominance of diesel engines has come from improved engine efficiencies and designs compared to other forms of propulsion such as steam or gas turbines.与蒸汽机、燃气轮机等形式的动力装置相比，无论是效率上的提高，还是设计上的进步，柴油机都体现出了一定的优势。

Many combinations and configurations of diesel engine power plant exist. All provide the energy to do the work of moving the ship using diesel engines.存在有很多种联合形式及结构形式的柴油机动力装置，他们都能够利用柴油机为船舶提供推动力。

Slow speed diesel engines 低速柴油机Slow speed diesel engines are large, especially tall, and heavy and operate on the two-stroke cycle.低速柴油机是体积较大、缸体较长、机身较重的二冲程柴油机。

These are the largest diesel engines ever built. Engine powers up to 100 000kw are available from a single engine.它们是已建造过的最大型的柴油机，它们的单机可用功率可达100000 kw。

轮机英语新教材电⼦版Lesson18airconditioningsystem Lesson18 air conditioning systemShips travel the world and are therefore subject to various climatic conditons .the crew of the ship must be provided with reasonable conditions in wihich to work regardless of the weather.Temperture alone is not sufficent measure of condition acceptable to the human body. Relative humidity iin conjunction with temperature more truly determines the environment for human comfort .Relative humidity ,expressed as a percentage, is the ratio of the water vapour pressure in the air tested, to the saturated vapour pressure of air at the same temperature. The fact that less water can be absorbed as air is cooled and more can be absored when it is heated is the major consideration in air conditioning system design. Other factors are the nearness of heat sources, exposure to sunlight, sources of cold and the insulation provided around the space(Fig.18-1).An air conditioning system aims to provide a comfortable working environment regardless of outside conditions. Satisfactory air treatment must involve a relatively "closed" system where the air is circulated and returned. However, some air is "consume" by humans and some machinery so there is a requirement for renewal. Public rooms and accommodation will operate with a reduced percentage of air renewal since the conditionig cost of 100% renewal would be considerable.Air conditioning systems fall into two main classes: individual unit system, in which each room contains its own small refrigeration plant and fan and air cooler; and central systems, where larger refrigeration machinery unit are installed and their out put distributed about the ship by a variety of means.Self-contained units are noisier than central systems, require more maintenance and have been found to have a relatively short life (about 7 years).The single duct system only allows for adjustment of temperature in each room by the occupant manually controlling the air volume admitted. It is thus less flexible than any of the other systems, which allow individual temperature control, at least of sections of the ship if not individual rooms.With ducted systems, the modern tendency is to use "high velocity" in the air ducts with fans generating up to 2550 mbar(250 mm H2O) pressure compared to "low velocity" systems with fans generating up to 520 mbar(50mm H2O). This tendency helps installation as the size of ducts is reduced and prefabricated standard ducts can be used, but it incurs the heavier running costs of more powerful fans. Air terminals lined with sound insulation material are necessary to reduce the noise passing into the room with high velocity systems.In a typical marine pattern self-contained unit, air circulation is usually effected by means of a centrifugal fan, for quiet running, and a direct expansion cooler served by a hermetic compressor. Water cooled condensers are used. As these contain small water passages, choking develops rapidly with direct sea water circulation and a better method is to circulate with fresh water, itself cooled in a sea water/fresh water heat exchanger.Control is on/off by a thermostat sensing the temperature of air returning to the unit.The cooling coil of the central unit may be of the direct expansion, brine or chilled water cooled type.When cooling is by direct expansion, a separate steam heater coil is fitted in the unit for winter heating.With brine or water coolers, a central heater is used so that the same coil serves for summer or winter. Thermostatic control is provided sensing air delivery temperature itself, the temperature of the room, or the return air temperture.All types of thermostats are found in air conditioning systems, direct acting, pneumatic and electrical. In themselves, they are all satisfactory instruments, but the results they achieve are dependent on the correct sitting of their sensing elements. Even the site for a direct acting thermostst to control one single berth cabin must be chosen with care-if it is masked behind curtains, or too far away from the air inlet control will be too sluggish.The correct location for a thermostat to control a block of cabins is more difficult to find . One can pick on a "typical" cabin , but if the occupation opens his porthole he can upset the whole block. Another possibilility is to site the thermostat in the alleyway of the block of cabin . This position may be affected more by an open door or draguht in the alleyway tthan by the temperature of the cabins . Yet another possiblility is to site the thermostat in the recirculation grill is to close to an outside door , this position too can be affected by outside air temperature when the door is open ,rather than by cabin temperature. General operation of the air conditoning installationThe first enssential in operating the air cooling appliances through out the ship is to hhave all thermostats correctly set and correctly functioning . In extreme weather conditions , either hot or coold , control of the plant usually present few diffculties . The capacity of many installations is such that under tropical conditions nearly all control valves move to the full open position. Although automated control has been lost ,internal conditions are by and large acceptable.Control diffculties arise in intermediate weather conditions when there is a call for only a small amout of cooling. The worst case is when part of the ship,say inboard cabins against the engine room , require cooling and other parts ,say exposed upper cabins , require warming .For this intermediate condition,thermostats must be correctly set by trial and error. It is found that a uniform setting of say 21°C throughout the ship is not satisfactory ,but slight variations of a few degrees up or down are needed to suit particular regions of the ship. Unfortunately, these variations in thermostat setting are not always the same for the cooling and heating condition and frequent resetting may be needed for a ship repeatedly passing from cold to warm weather.The control problem is eased if the chilled brine (or water) of systems using chilled liquid circulation is held at about 13°C in the intermediate weather conditions and lowered progressively to about 5°C as tropical weather conditions are approached. When air cooling is in use it is good practice to keep all portholes, windows and doors shut. On passengerships, some public announcement requesting that this be done is worthwhile.A wise precaution for an engineer to take is to go through accommodation and public rooms periodically recording wet and dry bulb temperature. Keeping a log of these reading then serves to identify any malfunctioning of the installation as soon as it arises.The quantity of cooled air delivered by an air conditioning unit should bablance the sum of the quantity of the air recirculated to the quantity mechanically exhausted. The correct bablance between supply and exhaust fans should be checked periodically. Even with filters fitted ducts can become partially blocked can fan performance can fall off to upset the bablance.On older ships, temperature maintenance can be made easier by increasing the ratio of recirculated to fresh air. Most air conditioning units have dampers for adjusting this ratio and the effect of these can be extended after they have reached, full travel by partially blocking fresh air inlets. Care must be taken not to reduce the fresh air so that stuffiness or smells arise.Cleaning or renewal of filters is necessary at baout 3-monthly intervals, the time varying according to location on the ship. Disposable filters can be vacuum-cleaned so that in fact two or three "lives" are obtained before they need to be thrown away.In addition to normal mechanical attention, such as lubrication of bearings, and adjustment of fan belts and cleaning of motors, careful greasing of linkages of automatic controls is necessary.Cooled air ducts should be examined to see that the insulation vapour seal remains in good order. If a plastic film: vapour seal becomes damsged, condensation forms within the film. As well as making the insulation wet and ineffective, the condensation may become serious enough to cause drips and damp parches on ceilings.VentilationVentilation is the provision of a supply of fresh untreated air through a space. Natural ventilation occurs when changes in temperature or air density cause circulation in the space. Mechanical or forced ventilation uses fans for a positive movement of large quantities of air (Fig. 18-2).Natural ventilation is used for some small workshops and stores but is impractical for working areas where machinery is present or a number of people are employed.Forced ventilation may be used in cargo spaces where the movement of air removes moisture or avoids condensation, removes odors or gases,etc.The machinery space presents another area which requires ventilation. As a result of itslarge size and the fact that large volumes of air are consumed a treatment plant would be extremely costly to run. Ventilation is therefore provided the sufficient quantities for machinery air consumption and also to effect cooling. Several axial flow fans provide air through ducting to the various working platforms. The hot air rises in the centre and leaves through louvers or openings, usually in the funnel. The machinery control room, as a separate space, may well be arranged for air conditioning with an individual unit which draws air through trucking from the outside and exhausts back to the atmosphere.Notes1. Air conditioning systems fall into two main classes: individual unit system, in which each room contains its own small refrigeration plant and fan and air cooler; and central systems, where larger refrigeration machinery unit are installed and their out put distributed about the ship by a variety of means.空调系统分为两⼤类，独⽴空调系统和中央空调系统。

轮机英语翻译课文LESSON 1Diesel enginesThe majority of ships around the world continue to be powered exclusively by diesel engines.世界范围内大多数船舶都是采用柴油机作为动力。

The predominance of diesel engines has come from improved engine efficiencies and designs compared to other forms of propulsion such as steam or gas turbines.与蒸汽机、燃气轮机等形式的动力装置相比，无论是效率上的提高，还是设计上的进步，柴油机都体现出了一定的优势。

Many combinations and configurations of diesel engine power plant exist. All provide the energy to do the work of moving the ship using diesel engines.存在有很多种联合形式及结构形式的柴油机动力装置，他们都能够利用柴油机为船舶提供推动力。

Slow speed diesel engines 低速柴油机For equivalent power output, the two-stroke diesel engine is significantly lighter than its comparable four-stroke relative.对于相同的功率输出，相对于四冲程柴油机，二冲程柴油机的重量明显轻很多。

This is most apparent for large power requirements where the two-stroke engine produces much more power for the same weight.对于大功率需求场合这是一个最明显的优势，二冲程柴油机能够在相同的重量情况下，发出更大的功率。