毕业设计电梯外文翻译

ELEVATOR SAFETY :GIVE THE MINER ABRAKE ABSTRACT

Over a five-year period,there were at least 18 documented cases of ascending elevators striking the overhead.In some cases,the accidents resulted in serious injuries or fatalities.These accidents occurred on counterweighted elevators as a result of electrical,mechanical,and structural failures.Elevator cars are fitted with safeties that grip the guide rails and stop a falling car;however,these devices do not provide protection in the uoward direction.

Rules and regulatioins applying to elevator safety have come under review in response to these accidents .Some governing authorities have already revised their regulations to require ascending car overspeed protection. this paper will discuss basic elevaton design ,hazard,regulation,and emergency braking systems designed to provide ascending car overspeed protection.In addition ,a case-study report on a pneumatic rope brake system installed and tested on a mine elevator will be discussed.

INTRODUCTION

Elevators incorporate several safety features to prevent the car from crashing into the bottom of the shaft .safeties installed on the car can prevent this type of accident form occurring when the machine brake fails or the wire ropes suspending the car break .However,the inherent design of the safeties render them inoperative in the ascending direction.

In the upward direction, the machine brake is required to stop the cage when an emergency condition occurs.Under normal operation,the machine brake serves only as a parking braked to hold the cage at rest .However,when an emergency condition is detected,modern elevator

control system designs rely solely on the machine brake to stop the car.

In theUnited States mining industry,the accident history has proven that this is not the best control strategy [2],[3].These accidents occurred when the retarding effort of the drive motor was defeated when the mechanical brake were inoperative.This allowed the counterweight to fall to the bottom of the shaft,causing the car to overspeed and strike the headframe.The high-speed elevator crashes into the overhead structure caused extensive mechanical damage and potentially fatal injuries.

ELEVATOR DESIGN

A basic understanding of elevator opration is required in order to assess the safety hazards present and determine the accident prevent methods available.Figure 1 shows a complete view of a mine elevator.

In a typical elevator,the car is raised and lowered by six to eight motor-driven wire ropes that are attached to the top of the car at one end,travel around a pair of sheaves,and are again attached to a counterweight at the other end .

The counterweight adds accelerating force when the elevator car is ascending and provides a retarding effort when the car is descending so that less motor horsepower is required.The counterweight is a collection of metal weights that is equal to the weighe of the car containing about 45% of its rated load. A set of chains are looped from the bottom of the counterweight to the underside of the car to help maintain balance by offsetting the weight of the suspension ropes.

Guide rails that run the length of the shaft keep the car and counterweight from swaying or twisting during their travel. Rollers are attached to the car and the counterweight to provide smooth travel along the guide rails

The traction to rasie and lower the car comes from the friction of the wire rope against the grooved sheaves .The main sheave is driven by an electric motor.

Most elevators use a direct current motor because its speed can be precisely controlled to allow smooth acceleration and deceleration.Motor-generator(M-G) sets typically provide to do power for the drive motor.Newer systems use a static drive control. The elevator controls vary the motor’s speed based on a set of feedback signals that indicate the car’s position in the shaftway.As the car approaches its destination,a switch near the landing signals the controls to stop the car at floor level.Additional shaftway limit switches are installed to monitor overtravel conditions.

The worst fear of many passengers is that the elevator will go out of control and fall through space until it smashes into the bottom of the shaft .There are several safety feature in modern elevators to prevent this from occurring.

The first is the high-strength wire ropes themselves. Each 0.625-in-diameter extra-high-strength wire rope can support 32,0001b,or about twice the average weight of a mine elevator filled with 20 passengers. For safety’s sake and to reduce wear,each car has six to eight of these cables.In addition, elevators have buffers intstalled at the shaft bottom that can stop the car without killing its passengers if they are struck at the normal speed of the elevator.

As previously discussed, modern elevators have several speed control features. If they do not work ,the controls will disconnect the motor and apply the machine brake.Finally,the elevator itself is equipped with safeties mounted underneath the car.If the car surpasses the rated speed by15 to16%,the governor will trip ,and the safeties will grip the guide

rails and stop the car.This was the invention that made elevator transportation acceptable for the general public.

SAFETY HAZARDS

A historical perspective of elevator development can account for today’s problems with elevator safety rules and regulations[4].In the beginning of modern elevator history,it was realized that although there were several factors of safety in the suspension rope design,the quality of construction and periodic inspection could not be assured .Therefore,the elevator cai was equipped with reliable stand by”safeties”that would stop the car safely if the suspension rope failed .In 1853, Elisha Otis,a New York mechanic,desingned and demonstrated an instantaneous safety capable of safely stopping a free-falling car. This addressed the hazard shown in figure2.

Later on,it was realized that passengers may be injured when the car overspeeds in the down direction with suspension ropes intact,as shown in figure 3.To prevent this hazard, an overspeed governor with gradually applied safeties was developed.It detected the overspeeding condition and activated the safeties.

Furthermore,it was noticed that frequent application of safeties caused mechanical stress on the elevator structure and safety system.Therefore,a governor overspeed switch was installed that would try to stop the car by machine brake before the safeties activated.The switch was a useful idea because it could also initiate stopping in the case of overspeeding in the up direction as well.

The problem started in the 1920’s when the American Elevator Safety Code was developed.The writers most likely looled at the technology that was available at that time and subsequently required it on all elevators covered by the Code.

The writers were so concentrated on describing the design of the required devices that they forgot to acknowledge the hazards’ that the devices are guarding against and the elevator components that may fail and cause the hazards.They did not consider the fact that for 90% of the elevator trips,the elevator is partially loaded(i.e.less than 45% of rated load)[5].Therefore,if a brake failure occurs,the elevator will overspeed and crash in the up direction as shown in figure 4.

Until recently,elevator safety systems have not differed significantly from the early 1990’s designs.The problem arises because rulemaking committees and regulatory authorities are reluctant to require new safeguards when the technology has not been fully developed.Conversely,the elevator manufacturing industry cannot justify the product development expense for a new safety device with little marketability.This problem will be addressed in the following sections.

RULES AND REGULATIONS

Several rulemaking committees and government safety authorities have addressed the deficiencies in the existing elevator regulations and have proposed revisions to the elevator safety codes.

The report-form the American Society of Mechanical Engineers-A17 Mechanical Design Committee on “Cars ascending into the building overhead”-dated September 1987,contained the type of failures that could result in elevators accelerating into overhead structure and an analysis of the possible solutions.In addition,a proposal to the A17.1Committee for a new code Rule 205.6 was introduced as follows:

R205.6(“Prevention of overspeeding car from striking the overhead structure”):All traction elevarors shall be provided with a means to prevent an ascending car from striking the overhead structure .This means shall conform to the following requirements:

1.Prior to the time when the counterweighe strikes its buffer,it shall reduce the speed of the car to the speed for which the counterweight buffer is designed.

2.It shall not develop an average retardation of the car in excess of 32.2 ft/s2 (9.81 m/s2) during the stopping phase.

3.It shall be a mechanical means independent of the driving machine brake.

4. It shall prevent overspeeding of the elevator system through the control of one or more of the following:

a.counterweight

b.car

c.suspension or compensating rope system.

This proposed rule is currently under committee review,and condideration has been given to requiring protection to prevent the car from leaving the landing with the doors opened or unlocked.

Pennsy I vania Bureau of Deep Mine Safety

An ascending elevator car accident occurred at a western Pennsylvania coal mine on February 4,1987 and caused extensive structural damage and disable the elevator for two months.Following this accident,the Pennsylvania Bureau of Deep Mine Safety established an advisory committee to determine these devices that are available o provide ascending car overspeed protection for new and existing mine elevator installations.

The following four preotective methods were determined to be feasible base on engineering principles or extensive mine testing.

1)Weight balancing (counterweight equals the empty car weight)

2)counterweight safeties

3)dynamic braking

4)rope brake

The Pennsylvania Bureau of Deep Mine Safety has approved these four methods and has made ascending car overspeed protection mandatory on all exishting counterweighted mine elevators.

Dynamic Braking

A second solution used in the United States mining industry is the application of passive dynamic braking to the elevator drive motor [6].As mentioned earlier, most elevators use direct current drive motors that can perform as generators when lowering an overhauling load .Dynamic braking simply connects a resistive load across the motor armature to dissipate the electrical energy generated by the falling counterweight. The dynamic braking control can be designed to function when the main power is interrupted.Dynamic braking does not stop the elevator but limits the runaway speed in either direction;therefore,the buffers can safely stop the conveyance.

Rope Brake

A pneumatic rope brake that grips the suspension ropes and stops the elevator during emergency conditions has been developed by Bode Aufzugel[7].This rope brake has been used in the Netherlands since August 12,1957.

Case Study :Rope Brake Test an Evaluation

The first pneumatic rope brake was installed in the United States at a western Pennsylvania coal mine on September 8,1989.The largest capacity Bode rope brake (model 580)was installed on this coal mine elevator.This

rope brake installation was tested extensively by Mine Safety and Health Administration engineers from the Pittsburgh Safety and Health Technology Center.A summary of the findings will be presented in this study.

Function

The rope brake is a safety device to guard against overspeed in the upward and downward directions and to provide protection for uncontrolled elebvator car movements.

The rope brake is activated when the normal running speed is exceeded by 15% as a result of a mechanical drive ,motor control system,or machine brake failure .The rope brake does not guard against free fall as a result of a break in the suspension ropes.

Standstill of the elevator car is also monitored by the rope brake system .If the elevator car moves more than 2 to 8 inches in either direction when the doors are open or not locked,the rope brake is activated and the control circuit interrupted.The rope brake control must be manually reset to restore normal operation.

The rope brake also provides jammed conveyance protection for elevator and friction driven hoists.If the elevator car does not move when the drive sheave is turning,the rope brake will set,and the elevator control circuit will be interrupted.

The rope brake control contains self-monitoring features.The rope brake is activated if a signal is not received from the pulse tachometer when the drive is running.

The rope brake requires electrical power and air pressure to function properly.The rope brake sets if the control power is interrupted. When the power is restored,the rope brake will automatically release.

Typically,elevator brakeing systems are spring applied and

electrically release. Therefore, external energy source is needed to set the brake requires stored pressurized air to set the brake and stop the elevator .Therefore,montoring of the air pressure is essential. If the working air pressure falls below a preset minimum,the motor armarure current is interrupted ,and the machine brake is set.When the air pressure is restored,the fault string is reset.

Pneumatic Design

The rope brake system is shown in figure 5.Starting from the air compressor tank,the pressurized air passes through a water separator and manual shut off valve to a check valve.The check valve was required to ensure the rope brake remains set even if an air leak develops in the compressed air supply.A pressure switch monitors for low air pressure at this point and will set the machine brake ai mentioned earlier.The air supply is split after the check valve and goes to two independent magnetic two-way valves.The air supply is shut off(port A),while the magnetic valve coil is energized .When the magnetic valve coil is deenergized,the air supply is directed to the Bport,which is open to the rope brake cylinder.The air pushes the piston inside the rope brake cylinder and forces a movable brake pad toward a stationary brake pad.The suspension ropes are claped between the two brake pads. The rope brake is released by energizing the magnetic valve,which vents the pressurized rope brake cylinder to the atmosphere through a blowout silencer on port S

The force exerted on the suspension ropes equals the air pressure multiplied by the surface area of the piston .The rope brake model number 580 designates the diameter of the brake cylinder in millimeters.This is translates into 409.36 in2 of the surface area.The working air pressure varies from 90 to 120 lbf/in2.The corresponding range of force

applied to the suspension ropes is 36,842 to 49,123lb.The rope experience a 6 to 41% greater force duiing emergency conditions than normally encountered duiing full load operation .

Mechanical Modifications

Prior to testing , several mechanical modifications were required to protect the rope brake system from environmental and mechanical damage .The modifications also reduced the possibility and the underirable effect of an air leak in the pneumatic system .The following modifications were included in the rope brake design.

1.The 200lbf/in2 rated plastic air hose was replaced with 2000lbf/in2 rated metal braided hose with integral couplings.

2.The air hose compression fittings were replaced by stainless steel threaded connectors.

3. All the electrical components were installed in protective enclosures, and the wiring was installed in conduit.

4.A check valve was installed in the compressed air supply line to hold the rope in the applied position once it was set even if air pressure was lost in the air compressor tank.

5.The added check valve required an additional pressure switch to monitor the supply air pressure .The original pressure switch would not detect a pressure loss in the air compressor tank when the check valve was installed .The contacts of the two pressure switches were installed in series.

Mechanical Testing

Tests were conducted to determine if the rope brake would operate reliably in the mining environment to provide ascending car overspeed

protection.

First,accelerated mechanical testing was performed to determine if the braking system could withstand repeated operation without experiencing significant wear or failure.These tests were performed while the suspension ropes were stationary.This testing was conducted at both the mine site installation and in the laboratory.

Mine site testing was conducted every 4hr.Mechanical counters were installed on both the machine brake and the rope brake to record the total number of oprations for each brake.Every 4hr,the number of times the machine brake had set during the previous 4hr period was noted ,and then ,the rope brake was operated an equal number of times.

The mechanical testing concluded after 30days of around the clock testing.The total number of rope brake operations was 3430.The temperature range varied from 25 to 83.

One of the rope brake components subjected to wear was the piston ring gasket.This gasket provides the air seal between the moving piston,which presses against the traveling brake pad,and the stationary cylinder.Anoverload test was conduted to determine the integrity of this seal.

For the test,8750lb(125% of rated load ) was loaded onto the car at the bottom of the shaft .Then,the rope brake was set ,and the machine brake was disengaged.The air pressure was released from the air compressor tank, and the air pressure inside the rope brake cylinder was monitored .The load was successfully held stationary for 1hr .The initial air pressure was 114lbf/in2,and after 1hr,the pressure was 102lbf/in2.The pressured reduction may be attributed to an air leak through the check valve or past the piston ring gasket as a result of wear.

Laborantory mechanical tests were also performed on the rope brake in the Mine Electical Systems Division laboratories located at the Pittsburgh Safety and Health Technology Center.The testing was performed on the smaller Bode rope brake model 200.The rope brake system was positioned outside the laboratory building under an awning that allowed the brake system to be exposed to the outside air temperature and humidity but was protected from direct contact with the rain dan snow.The computer was programmed to apply and then releasa the rope brake every 38s and log the number of operations.The outside air temperature ,relative humidity ,and barometric pressure were also continuously recorded.

After 2 mo of testing and 146,836 operations,the rope brake was disassembled and inspected for wear.The pneumatic piston ring gasket exhibited minimal wear.Superficial rust was evident where the compressed air entered the rope brake and displaced the lubricant.

Over the 70days of testing ,the temperature ranged from 5 to 82,and the relative humidity varied from 25 to 100%.At times, thick accumulations of frost build up on the air line between the magnetic valve and the rope brake cylinder.Therefore, the formation of ice inside the compressed air lines was possible ,however,no adverse affects were observed .Rope Brake Control Failure Analysis.

In addition to the previously discussed mechanical analysis ,testing and evaluation of the rope brake electrical control system was conducted .Brake control system studies were performed at the mine site and in the laboratory .The safety evaluation was conducted to ensure that a single undertected failure would not defeat the protection provided by the ropt brake .

Component failure should be detected by the brake control

system。 an cause the elevator or stop safely and remain at rest until the failure is corrected .If automatic detection was not feasible ,the periodic inspection and maintenance procedures were required to specify detailed testing of the possible failed component.

The rope brake control system,which is shown in figure 6,monitors the following four inputs:M contacor,speed relay,pressure switch ,and the rope pulse tachometer .Based on this input information ,the brake logic decides to set the machine brake or both the machine brake and the rope brake. A test board was designed and built to simulate the brake control inputs with toggle switches and to provide relay coil loads for the brake logic output.A separate power source supplied 24Vdc to the simulator board and brake control box .Evaluation of this simulation board provided the following information on the function of each input.

软件开发概念和设计方法大学毕业论文外文文献翻译及原文

毕业设计（论文）外文文献翻译 文献、资料中文题目：软件开发概念和设计方法文献、资料英文题目： 文献、资料来源： 文献、资料发表（出版）日期： 院（部）： 专业： 班级： 姓名： 学号： 指导教师： 翻译日期： 2017.02.14

外文资料原文 Software Development Concepts and Design Methodologies During the 1960s, ma inframes and higher level programming languages were applied to man y problems including human resource s yste ms,reservation s yste ms, and manufacturing s yste ms. Computers and software were seen as the cure all for man y bu siness issues were some times applied blindly. S yste ms sometimes failed to solve the problem for which the y were designed for man y reasons including: ?Inability to sufficiently understand complex problems ?Not sufficiently taking into account end-u ser needs, the organizational environ ment, and performance tradeoffs ?Inability to accurately estimate development time and operational costs ?Lack of framework for consistent and regular customer communications At this time, the concept of structured programming, top-down design, stepwise refinement，and modularity e merged. Structured programming is still the most dominant approach to software engineering and is still evo lving. These failures led to the concept of "software engineering" based upon the idea that an engineering-like discipl ine could be applied to software design and develop ment. Software design is a process where the software designer applies techniques and principles to produce a conceptual model that de scribes and defines a solution to a problem. In the beginning, this des ign process has not been well structured and the model does not alwa ys accurately represent the problem of software development. However,design methodologies have been evolving to accommo date changes in technolog y coupled with our increased understanding of development processes. Whereas early desig n methods addressed specific aspects of the

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外文资料名称： Design and performance evaluation of vacuum cleaners using cyclone technology 外文资料出处：Korean J. Chem. Eng., 23(6), (用外文写) 925-930 (2006) 附件： 1.外文资料翻译译文 2.外文原文

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毕业设计外文翻译资料

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Optimum blank design of an automobile sub-frame Jong-Yop Kim a ,Naksoo Kim a,*,Man-Sung Huh b a Department of Mechanical Engineering,Sogang University,Shinsu-dong 1,Mapo-ku,Seoul 121-742,South Korea b Hwa-shin Corporation,Young-chun,Kyung-buk,770-140,South Korea Received 17July 1998 Abstract A roll-back method is proposed to predict the optimum initial blank shape in the sheet metal forming process.The method takes the difference between the ?nal deformed shape and the target contour shape into account.Based on the method,a computer program composed of a blank design module,an FE-analysis program and a mesh generation module is developed.The roll-back method is applied to the drawing of a square cup with the ˉange of uniform size around its periphery,to con?rm its validity.Good agreement is recognized between the numerical results and the published results for initial blank shape and thickness strain distribution.The optimum blank shapes for two parts of an automobile sub-frame are designed.Both the thickness distribution and the level of punch load are improved with the designed blank.Also,the method is applied to design the weld line in a tailor-welded blank.It is concluded that the roll-back method is an effective and convenient method for an optimum blank shape design.#2000Elsevier Science S.A.All rights reserved. Keywords:Blank design;Sheet metal forming;Finite element method;Roll-back method

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基于PLC的电梯控制系统设计中英文翻译部分 - 副本

本科毕业设计（论文）中英文对照翻译 院（系部）电气工程与自动化 专业名称电气工程及其自动化 年级班级 学生姓名 指导老师 2013年6月1日

Elevator System Based on PLC Composed by the order of relay control system is a realization of the first elevator control method. However, to enter the nineties, with the development of science and technology and the widespread application of computer technology, the safety of elevators, reliability of the increasingly high demand on the relay control weaknesses are becoming evident. Elevator control system relays the failure rate high, greatly reduces the reliability and safety of elevators, and escalators stopped often to take with the staff about the inconvenience and fear. And the event rather than taking the lift or squat at the end of the lift will not only cause damage to mechanical components, but also personal accident may occur. Programmable Logic Controller (PLC) is the first order logic control in accordance with the needs of developed specifically for industrial environment applications to operate the electronic digital computing device. The PLC biggest characteristics lie in: The electrical engineering teacher already no longer electric hardware up too many calculations of cost, as long as order the importation that the button switch or the importation of the sensors order to link the PLC up can solve problem, pass to output to order the conjunction contact machine or control the start equipments of the big power after the electric appliances, but the exportation equipments direct conjunction of the small power can. PLC internal containment have the CPU of the CPU, and take to have an I/ O for expand of exterior to connect a people's address and saving machine three big pieces to constitute, CPU core is from an or many is tired to add the machine to constitute, mathematics that they have the logic operation ability, and can read the procedure save the contents of the machine to drive the homologous saving machine and I/ Os to connect after pass the calculation; The I/ O add inner part is tired the input and output system of the machine and exterior link, and deposit the related data into the procedure saving machine or data saving machine; The saving machine can deposit the data that the I/ O input in the saving machine, and in work adjusting to become tired to add the machine and I/ O to connect, saving machine separately saving machine RAM of the procedure saving machine ROM and dates, the ROM can do deposit of the data permanence in the saving machine, but RAM only for the CPU computes the temporary calculation usage of hour of buffer space.

毕业设计外文翻译

毕业设计外文资料翻译 设计题目: 译文题目: 太阳能蒸笼 学生姓名： 学号： 专业班级： 指导教师： 正文：外文资料译文附件：外文资料原文

太阳能蒸笼 罗达.斯坦塔食品和营养学助理 许多不同的系统介绍了太阳能炊具。不同的设计有不同的优势。它也表明太阳能灶还处于初级阶段,将有希望有个美好的未来,不仅有助于解决气候变化问题,而且在做一件重要的事,服务许多人的生命。

大部份太阳能炊具有某种形式的反光罩的集中太阳的能量。太阳轮使用不反光但集中太阳能通过创造蒸汽从相对较大的收集器区域,并将其用于一个较小的烹饪区。随着太阳能轮使用蒸汽作为传热媒介,它是一种间接的烹饪系统。这允许一个分裂的烹饪系统,其热太阳能集热器可以放置在某个距离(如在屋顶上)除了烹饪的地方(例如在厨房里)。厨师正在不接触阳光的并且可以用蒸汽,无论高低都方便,可接受的区域。 这使它成为一个非常方便的炊具为大量的食物。使用简单叠加可以蒸煮几样菜，可以煮熟的同时进行。那热气腾腾的过程是非常相似与传统蒸煮过程，应该容易得到各种文化的认可。 太阳所产生的蒸汽也可以被用来热量大的罐炖肉或汤通过引导蒸汽直接进入了液体在它凝聚和释放的热凝。这就引起我做一个温柔的风潮的食品烤干。 在其设计技术,利用太阳船的有效性标准疏散管太阳能集热器可降低成本。 配料系统 可以看出从素描以上基本的想法是很简单的。太阳能收集器里装满了水。因为它具有极高的效率和良好的保温玻璃管的撤离开始沸腾的水会暴露在阳光下时。蒸汽会被引导到蒸笼以灵活的、蒸汽抗性软管。 连续系统

最后更复杂的,因为它必须确信,玻璃管永远不会变干的。一滴滴喂料系统集成式换热器提供了一条连续的淡水来代替水流失为蒸汽。这也防止了重建的盐和污染的太阳能集热器。因为这个系统包含了大量的沸腾的水在玻璃管,它具有使绝对肯定,没有压力,建立该体系。 成本 为了保持成本低，Sun2Steam正在出售一转换工具包可以很容易地安装在一个标准的低成本太阳能集热器。此套将直接来自澳大利亚,而太阳能收集器可直接来源于一个低成本的供应商。 一个太阳能集热器和20管直径和57mm 1.8米长，在中国是可以买到的大约200美元。转换组件包括500万绝缘软管取决于汇率蒸汽将大约200美元。成本增加25%,装船的税负导致的总费用为500美元左右的太阳能船没有安装费用和培训。 这使得轮船进入上部成本支架太阳能炊具。然而所有的材料都要持久和完整的炊具应该很容易超过了一生的10年。炉子可以很容易地帮助准备食物为10人。这使人均成本的太阳能减少至约五十美元。 也有一些额外的好处。太阳轮能生产大约5升的高质量的蒸馏水一天所产生的凝汽。一个可选的转换器将允许生产超过100升的安全、pasteurised饮水每天。报告描述太阳能蒸笼在这里可以找到: 大多数高海拔的烹饪和烘烤的指示不推荐补偿,直到你到达约6000英尺的海拔高度。居住在该地区,并且现在我住在怀俄明,是正确的,我们的高度范围你真正开始注重细微的差别,所以我已经学会补偿烤时和烹饪。 水沸腾时会出现在较低的温度在这里——这是由于减少了空气压力。你不会真正注意到什么大的差异在4000英尺,甚至在6000英尺,唯一的真正的区别是面带最微小的更久一点做饭,和糙米试你的耐心一点超过正常(以接近一个小时做饭,而不是通常的40分钟)。糖果还可以要求较长的沸腾时期达到各种球类或裂缝阶段。最引人注目的差异在这个高度是烤面包。蛋糕是一个倾向于看起来更温柔,更容易摔跤在中间。面包做一些有趣的事情。 蛋糕混合料通常会表明你应该添加额外的勺面粉加入混合,如果你是在高海拔超过5-6000呎。你可能需要补偿甚至更多,如果你是比那更高一些。

毕业设计外文翻译---控制系统介绍

英文原文 Introductions to Control Systems Automatic control has played a vital role in the advancement of engineering and science. In addition to its extreme importance in space-vehicle, missile-guidance, and aircraft-piloting systems, etc, automatic control has become an important and integral part of modern manufacturing and industrial processes. For example, automatic control is essential in such industrial operations as controlling pressure, temperature, humidity, viscosity, and flow in the process industries; tooling, handling, and assembling mechanical parts in the manufacturing industries, among many others. Since advances in the theory and practice of automatic control provide means for attaining optimal performance of dynamic systems, improve the quality and lower the cost of production, expand the production rate, relieve the drudgery of many routine, repetitive manual operations etc, most engineers and scientists must now have a good understanding of this field. The first significant work in automatic control was James Watt’s centrifugal governor for the speed control of a steam engine in the eighteenth century. Other significant works in the early stages of development of control theory were due to Minorsky, Hazen, and Nyquist, among many others. In 1922 Minorsky worked on automatic controllers for steering ships and showed how stability could be determined by the differential equations describing the system. In 1934 Hazen, who introduced the term “ervomechanisms”for position control systems, discussed design of relay servomechanisms capable of closely following a changing input. During the decade of the 1940’s, frequency-response methods made it possible for engineers to design linear feedback control systems that satisfied performance requirements. From the end of the 1940’s to early 1950’s, the root-locus method in control system design was fully developed. The frequency-response and the root-locus methods, which are the