微型风冷活塞式压缩机(W-80)的设计【含CAD图纸+PDF图】
喜欢这套资料就充值下载吧。资源目录里展示的都可在线预览哦。下载后都有,请放心下载,文件全都包含在内,【有疑问咨询QQ:414951605 或 1304139763】喜欢这套资料就充值下载吧。资源目录里展示的都可在线预览哦。下载后都有,请放心下载,文件全都包含在内,【有疑问咨询QQ:414951605 或 1304139763】
编号无锡太湖学院毕业设计(论文)相关资料题目:微型风冷活塞式压缩机(W-80)的设计 信机 系 机械工程及自动化专业学 号: 0923208 学生姓名: 顾 佳 庆 指导教师: 俞萍(职称:高级工程师) (职称: ) 2013年5月25日目 录一、毕业设计(论文)开题报告二、毕业设计(论文)外文资料翻译及原文三、学生“毕业论文(论文)计划、进度、检查及落实表”四、实习鉴定表无锡太湖学院毕业设计(论文)开题报告题目:微型风冷活塞式压缩机(W-80)的设计 信机 系 机械工程及自动化 专业学 号: 0923208 学生姓名: 顾佳庆 指导教师: 俞萍(职称:高级工程师) (职称: ) 2012年11月20日 课题来源本课题来源于企业;结合所学知识,老师拟定题目; 综合大学里所学知识,将理论与实践相互结合。科学依据(包括课题的科学意义;国内外研究概况、水平和发展趋势;应用前景等)1、 化工、冶金、化肥、食品、医疗等众多企业的生产过程需要用到气体压缩机,而活塞式空气压缩机由于有较高的压缩比,在高压气体生产与输送中尚不能被其它设备所替代,是许多工程项目中的关键设备。2、 活塞式压缩机在圆筒形气缸中具有一个可往复运动的活塞,气缸上有控制进、排气的阀门,当活塞作往复运动时,气缸的容积便周期性的变化,借以实现气体的吸进、压缩、和排出。3、 随着经济的高速发展和科学技术的不断进步,各种压缩机在国民经济各大领域大显身手,压缩机是原基础材料之一的冶金工业中极为重要的设备,又是石油化工流程中的心脏设备。车辆的制动、船用内燃机启动,航空发动机的运行都需要各种压缩机,可以说压缩机在陆海空交通运输工具中都必不可少,与人民的日常生活更是休戚相关。4、 目前压缩机制造业已经发展成为机械制造工业的一个重要组成部分。研究内容1、 微型风冷活塞式压缩机的工作原理以及工作形成;2、 微型风冷活塞式压缩机参数与结构的设计;3、 微型风冷活塞式压缩机设计图纸的绘制。拟采取的研究方法、技术路线、实验方案及可行性分析研究方法:通过阅读有关资料,文献,收集筛选,整理课题研究所需的 有关数据,理论依据,综合运用所学理论知识研究论文课题。技术路线:分析微型风冷活塞式压缩机的各个参数的取值情况,包括结 构参数、工艺参数、热力学参数和动力学参数。确定各参数 的具体数值或取值区间。可行性分析:通过对论文课题的学习研究,达到巩固,扩大,深化已学 理论知识,提高思考分析解决实际问题等综合素质的目的。研究计划及预期成果1、 首先对微型风冷活塞式压缩机整体结构进行分析,对传动结构进行筛选,初步选择达到设计要求的结构方案;2、 对压缩机的热力部分及动力部分进行计算,通过压缩机机构的分析计算可提高其自身的精度;3、 对微型风冷活塞式压缩机的主要零件进行强度校核,提高机构稳定性,稳定性。特色或创新之处通过对微型风冷活塞式压缩机的设计及计算,形成一整套现代的设计方法,对理论和实践的结合,起到整体的规划的作用,达到降低损耗提高效率,优化结构设计方便使用。已具备的条件和尚需解决的问题已具备的条件:拥有机械设计手册等参考资料及文献;对活塞式压缩机进行直观的了解与认识,对所学的机械基础知识有较好的掌握;能熟练运用CAXA制图软件,提高作图效率。尚需解决的问题:对于微型风冷活塞式压缩机的工作原理不是非常清楚 和熟悉,缺乏设计经验。 指导教师意见 指导教师签名:年 月 日教研室(学科组、研究所)意见 教研室主任签名: 年 月 日系意见 主管领导签名: 年 月 日无锡太湖学院毕业设计(论文)外文资料翻译 信机 系 机械工程及自动化 专业院 (系): 信 机 系 专 业: 机械工程及自动化 班 级: 机械95班 姓 名: 顾 佳 庆 学 号: 0923208 外文出处: 机械专业英语教程 附 件: 1.译文;2.原文;3.评分表 2013年5月25日 英文原文Efficiency And Operating Characteristics Of Centrifugal And Reciprocating Compressors By Rainer Kurz, Bernhard Winkelmann, and Saeid iVIokhatab Reciprocating compressors and centrifugal compressors have different operating characteristics and use different eificiency definitions. This article provides guidelines for an equitable comparison, resulting in a universal efficiency definition for both types of machines. The comparison is based on the requirements in which a user is ultimately interested. Further, the impact of actual pipeline operating conditions and the impact on efficiency at different load levels is evaluated. At first glance, calculating the efficiency for any type of compression seems to be straightforward: comparing the work required of an ideal compression process with the work required of an actual compression process. The difficulty is correctly defining appropriate system boundaries that include losses associated with the compression process. Unless these boundaries are appropriately defined, comparisons between centrifugal and reciprocating compressors become flawed. We also need to acknowledge that the efficiency definitions, even when evaluated equitably, still dont completely answer one of the operators main concerns: What is the driver power required for the compression process?To accomplish this, mechanical losses in the compression systems need to be discussed. Trends in efficiency should also be considered over time, such as off-design conditions as they are imposed by typical pipeline operations, or the impact of operating hours and associated degradation on the compressors. The compression equipment used for pipelines involves either reciprocating compressors or centrifugal compressors. Centrifugal compressors are driven by gas turbines, or by electricmotors. The gas turbines used are, in general,two-shaft engines and the electric motor drives use either variable speed motors, or variable speed gearboxes. Reciprocating compressors are either low speed integral units, which combine the gas engine and the compressor in one crank casing,or separable high-speed units. The latter units operate in the 750-1,200 rpm range (1,800 rpm for smaller units) and are generally driven by electric motors, or four-stroke gas engines.EfficiencyTo determine the isentropic efficiency of any compression process based on total enthalpies (h), total pressures (p), temperatures (T)and entropies (s) at suction and discharge of the compressor are measured, and the isentropic efficiency r then becomes: (Eq.1)and, with measuring the steady state mass flow m, the absorbed shaft power is: (Eq.2)considering the mechanical efficiency r.The theoretical (isentropic) power consumption (which is the lowest possible power consumption for an adiabatic system) follows from: (Eq.3)The flow into and out of a centrifugal compressor can be considered as steady state. Heat exchange with the environment is usually negligible. System boundaries for the efficiency calculations are usually the suction and discharge nozzles. It needs to be assured that the system boundaries envelope all internal leakage paths, in particular recirculation paths from balance piston or division wall leakages. The mechanical efficiency r)., describing the friction losses in bearings and seals, as well as windage losses, is typically between 98 and 99%.For reciprocating compressors, theoretical gas horsepower is also given by Eq. 3,given the suction and discharge pressure are upstream of the suction pulsation dampeners and downstream of the discharge pulsation dampeners. Reciprocating compressors, by their very nature, require manifold systems to control pulsations and provide isolation from neighboring units (both reciprocating and centrifugal), as well as from pipeline flow meters and yard piping and can be extensive in nature.The design of manifold systems for either slow speed or high speed units uses a combination of volumes, piping lengths and pressure drop elements to create pulsation (acoustic) filters.These manifold systems (filters) cause a pressure drop, and thus must be considered in efficiency calculations. Potentially, additional pressure deductions from the suction pressure would have to made to include the effects of residual pulsations. Like centrifugal compressors, heat transfer is usually neglected.For integral machines, mechanical efficiency is generally taken as 95%. For separable machines a 97% mechanical efficiency is often used. These numbers seem to be somewhat optimistic, given the fact that a number of sources state that reciprocating engines incur between 8-15% mechanical losses and reciprocating compressors between 6-12%(Ref 1: Kurz , R., K. Bun, 2007).Operating Conditions For a situation where a compressor operates in a system with pipe of the length Lu upstream and a pipe of the length Ld downstream, and further where the pressure at the beginning of the upstream pipe pu and the end of the downstream pipe pe are known and constant, we have a simple model of a compressor station operating in a pipeline system (Figure 1). Figure 1: Conceptual model of a pipeline segment (Ref. 2: Kurz, R., M. Lubomirsky.2006). For a given, constant flow capacity Qstd the pipeline will then impose a pressure ps at the suction and pd at the discharge side of the compressor. For a given pipeline, the head (Hs)-flow (Q) relationship at the compressor station can be approximated by(Eq.4)where C3 and C4 are constants (for a given pipeline geometry) describing the pressure at either ends of the pipeline, and the friction losses, respectively(Ref 2: Kurz, R., M. Lubomirsky, 2006). Among other issues, this means that for a compressor station within a pipeline system, the head for a required flow is prescribed by the pipeline system (Figure 2). In particular, this characteristic requires the capability for the compressors to allow a reduction in head with reduced flow, and vice versa, in a prescribed fashion. The pipeline will therefore not require a change in flow at constant head (or pressure ratio). Figure 2: Stafion Head-Flow relationship based on Eq. 4. In transient situations (for example during line packing), the operating conditions follow initially a constant power distribution, i.e. the head flow relationship follows:(Eq.5)and will asymptotically approach the steady state relationship (Ref 3: Ohanian, S., R.Kurz, 2002). Based on the requirements above, the compressor output must be controlled to match the system demand. This system demand is characterized by a strong relationship between system flow and system head or pressure ratio.Given the large variations in operating conditions experienced by pipeline compressors, an important question is how to adjust the compressor to the varying conditions, and, in particular, how does this influence the efficiency. Centrinagal compressors tend to have rather flat head vs. flow characteristic. This means that changes in pressure ratio have a significant effect on the actual flow through the machine (Ref 4:Kurz, R., 2004). For a centrifugal compressor operating at a constant speed, the head or pressure ratio is reduced with increasing flow. Controlling the flow through the compressor can be accomplished by varying the operating speed of the compressor This is the preferred method of controlling centrifugal compressors. Two shaft gas turbines and variable speed electric motors allow for speed variations over a wide range (usually from 40-50% to 100% of maximum speed or more).It should be noted, that the controlled value is usually not speed, but the speed is indirectly the result of balancing the power generated by the power turbine (which is controlled by the fuel flow into the gas turbine) and the absorbed power of the compressor. Virtually any centrifugal compressor installed in the past 15 years in pipeline service is driven by a variable speed driver, usually a two-shaft gas turbine. Older installations and installations in other than pipeline service sometimes use single-shaft gas turbines (which allow a speed variation from about 90-100% speed) and constant speed electric motors. In these installations, suction throttling or variable inlet guide vanes are used to Drovide means of control. Figure 3: Typical pipeline operating points plotted into a typical centrifugal compressor performance map. The operating envelope of a centrifugal compressor is limited by the maximum allowable speed, the minimum flow (surge flow),and the maximum flow (choke or stonewall)(Figure 3). Another limiting factor may be the available driver power. Only the minimum flow requires special attention, because it is defined by an aerodynamic stability limit of the compressor Crossing this limit to lower flows will cause a flow reversal in the compressor, which can damage the compressor. Modem control systems prevent this situation by automatically opening a recycle valve. For this reason, virtually all modern compressor installations use a recycle line with control valve that allows the increase of the flow through the compressor if it comes near the stability limit. The control systems constantly monitor the operating point of the compressor in relation to its surge line ,and automatically open or close the recycle valve if necessary. For most applications, the operating mode with an open, or partially open recycle valve is only used for start-up and shutdown, or for brief periods during upset operating conditions. Assuming the pipeline characteristic derived in Eq. 4, the compressor impellers will be selected to operate at or near its best efficiency for the entire range of head and flow conditions imposed by the pipeline. This is possible with a speed (N) controlled compressor, because the best efficiency points of a compressor are connected by a relationship that requires approximately (fan law equation): (Eq.6)For operating points that meet the above relationship, the absorbed gas power Pg is (due to the fact that the efficiency stays approximately constant): (Eq.7) As it is, this power-speed relationship allows the power turbine to operate at, or very close to its optimum speed for the entire range. The typical operating scenarios in pipelines therefore allow the compressor and the power turbine to operate at its best efliciency for most of the time. The gas producer of the gas turbine will, however, lose some thermal efficiency when operated in part load. Figure 3 shows a typical real world example: Pipeline operating points for different flow requirements are plotted into the performance map of the speed controlled centrifugal compressor used in the compressor station. Reciprocating compressors will automatically comply with the system pressure ratio demands, as long as no mechanical limits (rod load power)are exceeded. Changes in system suction or discharge pressure will simply cause the valves to open earlier or later. The head is lowered automatically because the valves see lower pipeline pressures on the discharge side and/or higher pipeline pressures on the suction side. Therefore, without additional measures, the flow would stay roughly the same except for the impact of changed volumetric efficiency which would increase, thus increasing the flow with reduced presstire ratio. The control challenge lies in the adjustment of the flow to the system demands. Without additional adjustments, the flow throughput of the compressor changes very little with changed pressure ratio. Historically, pipelines installed many small compressors and adjusted flow rate by changing the number of machines activated. This capacity and load could be fine-tuned by speed or by a number of small adjustments (load steps) made in the cylinder clearance of a single unit. As compressors have grown, the burden for capacity control has shifted to the individual compressors. Load control is a critical component to compressor operation. From a pipeline operation perspective, variation in station flow is required to meet pipeline delivery commitments, as well as implement company strategies for optimal operation (i.e., line packing, load anticipation).From a unit perspective, load control involves reducing unit flow (through unloaders or speed)to operate as close as possible to the design torque limit without overloading the compressor or driver The critical limits on any load map curve are rod load limits and HP/torque limits for any given station suction and discharge pressure. Gas control generally will establish the units within a station that must be operated to achieve pipeline flow targets. Local unit control will establish load step or speed requirements to limit rod loads or achieve torque control. The common methods of changing flow rate are to change speed, change clearance, or de-activate a cylinder-end (hold the suction valve open). Another method is an infinite-step unloader, which delays suction valve closure to reduce volumetric efficiency. Further, part of the flow can be recycled or the suction pressure can be throttled thus reducing the mass flow while keeping the volumetric flow into the compressor approximately constant. Control strategies for compressors should allow automation, and be adjusted easily during the operation of the compressor .In particular, strategies that require design modifications to the compressor (for example: re-wheeling of a centrifugal compressor, changing cylinder bore, or adding fixed clearances for a reciprocating compressor)are not considered here. It should be noted that with reciprocating compressors, a key control requirement is to not overload the driver or to exceed mechanical limits.OperationThe typical steady state pipeline operation will yield an efficiency behavior as outlined in Figure 4. This figure is the result of evaluating the compressor efficiency along a pipeline steady state operating characteristic. Both compressors would be sized to achieve their best efficiency at 100% flow, while allowing for 10% flow above the design flow. Different mechanical efficiencies have not been considered for this comparison.The reciprocating compressor efficiency is derived n-on valve efficiency measurements in Ref 5 (Null, M., W. Couch, 2003) with compression efficiency and losses due to pulsation attenuation devices added. The efficiencies are achievable with low speed compressors. High speed reciprocating compressors may be lower in efficiency.Figure 4: Compressor Efficiency at different flow rates based on operation along a steady state pipeline characteristic.Figure 4 shows the impact of the increased valve losses at lower pressure ratio and lower flow for reciprocating machines, while the efficiency of the centrifugal compressor stays more or less constant.ConclusionsEfficiency definitions and comparison between different types of compressors require close attention to the definition of the boundary conditions for which the efficiencies are defined as well as the operating scenario in which they are employed. The mechanical efficiency plays an important role when efficiency values are used to calculate power consumption. If these definitions are not considered, discussions of relative merits of different systems become inaccurate and misleading. REFERENCES1 Kurz . R. K. Burn. 2007. Efficiency Definition and Load Management for Reciprocating and Centrifugal Compressors, ASME Paper GT2OO7-27O81.2 Kurz. R., M. Lubomirsky, 2006. Asymttietric Solution for Compressor Station Spare Capacity.ASMt: Paper 2006-90069.3 Ohanian. S. R. Kurz. 2002, Series or Parallel Arrangement in a Two-Unit Compressor Station. Trans.ASME Jeng for GT and Power. Vol.124.4 Kurz. R. 2004. The Physies of Centrifugal Compressor Performance. Pipeline Simulation Interest Group. Palm Springs. CA.5 Noral, M. W. Couch. 2003, Performance and Endurance Tests of Six Mainline Compressor Valves in Natural Gas Compression Service. Gas Machinery Conference. Salt Lake City. UT.中文原文离心式和往复式压缩机的工作效率特性 Rainer Kurz , Bernhard Winkelmann , and Saeid Mokhatab往复式压缩机和离心式压缩机具有不同的工作特性,而且关于效率的定义也不同。本文提供了一个公平的比较准则,得到了对于两种类型机器普遍适用的效率定义。这个比较基于用户最感兴趣的要求提出的。此外,对于管道的工作环境影响和在不同负载水平的影响给出了评估。乍一看,计算任何类型的压缩效率看似是很简单的:比较理想压缩过程和实际压缩过程的工作效率。难点在于正确定义适当的系统边界,包括与之相关的压缩过程的损失。除非这些边界是恰好定义的,否则离心式和往复式压缩机的比较就变得有缺陷了。我们也需要承认,效率的定义,甚至是在评估公平的情况下,仍不能完全回应操作员的主要关心问题:压缩过程所需的驱动力量是什么?要做到这一点,就需要讨论在压缩过程中的机械损失。随着时间的推移效率趋势也应被考虑,如非设计条件,它们是由专业的流水线规定,或者是受压缩机的工作时间和自身退化的影响。管道使用的压缩设备涉及到往复式和离心式压缩机。离心式压缩机用燃气轮机或者是电动马达来驱动。所用的燃气轮机,总的来说,是两轴发动机,电动马达使用的是变速马达或者变速齿轮箱。往复压缩机是低速整体单位或者是可分的“高速”单位,其中低速整体单位是燃气发动机和压缩机在一个曲柄套管内。后者单位的运行在750-1,200rpm范围内(1,800rpm是更小的单位)并且通常都是由电动马达或者四冲程燃气发动机来驱动。效率要确定任何压缩过程的等熵效率,就要基于测量的压缩机吸入和排出的总焓(h),总压力(p),温度(T)和熵(s),于是等熵效率变为: (Eq.1)并且加上测量的稳态质量流m,吸收轴功率为: (Eq.2)考虑机械效率。理论(熵)功耗(这是绝热系统可能出现的最低功耗)如下: (Eq.3)流入和流出离心式压缩机的流量可以视为“稳态”。环境的热交换通常可以忽略。系统边界的效率计算通常是用吸入和排出的喷嘴。需要确定的是,系统边界要包含所有内部泄露途径,尤其是从平衡活塞式或分裂墙渗漏的循环路径。机械效率,在描述轴承和密封件的摩擦损失以及风阻损失时可以达到98%和99%。对于往复式压缩机,理论的气体马力也是由Eq.3给出的,鉴于吸力缓冲器上游和排力缓冲器下游的吸气和排气压力脉动。往复压缩机就其性质而言,从临近单位需要多方面的系统来控制脉动和提供隔离(包括往复式和离心式),以及可以自然存在的来自管线的管流量和面积管道。对于任何一个低速或高速单位的歧管
收藏