动力工程专业英语
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Chapter 1 Introduction to Thermal Science
第一章 热科学基础
Acoustic flow meter 声波流量计 ]绝热的 Adiabatic [ Aerodynamics 空气动力学 Affiliation 联系 Airfoil 机翼,螺旋桨 Alternative 替代燃料 Anemometer 风速计 Corrugated fin 波状散热片 Cross product 矢量积 Denominator 分母 Developed flow 充分发展流 Diffusion 扩散 Doppler effect 多普勒效应 Double-pipe heat exchanger 套管式换热 器 Angular speed 角速度 Dry saturated vapor 干饱和蒸汽 Area density 表面密度 Electrode 电极 Baffle 挡板 Electrolyte 电解,电解液 Bifurcation 分形 Electrostatic 静电的 Blackbody 黑体 Emissivity 发射率 Blade 浆叶,叶片 Equilibrium 平衡 Boiler 锅炉 Fluid mechanics 流体力学 Boundary layer 边界层 Forced convection 强制对流 Carnot Cycle 卡诺循环 Free convection 自然对流 Cartesian coordinates 笛卡尔坐标系 Friction loss 摩擦损失 Celsius Degree 摄氏度 Glass ceramic 微晶玻璃,玻璃陶瓷 Compact heat exchanger 紧凑式换热器 Heat engine 热机 Composition 成分,合成物 Heat pump 热泵 Compressed liquid 压缩液体 Hydrofoil 水翼 Compressibility 可压缩性,压缩率 Hypersonic speed 高超音速 Condensation 凝结 Infinitesimal 无穷小的 Condenser 冷凝器 Inflating/deflating 充气/压缩 Conduction 导热 Internal combustion engine 内燃机 Control volume 控制体 Isentropic 等熵的 Convection 对流 Isobaric 等压的 Coriolis-accelaration flowmeter 科 氏 加 Isolated system 孤立体系的 速流量计 Isometric 等容的 Rough-wall tube 粗糙管 Isothermal 等温的 Saturation 饱和 Kinematic viscosity 运动黏度 Shear stress 剪切力、切应力 Laminar 层流 Shell-and-tube heat exchanger 管壳式换 热器 Manuscript 手稿,原稿 Specific volume 比容 Moisture 湿度,水分 Steady 稳态的,定常的 Molecule (化学)分子 Stifling engine 斯特林机 Molten polymer 熔融聚合物 Strain rate 变形速度,应变率
2
热力学是一门研究能量储存、转换及传递的科学。能量以内能(与温度有关)、动能 (由物体运动引起)、 势能(由高度引起)和化学能(与化学组成相关)的形式储存。 不同 形式的能量可以相互转化,而且能量在边界上可以以热和功的形式进行传递。
In thermodynamics, we will derive equations that relate the transformations and transfers of energy to properties such as temperature, pressure and density. Substances and their properties, thus, become very important in thermodynamics. Many of our equations will be based on experimental observations that have been organized into mathematical statements or laws, the first and second laws of thermodynamics are most widely used. 在热力学中,我们将推导有关能量转化和传递与物性参数,如温度、 压强及 密度等关系间的方程。因此,在热力学中,物质及其性质变得非常重要。许多热 力学方程都是建立在实验观察的基础之上,而且这些实验观察的结果已被整理 成数学表达式或定律的形式。其中,热力学第一定律和第二定律应用最为广泛。 1.1.1 1.1.1 Thermodynamic system and control volume 热力系 统 和控制体
系统之外的所有物质和空间统称外界 或环境。热力学主要研究系统与外界或系统与系 统之间的相互作用。 系统通过在边界上进行能量传递,从而与外界进行相互作用,但在边界 上没有质量交换。当系统与外界间没有能量交换时,这样的系统称为孤立系统。
In many cases, an analysis is simplified if attention is focused on a particular volume in space into which, or from which, a substance flows. Such a volume is a control volume. A pump, a turbine, and an inflating or deflating balloon are examples of control volume. The surface that completely surrounds the control volume is called a control surface.
A thermodynamic system is a fixed quantity of matter contained within some enclosure. The surface is usually an obvious one (like that surrounding the gas in the cylinder). However, it may be an imagined boundary (like the deformass as it flows through a pump).
热力系统是一包围在某一封闭边界内的具有固定质量的物质。系统边界通常是比较明 显的(如气缸内气体的固定边界)。 然而,系统边界也可以是假想的(如一定质量的流体流 经泵时不断变形的边界)。
All matter and space external to a system is collectively called its surroundings. Thermodynamics is concerned with the interaction of a system and its surroundings, or one system interacting with another. A system interacts with its surroundings by transferring energy across its boundary. No material crosses the boundary of a system. If the system does not exchange energy with the surroundings, it is an isolated system.
Streamline 流线 Strut 支撑,支柱 Subcooled liquid 过冷液体 Superheated vapor 过热蒸汽 Surrounding 环境,外界 Thermal conductivity 热传导率 Thermal efficiency 热效率 Thermodynamics 热力学 Torsional 扭力的,扭转的 Trailing edge 机翼后缘、尾缘 Transmitter 传送装置、发送器 Turbine meter 涡轮流量计 Turbulent 湍流的 Ultrosonic 超声波的 Uniform flow 均匀刘 Vacuum 真空 View factor 角系数 Viscous 黏性的 Cortex shedding 漩涡脱落 Water faucet 水龙头,水嘴 Abbreviation NPSH 汽蚀余量 NTU 传热单元数 Nu 努谢尔特数 PE 势能 Pr 普朗特数 Ra 瑞利数 Re 雷诺数 Sc 施密特数 St 斯坦顿数 , 斯特劳哈数 We 韦伯数
1
Muti-disciplinary 多学科的 Newtonian Fluid 牛顿流体 Nominal temperature gradient 法向温度 梯度 Numerator (数学)分子 Parallel flow 平行流动,并流 Pathline 迹线 Phase change 相变 Plane flow 平面流,二元流 Plate and flame heat exchanger 板式换热器 Polymer solution 胶浆 Proof 校样 Propeller 螺旋桨,推进器 Pump 泵 Qulity 干度 Qusi-equilibrium 准平衡、准静态 Radiation 辐射 Rankin Cycle 朗肯循环 Regenerative heat exchanger 蓄热/再生式换热器 Reservoir 水库,蓄水池 Reversible 可逆的 Rotameter 转子流量计 Bi Biot number 比澳数 CFD 计算流体力学 CHF 临界热流量 COP 制冷系数 Eu 欧拉数 Fo 富立叶数 Fr 弗劳德数 Gr 格拉晓夫数 KE 动能 LMTD 对数平均温差
在许多情况下,当我们只关心空间中有物质流进或流出的某个特定体积时,分析可以
3
得到简化。 这样的特定体积称为控制体。 例如泵、 透平、 充气或放气的气球都是控制体的例子。 包含控制体的表面称为控制表面。
Thus, we must choose, in a particular problem, whether a system is to be considered or whether a control volume is more useful. If there is mass flux across a boundary, then a control volume is required; otherwise, a system is identified.
1.1 Fundamental of Engineering Thermodynamics
1.1 工程热力学基础
Thermodynamics is a science in which the storage, transformation and transfer of energy are studied. Energy is stored as internal energy (associated with temperature), kinetic energy (du to motion), potential energy (due to elevation) and chemical energy (due to chemical composition); it is transformed from one of these forms to another; and it is transferred across a boundary as either heat or work.
第一章 热科学基础
Acoustic flow meter 声波流量计 ]绝热的 Adiabatic [ Aerodynamics 空气动力学 Affiliation 联系 Airfoil 机翼,螺旋桨 Alternative 替代燃料 Anemometer 风速计 Corrugated fin 波状散热片 Cross product 矢量积 Denominator 分母 Developed flow 充分发展流 Diffusion 扩散 Doppler effect 多普勒效应 Double-pipe heat exchanger 套管式换热 器 Angular speed 角速度 Dry saturated vapor 干饱和蒸汽 Area density 表面密度 Electrode 电极 Baffle 挡板 Electrolyte 电解,电解液 Bifurcation 分形 Electrostatic 静电的 Blackbody 黑体 Emissivity 发射率 Blade 浆叶,叶片 Equilibrium 平衡 Boiler 锅炉 Fluid mechanics 流体力学 Boundary layer 边界层 Forced convection 强制对流 Carnot Cycle 卡诺循环 Free convection 自然对流 Cartesian coordinates 笛卡尔坐标系 Friction loss 摩擦损失 Celsius Degree 摄氏度 Glass ceramic 微晶玻璃,玻璃陶瓷 Compact heat exchanger 紧凑式换热器 Heat engine 热机 Composition 成分,合成物 Heat pump 热泵 Compressed liquid 压缩液体 Hydrofoil 水翼 Compressibility 可压缩性,压缩率 Hypersonic speed 高超音速 Condensation 凝结 Infinitesimal 无穷小的 Condenser 冷凝器 Inflating/deflating 充气/压缩 Conduction 导热 Internal combustion engine 内燃机 Control volume 控制体 Isentropic 等熵的 Convection 对流 Isobaric 等压的 Coriolis-accelaration flowmeter 科 氏 加 Isolated system 孤立体系的 速流量计 Isometric 等容的 Rough-wall tube 粗糙管 Isothermal 等温的 Saturation 饱和 Kinematic viscosity 运动黏度 Shear stress 剪切力、切应力 Laminar 层流 Shell-and-tube heat exchanger 管壳式换 热器 Manuscript 手稿,原稿 Specific volume 比容 Moisture 湿度,水分 Steady 稳态的,定常的 Molecule (化学)分子 Stifling engine 斯特林机 Molten polymer 熔融聚合物 Strain rate 变形速度,应变率
2
热力学是一门研究能量储存、转换及传递的科学。能量以内能(与温度有关)、动能 (由物体运动引起)、 势能(由高度引起)和化学能(与化学组成相关)的形式储存。 不同 形式的能量可以相互转化,而且能量在边界上可以以热和功的形式进行传递。
In thermodynamics, we will derive equations that relate the transformations and transfers of energy to properties such as temperature, pressure and density. Substances and their properties, thus, become very important in thermodynamics. Many of our equations will be based on experimental observations that have been organized into mathematical statements or laws, the first and second laws of thermodynamics are most widely used. 在热力学中,我们将推导有关能量转化和传递与物性参数,如温度、 压强及 密度等关系间的方程。因此,在热力学中,物质及其性质变得非常重要。许多热 力学方程都是建立在实验观察的基础之上,而且这些实验观察的结果已被整理 成数学表达式或定律的形式。其中,热力学第一定律和第二定律应用最为广泛。 1.1.1 1.1.1 Thermodynamic system and control volume 热力系 统 和控制体
系统之外的所有物质和空间统称外界 或环境。热力学主要研究系统与外界或系统与系 统之间的相互作用。 系统通过在边界上进行能量传递,从而与外界进行相互作用,但在边界 上没有质量交换。当系统与外界间没有能量交换时,这样的系统称为孤立系统。
In many cases, an analysis is simplified if attention is focused on a particular volume in space into which, or from which, a substance flows. Such a volume is a control volume. A pump, a turbine, and an inflating or deflating balloon are examples of control volume. The surface that completely surrounds the control volume is called a control surface.
A thermodynamic system is a fixed quantity of matter contained within some enclosure. The surface is usually an obvious one (like that surrounding the gas in the cylinder). However, it may be an imagined boundary (like the deformass as it flows through a pump).
热力系统是一包围在某一封闭边界内的具有固定质量的物质。系统边界通常是比较明 显的(如气缸内气体的固定边界)。 然而,系统边界也可以是假想的(如一定质量的流体流 经泵时不断变形的边界)。
All matter and space external to a system is collectively called its surroundings. Thermodynamics is concerned with the interaction of a system and its surroundings, or one system interacting with another. A system interacts with its surroundings by transferring energy across its boundary. No material crosses the boundary of a system. If the system does not exchange energy with the surroundings, it is an isolated system.
Streamline 流线 Strut 支撑,支柱 Subcooled liquid 过冷液体 Superheated vapor 过热蒸汽 Surrounding 环境,外界 Thermal conductivity 热传导率 Thermal efficiency 热效率 Thermodynamics 热力学 Torsional 扭力的,扭转的 Trailing edge 机翼后缘、尾缘 Transmitter 传送装置、发送器 Turbine meter 涡轮流量计 Turbulent 湍流的 Ultrosonic 超声波的 Uniform flow 均匀刘 Vacuum 真空 View factor 角系数 Viscous 黏性的 Cortex shedding 漩涡脱落 Water faucet 水龙头,水嘴 Abbreviation NPSH 汽蚀余量 NTU 传热单元数 Nu 努谢尔特数 PE 势能 Pr 普朗特数 Ra 瑞利数 Re 雷诺数 Sc 施密特数 St 斯坦顿数 , 斯特劳哈数 We 韦伯数
1
Muti-disciplinary 多学科的 Newtonian Fluid 牛顿流体 Nominal temperature gradient 法向温度 梯度 Numerator (数学)分子 Parallel flow 平行流动,并流 Pathline 迹线 Phase change 相变 Plane flow 平面流,二元流 Plate and flame heat exchanger 板式换热器 Polymer solution 胶浆 Proof 校样 Propeller 螺旋桨,推进器 Pump 泵 Qulity 干度 Qusi-equilibrium 准平衡、准静态 Radiation 辐射 Rankin Cycle 朗肯循环 Regenerative heat exchanger 蓄热/再生式换热器 Reservoir 水库,蓄水池 Reversible 可逆的 Rotameter 转子流量计 Bi Biot number 比澳数 CFD 计算流体力学 CHF 临界热流量 COP 制冷系数 Eu 欧拉数 Fo 富立叶数 Fr 弗劳德数 Gr 格拉晓夫数 KE 动能 LMTD 对数平均温差
在许多情况下,当我们只关心空间中有物质流进或流出的某个特定体积时,分析可以
3
得到简化。 这样的特定体积称为控制体。 例如泵、 透平、 充气或放气的气球都是控制体的例子。 包含控制体的表面称为控制表面。
Thus, we must choose, in a particular problem, whether a system is to be considered or whether a control volume is more useful. If there is mass flux across a boundary, then a control volume is required; otherwise, a system is identified.
1.1 Fundamental of Engineering Thermodynamics
1.1 工程热力学基础
Thermodynamics is a science in which the storage, transformation and transfer of energy are studied. Energy is stored as internal energy (associated with temperature), kinetic energy (du to motion), potential energy (due to elevation) and chemical energy (due to chemical composition); it is transformed from one of these forms to another; and it is transferred across a boundary as either heat or work.