Acknowledge the important role of Engineering Thermodynamics in practical project application.
了解工程热力学在工程应用中的重要作用。
Heat Transfer, Fluid dynamics, Engineering Thermodynamics, Mechanics of Materials, General Chemistry.
传热学,流体力学,工程热力学,材料力学,普通化学。
In this course, we will review some basic concepts and basic laws of thermodynamics in chapter one, which is connected with engineering thermodynamics.
本课程第一章回顾了热力学的基本概念和基本定律,与本科工程热力学课程相衔接。
Based on the energy conversation equation of chemical engineering thermodynamics, two computation methods of explosion temperature and pressure of gas explosion in vessels were built.
根据化工热力学能量守恒方程,推导出了两种容器内可燃气体爆炸温度和压力的计算方法。
Based on the theory of aerodynamics, engineering thermodynamics, the mechanical model for air spring vertical dynamical characteristics analysis is built and proved to be correct by test.
应用空气动力学、工程热力学理论,推导空气弹簧垂向动态特性分析的数学模型,经过试验验证模型的正确性。
Academic Main Courses: Chemical Engineering Transfer, Chemical Engineering Thermodynamics, Physical mathematics Equation, Probability and Statistics, Enhanced Heat Transfer, Mass Transfer.
在校期间所学课程有:化工传递、化工热力学、数理方程、数理统计、强化传热、传质学等,成绩优秀。
Volumetric expansion coefficient and compressibility of water and steam are important parameters usually applied in the reactor thermal hydraulic, heat transfer and engineering thermodynamics.
水和蒸汽的体膨胀系数和压缩率是反应堆热工水力、传热学和工程热力学中常用的参数之一。
The prerequisites for this course are the undergraduate courses in thermodynamics and fluid mechanics, specifically Thermal Fluids Engineering I and Thermal Fluids Engineering II or their equivalents.
本课程之先修科目有大学部之热力学及流体力学,即热流工程i及热流工程II或者与其相当的科目。
Chemical Engineering, chemical thermodynamics and physical chemistry and other basic courses, and achieved excellent results.
化工原理,化工热力学和物理化学等基础课程,并取得优异的成绩。
Engineering is based principally on physics, chemistry, and mathematics and their extensions into materials science, soild and fluid mechanics, thermodynamics, and systems analysis.
物理学、化学、数学,以及这些学科扩展出的物质科学、固体物理、流体力学、热力学和系统分析等等学科是工程学的重要基础。
Pinch analysis was applied to diagnosis and optimization of energy utilization of process systems based on the principles of thermodynamics and system engineering.
把热力学与系统工程的方法相结合,进一步将“夹点分析”应用于化工过程系统的用能诊断及调优。
Biochemical processes, thermodynamics, and kinetics are used in the application of engineering principles to analyze, design, and develop processes using biocatalysts.
应用生化过程、热力学和动力学等的工程学原理,用以分析、设计并改进利用生物催化剂的生产过程。
The design of engineering works requires the application of design theory from many fields (e. g., hydraulics, thermodynamics, nuclear physics).
工程设计的工作需要应用许多方面的设计理论(如水力学、热力学和核物理等)。
The focus will be on modeling and engineering approximation schemes that describe the thermodynamics and kinetics of electrochemical systems.
焦点将在描述电化学的系统的热力学和动力学的模型化和工程接近计画。
The focus will be on modeling and engineering approximation schemes that describe the thermodynamics and kinetics of electrochemical systems.
焦点将在描述电化学的系统的热力学和动力学的模型化和工程接近计画。
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