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Conservation of Energy in Control Volume01:14

Conservation of Energy in Control Volume

837
Consider a turbine operating under steady-flow conditions. The control volume is drawn around the turbine, with fluid entering at one point and exiting at another. The turbine extracts energy from the fluid, which performs mechanical work (shaft work).
For steady flow systems, the time derivative of the stored energy becomes zero since there is no energy accumulation within the control volume. This simplifies the energy equation to:
837
Path Between Thermodynamics States01:21

Path Between Thermodynamics States

3.2K
Consider the two thermodynamic processes involving an ideal gas that are represented by paths AC and ABC in Figure 1:
3.2K
Energy Diagrams - I01:14

Energy Diagrams - I

5.0K
The dynamics of a mechanical system can be easily understood by interpreting a potential energy diagram. Since energy is a scalar quantity, the interpretation of the dynamics of the system becomes even simpler.
Take the example of a skater on a parabolic ramp. The potential energy at different points along the ramp will be proportional to the height of the ramp, which varies quadratically with the horizontal position on the ramp. As the skater moves down the ramp from the highest position,...
5.0K
The Carnot Cycle01:30

The Carnot Cycle

2.9K
Converting work to heat is an irreversible process, and the purpose of a heat engine is to reverse the effect partially. Heat engines aim to increase the efficiency of the reversal, that is, maximize the work retrieved from heat. If the efficiency of a heat engine were 100%, it would imply reversing the process completely without introducing any other effect. Thus, it would violate the second law of thermodynamics.
What could be the theoretical limit to the efficiency of a heat engine? The...
2.9K
Energy Conservation and Bernoulli's Equation01:16

Energy Conservation and Bernoulli's Equation

8.9K
Applying the conservation of energy principle or the work-energy theorem to an incompressible, inviscid fluid in laminar, steady, irrotational flow leads to Bernoulli's equation. It states that the sum of the fluid pressure, potential, and kinetic energy per unit volume is constant along a streamline.
All the terms in the equation have the dimension of energy per unit volume. The kinetic energy per unit volume is called the kinetic energy density, and the potential energy per unit volume is...
8.9K
Conservation of Energy: Application01:12

Conservation of Energy: Application

6.9K
When solving problems using the energy conservation law, the object (system) to be studied should first be identified. Often, in applications of energy conservation, we study more than one body at the same time. Second, identify all forces acting on the object and determine whether each force doing work is conservative. If a non-conservative force (e.g., friction) is doing work, then mechanical energy is not conserved. The system must then be analyzed with non-conservative work. Third, for...
6.9K

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相关实验视频

Updated: Jul 2, 2025

Author Spotlight: Simulation and Analysis of the Temperature Rise of Ring Main Unit Equipment
04:35

Author Spotlight: Simulation and Analysis of the Temperature Rise of Ring Main Unit Equipment

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对于一些线性稳定状态的能量转换定理.

L A Arias-Hernandez1, G Valencia-Ortega2, C R Martinez-Garcia3

  • 1Departamento de Física, Escuela Superior de Física y Matemáticas, Instituto Politécnico Nacional, Ciudad de México 07738, México.

Physical review. E
|February 17, 2024
PubMed
概括

本研究探讨了同热系统的能量转换定理,揭示了设计和操作模式之间的权衡. 它在各种操作模式中建立了输出功率,效率和消耗功率的能量层次.

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Uncoupling Coriolis Force and Rotating Buoyancy Effects on Full-Field Heat Transfer Properties of a Rotating Channel
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A Rapid Method for Modeling a Variable Cycle Engine
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相关实验视频

Last Updated: Jul 2, 2025

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Author Spotlight: Simulation and Analysis of the Temperature Rise of Ring Main Unit Equipment

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Uncoupling Coriolis Force and Rotating Buoyancy Effects on Full-Field Heat Transfer Properties of a Rotating Channel
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科学领域:

  • 热力学是一种热力学.
  • 能源转换 能源转换
  • 非平衡系统 非平衡系统

背景情况:

  • 真正的能量转换器不可避免地产生,导致系统的能量退化.
  • 设计用于最小的转换器产生零输出功率和效率.
  • 非平衡热力学为分析退化系统中的产生提供了一个框架.

研究的目的:

  • 为 (2x2) 线性同热能转换器建立能量转换定理,类似于Prigogine的定理.
  • 揭示转换器设计和各种操作模式之间的权衡.
  • 调查驱动热力学约束的客观功能的稳定性.

主要方法:

  • 为等热系统制定了具有受约束力的能量转换定理.
  • 使用双网电路作为实验模型.
  • 在多个操作模式中分析了系统行为:最大输出功率 (MPO),最大有效功率 (MPη),最大欧米茄功能 (MΩ),最大生态功能 (MEF),最大效率 (Mη) 和最小消散功能 (mdf).

主要成果:

  • 使用电路模型证明了已建立的能量转换定理的有效性.
  • 揭示了输出功率,效率和散射功能的明显能量层次.
  • 展示了与热力学约束相关的客观功能的稳定性.

结论:

  • 开发的定理为优化能量转换器设计和操作提供了洞察力.
  • 了解能量层次对于平衡功率和效率等性能指标至关重要.
  • 该研究为分析复杂的能量转换过程提供了理论和实验基础.