Heat transfer technology of regenerator was analyzed in both heat transfer fluid and filling particles.
对回热器的强化换热技术从填充颗粒,换热流体两个方面进行了分析介绍。
In thermoacoustic system, the oscillating heat transfer in regenerator is along the axis direction of the stack and in heat exchanger it is along the radial direction of the tube.
在热声发动机系统中,回热器的振荡换热是沿流体通道的轴向,而加热器振荡换热主要是沿流体通道径向。
The computations show that with the increase of specific surface area, the regenerative energy by regenerator increases, so does recover rate of heat amount.
计算表明,增加比表面积,可以提高蓄热体的蓄热能力并提高余热回收率。
A thermoacoustic system with double acoustic drivers was constructed, which was composed of double speakers, a resonator, regenerator distributed in resonator and heat exchanger.
搭建了一套双声源驱动热声热机实验系统,该系统包括双扬声器、谐振管、置于谐振管内的回热器和换热器等元件。
The heat recovery rate, optimal switching time and pressure drop of honeycomb regenerator used in the high temperature air combustion system were investigated.
实验研究了高温空气燃烧系统使用的蜂巢蓄热体热回收率、最佳换向时间、流动阻力等性能参数及其随几何尺寸的变化规律;
The optimal performance can be obtained by optimizing the distribution of heat conductances or heat transfer surface areas among the two heat exchangers and the regenerator.
通过优化两个换热器和回热器之间的热导率分配或传热面积分配可得循环最优性能。
Cooling coils are introduced into the regenerator to control the temperature and remove the excess heat.
在再生器中放进冷却盘管能控制温度,也能除去过多的热量。
The design method of regenerator temperature change and switching period is studied on the basis of the exact solution of heat transfer between gas and solid phases in a honeycomb regenerator.
基于蜂窝蓄热体气-固传热精确解,研究蓄热体温度变化和切换周期设计方法。
At these temperatures, solid materials have lower values for specific heat, so the regenerator must be made out of unexpected materials, such as cotton.
在这些温度下,固体材料有较低的值比热,所以再生必须作出了意想不到的材料,如棉花。
This paper analyzed the heat exchange between ceramic honeycomb regenerator and gas, and established a heat transfer process mathematical model for ceramic honeycomb regenerator.
分析了高风温燃烧系统中陶瓷蜂窝蓄热体和气体间的热量交换,建立了陶瓷蜂窝蓄热体传热过程数学模型。
The static conduction, shuttle and radiation heat losses, as well as regenerator inefficiency have been considered.
计算中主要考虑了导热损失、穿梭损失、辐射损失以及回热损失。
The transmission and conversion process of the heat and momentum in the regenerator is very complex. It is a problem which relates to heat transfer, hydrodynamics and thermodynamics.
交变流动蓄冷器内部热量和动量的传输及转换过程是传热学、流体力学和热力学耦合在一起的复杂问题。
The transmission and conversion process of the heat and momentum in the regenerator is very complex. It is a problem which relates to heat transfer, hydrodynamics and thermodynamics.
交变流动蓄冷器内部热量和动量的传输及转换过程是传热学、流体力学和热力学耦合在一起的复杂问题。
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