The spatial distribution of the flux density is investigated by the CCD method and calibrated by heat flow meter.
采用CCD法得到了能流密度的相对分布并用热流计标定出能流密度分布。
Heat transfer model and energy equations for porous plaque have been established, temperature distribution and variation of radiative heat flux are also found.
建立了泡沫多孔板的传热模型和能量方程,同时求得了板内烟气温度分布及辐射热流强度变化。
Change of heat flux and temperature distribution along furnace height with varying furnace conditions can be reflected in the model.
此模型能够反映出沿炉膛高度方向热流和温度分布随炉内工况变化。
The distribution of some field parameters such as the flux, the velocity, and the heat-transfer coefficient computed by the programming provided required conditions for cooling simulation.
最后通过程序实现计算出冷却水的流量场、速度场、换热系数场等的分布,为玻壳模具温度场的数值模拟提供了必需的边界条件。
The distribution of radiative heat flux to the combustor wall has been obtained by.
通过计算,获得了燃烧室壁面的辐射热流分布。
The wall heat flux distribution, two-phase flow field, temperature field and pulverized coal particles trajectory in furnace are described according to the calculation results.
根据数值模拟的结果,描绘出炉膛内的壁面热负荷分布、两相流场、温度场、煤粉颗粒轨迹等。
The heat flux distribution is provided at the asymmetric side of the body, wing and the vertical fin.
试验给出机身对称面、翼前缘、立尾前缘等处的热流率分布。
It was found that temperature and heat flux distribution of interface were affected remarkably by the interface length, the thickness of fireproof fibers and the temperature of gasifier.
结果表明,托架长度、耐火纤维厚度、炉内温度是影响托架温度和热流密度分布的主要因素。
Critical heat flux for axial non-uniform heat flux distribution in rectangle narrow channel was studied in this report.
对矩形窄缝通道轴向非均匀加热临界热流密度进行了研究。
The calculation of the model reveals the distribution variation of flue gas concentration and heat flux density within the furnace.
模型计算揭示烟气温度和热流密度在炉膛内的分布变化。
We aim at the establishment of one-dimensional physical and math model in the multiplayer walls. Heat flux and temperature distribution expression has been reduced and analyzed.
建立了室外空气温度发生周期性变化情况下的复合墙体一维非稳态传热物理模型及数学模型,推导出复合墙体温度分布及热流密度分布表达式。
Regarding ball - cone-column model, then the forehead cone partial heat flux distribution is calculated emphatically.
对于球锥柱模型,则着重计算头部锥体部分的热流加热率。
To obtain more uniform distribution of temperature and heat flux could raises supply water temperature or reduces temperature difference between supply and return water;
为了得到更均匀的温度及热流密度分布,应适当提高供水温度或降低供回水温差;
To obtain more uniform distribution of temperature and heat flux could raises supply water temperature or reduces temperature difference between supply and return water;
为了得到更均匀的温度及热流密度分布,应适当提高供水温度或降低供回水温差;
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