本文分析了集热管内气体压强对于气体导热的影响。
The influence of pressure in glass collector tubes on gas conduction has been analysed.
这是一种用来测量气体压强(在体积恒定下)的装置。
It is a device used to measure the pressure of a fixed volume of gas.
在这一区域内,阳极位降、阳极位降区厚度主要由放电电流和气体压强所决定。
In this region, its thickness and potential fall are mainly determined by discharge current and gas pressure.
模拟计算结果表明,平行平板间滑移流动的气体压强分布曲线是上凸的下降抛物曲线。
Computational results showed that pressure distribution curve in parallel plates microchannel was convex decreasing parabolic curve.
本文从球形容器中理想气体入手,用一种简单易懂且不失一般性的方法,推导出理想气体压强公式。
A concise derivation of the pressure formula of ideal gases is given by considering the gas molecules moving within spherical container.
在较大分子的气体(如SF_6)中,正、负电晕起始电压有明显差别,而且随着气体压强增加而增大。
The results show that in SF6 there is obvious difference between the positive and negative onset voltage and the difference is increased by an increase of gas pressure.
这就导致了苏联火箭可以通过加装一个预热器,来增加气体压强。 着在美国科学家看来是个不可能的事情。
This resulted in the Soviets being able to increase gas pressure through a preheater something american rocket scientists thought was impossible.
采用脉冲激光烧蚀技术在氩气环境下制备了纳米硅薄膜,研究了环境气体压强对纳米硅薄膜表面形貌的影响。
In argon (ar) gas, nanocrystalline silicon films are prepared by pulsed laser ablation. The influence of ambient pressure on surface morphology of nanocrystalline silicon film is studied.
考虑到实际气体分子之间的相互作用,利用正则分布,按照气体压强的统计解释,得到了实际气体的压强方程。
Considering the interaction of practical gas, using the canonical distribution and statistical interpretation of gas pressure, this paper derives a pressure formula of practical gas directly.
起旋室通气井通风系由旋流洞内表面轴向水流“挟带”空气而致空腔内气体压强减小进入,模型存在缩尺效应。
Ventilation of starting rotation device ventilation pipe is from Axial flow of swirl hole inner surface takes air leads to vacuum cavity, model existence of scale effect.
探讨了等离子体处理时间、放电功率、气体压强及接枝单体浓度、接枝反应时间、温度等各因素对接枝率的影响规律。
The influences of the treating time, power, treating pressure of plasma, concentration of monomer, reaction temperature and time on the grafting rate are discussed.
给出了肋片的厚度、长度、气隙宽度、外壳壁厚与导通热导之间的关系曲线以及气体压强、外壳厚度与关断热导之间的关系曲线。
The relationships between thickness of the fin, length of the fin, gap clearance between fins and on-inductance are given. The off-inductances as functions of gas pressure, thickness of exterior...
应用两种形式的励磁线圈,实测了五种型号的真空灭弧室内气体压强与磁控放电离子电流的关系曲线,并对试验结果进行了理论分。
Two types of exciting coils have been used to obtain the relationship of the internal pressures and the ionic currents of magnetron discharge for 5 types of vacuum interrupter.
如果你想让更多的气体通过节流阀,应该使一边的压强,大于另一边,是吗?所以这就是,时间尺度发挥作用的地方。
You've got to put more pressure on one side than the other if you want to push that gas through the throttle, right? So this is where the time scale issue comes into play.
如果我位于这条线以下的,某个位置,比如这里,给定的压强,给定的气体组分,很好。
If I'm sitting below the line here somewhere, so I'm sitting here. Some composition in the gas phase, a certain pressure.
压强,低的压强下我只有纯气体。
所以你需要很大的压强,或者说大量的惰性气体,才能使蒸汽压发生很小的改变。
So it takes a lot of pressure on top, a lot of extra inert gas to really make much of a difference.
调节温度和混合气体的压强,模拟海平面以上各种高度的大气状态。
They adjust the temperature and pressure of the mix to mimic conditions at various heights above sea level.
如果它发生了变化,当然在等体条件下,如果气体的总量,发生了变化,压强也会发生变化。
If that changes, of course you know that the pressure in there is going to change at constant volume if the amount of gas in there is changing.
我们一开始有四个变量:,温度,压强,某个组分在液体中的比例,和它在气体中的比例。
We started out with four variables; the temperature, the pressure, and the components in the composition in the liquid phase and the composition in the gas phase.
没有气体,我们要降低压强。
如果这是一个理想气体系统,我们知道压强等于nRT除以体积。
Now, if this is an ideal gas, we know that pressure is equal to nRT over volume.
在我们举的这个例子中,外界压强不变,气体体积改变。
This is an example where the external pressure here is kept fixed as the volume changes, but it doesn't have to be kept fixed.
假设有1摩尔气体,具有一点的压强p,体积,温度,我们将让它,经过两条不同的路径。
So we're going to start with a mole of gas, V at some pressure, some volume, T temperature and some mole so V, doing it per mole, and we're going to do two paths here.
现在让压强趋于,现在测量气体的压强,和摩尔体积。
So, you do this measurement, you measure with the gas, you measure the pressure and the molar volume.
这种光谱调制传感器系统能够测量多种物理参数,如压强、温度、气体密度及多种化学成份。
The spectral modulation sensor system can detect and measure various physical parameters such as pressure, temperature, gas density, and various chemical species.
当我增加总压强的时候,这意味着我放入越来越多的惰性气体,的蒸汽压会如何变化?,which, way, is, this,going ?,它是增加,减少很是保持不变?
As I'm increasing the total pressure, meaning I'm putting more and more inert gas in there, a Is it going up, down, or staying the same?
总压强P等于惰性气体的分压,与A物质的蒸汽压之和,在我们的例子中总压强是一个大气压。
Such that the sum of the partial pressure of the inert gas, plus the partial pressure of A, is the total pressure. One bar, in our case.
比p1中的压强小,在整个逆向过程中气体,会从p2到p1中去吗?
If p2, the pressure in p2, is less than the pressure in p1, is the gas going to want to go from p2 to p1 and the whole thing reverse back?
比p1中的压强小,在整个逆向过程中气体,会从p2到p1中去吗?
If p2, the pressure in p2, is less than the pressure in p1, is the gas going to want to go from p2 to p1 and the whole thing reverse back?
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