本文为您带来热力的英文翻译，包括热力用英语怎么说，热力用英语怎么说，热力的英语造句，热力的英文原声例

本文为您带来热力的英文翻译，包括热力用英语怎么说，热力用英语怎么说，热力的英语造句，热力的英文原声例句，热力的相关英语短语等内容。

热力的英文翻译，热力的英语怎么说？

热力的英语网络释义

GPS系统在热力管线中的应用-好期刊网-计算机毕业论文|教育论文发表|建筑论文写作|毕业论文|医疗论文发表|经济论文|社科论文发表|英语论文 关键词】：热力，测量，CORS [gap=779]key words 】 : heat, measured, CORS

热力地理信息系统的建设和运行维护 关键词 ：热力；地理信息系统；建设；运行维护 [gap=519]Key words ：heating power； geographic information system； construction； operation maintenance

热力(thermal force), 此释义来源于网络辞典。

专辑英文名 : Sweat 专辑中文名 : 热力 歌手 : Nelly 版本 : [Flac] 发行时间 : 2004年 地区 : 美国 语言 : 英语 简介 :专辑介绍：2000年夏天，嘻哈热浪吹

热力的汉英大词典

热力[rè lì]

• {机} heating power
• 短语:
  • 热力变质岩 thermal metamorphic rock;
  • 热力变质作用 thermal metamorphism; {岩} thermometamorphism;
  • 热力采油 oil recovery by heating;
  • 热力层次 thermodynamic stratification;
  • 热力潮 {气} thermal tide;
  • 热力穿孔机 jet-pierce machine;
  • 热力对流 thermal convection; free convection;
  • 热力方程 heat equation;
  • 热力风化 thermal weathering;
  • 热力工程 heat engineering; thermal engineering;
  • 热力管道 heat distribution pipeline;
  • 热力过程 thermodynamic process;
  • 热力红斑 erythema caloricum;
  • 热力计算 thermodynamic calculation;
  • 热力交代作用 pyrometasomatism;
  • 热力离解作用 thermal dissociation;
  • 热力浓度 tehrmodynamic concentration;
  • 热力偶塞 thermal plug;
  • 热力平衡 thermodynamic equilibrium;
  • 热力气旋生成 thermocyclogenesis;
  • 热力切割法 thermodynamic cutting process;
  • 热力扰动 thermodynamic disturbance;
  • 热力势 {热} thermodynamic potential;
  • 热力图 thermodynamic chart; thermodynamic diagram;
  • 热力系统 thermodynamic system;
  • 热力效率 thermodynamic efficiency;
  • 热力循环 thermal circuit; thermodynamic cycle;
  • 热力有效浓度 thermodynamic concentration;
  • 热力再流动法 thermal-reflowing process;
  • 热力凿岩 thermal drilling;
  • 热力钻进 thermal-spalling drilling;
  • 热力钻机 jet drill

热力的英语短语

热力的英文例句

在这种情况下，老化必须根据物理化学和热力学定律进行。

Ageing in this case must occur according to the laws of physical chemistry and of thermodynamics.

金字塔、大教堂和火箭的存在并不是因为几何形状或热力学，而是因为它们首先是建造它们的人的脑海中的图画。

Pyramids, cathedrals, and rockets exist not because of geometry or thermodynamics, but because they were first a picture in the minds of those who built them.

但我们知道热力学都是关于平衡的。

But we know thermodynamics is all about equilibrium.

我们已经从热力学，了解了平衡。

And we already know about equilibrium from thermodynamics.

它真正的能量来自地球内部的热力。

It is simply power derived from the Earth's internal heat.

然后抽象这些一般的热力学定律。

We formulate these broad thermodynamic laws.

这些依赖于热力学,和平衡态的性质。

They also do depend on thermodynamics and where equilibrium states are.

总体上可以说热力学限制了这些特性。

Collectively, these features can be said to arise via thermodynamic constraints.

在热力学或者统计力学中。

In statistical mechanics and in thermodynamics.

你可以把非平衡热力学,应用于经济学。

You can apply non-equilibrium thermodynamics to economics.

在方程里面，基本是相同的热力学图像。

In your equations, it's the same thermodynamic picture.

即我们前面学到的热力学。

The thermodynamics that we've seen so far.

和热力学没有任何关系。

It has nothing to do with thermodynamics.

它是热力学的微观描述。

The microscopic underpinnings of thermodynamics.

这就是热力学第零定律。

And that's the zeroth law thermodynamic.

现在我开始推导热力学。

Now, what I want to do is start deriving thermodynamics.

但不改变热力学过程。

It doesn't change the thermodynamics.

这是热力学第一定律。

That's the first law of thermodynamics.

因为所有的热力学量都是态函数。

Since these are all state functions.

但热力学做的是鸟瞰。

But thermodynamics takes a bird's eye view.

这条指责误解了热力学第二定律。

This argument derives from a misunderstanding of the Second Law.

如果它是个平衡系统，那么热力学就能描述它。

If it's an equilibrium system, then thermodynamics can describe it.

在热力学的框架下，我们已经处理过这些问题。

On the thermodynamic framework e've been working with all term.

因此热力学只研究平衡系统。

So it only talks about equilibrium systems.

由于核心旋转更加迅速，其热力与大小也会增加。

Because the core is spinning more rapidly, it is increasing in heat and size.

这样我们就能开始写出不同结果，热力学性质的。

And then we can start writing out the results for the various thermodynamic properties.

现在我想看一下关于这个的热力学知识。

So now, I want to take a look at the energetics of that.

这样我们可以马上开始，得到所有热力学的量对吧？

And so we can immediately start in deriving all of the thermodynamics, right?

学完渗透压之后，你们就把热力学学完了。

And after osmotic pressure, you'll be done with thermo.

所以能够利用G写出任意一个热力学函数。

So we can write any of these functions in terms of G.

热力的原声例句

Thermodynamics is asking you, what work does this thing do on the surroundings or the surroundings do on the system?

热力学在问你们，到底是系统对环境做功,还是环境对系统做功？

So what they do is, they're describing how these thermodynamic properties change, in terms of only state functions and state variables.

他们的作用是描述,随着状态函数和状态变量的变化，系统的热力性质如何变化。

So, what we're going to do now is look at the energetics associated with that.

所以现在我们要做的就是,看一下与之相关的热力学。

And they had this feeling because there had just been this huge boon of discovery, of scientific advances that included Newtonian mechanics, it included Dalton's atomic theory of matter, also thermodynamics and classical electromagnetism.

他们会有这样的感觉,是因为他们刚，经历科学上的,大繁荣期，包括牛顿力学,道尔顿物质原子理论，热力学和电磁学,都取得了巨大进展。

Now the first law is going to hold in all of these steps, and we're going around in a cycle.

现在热力学第一定律,就蕴含在这所有的步骤里了，我们沿着这个循环走。

And if you work out the energetics as we've gone with thermochemistry, dH you discover there's a huge negative delta H.

如果你计算能量变化,就像在化学热力学中所作的一样，你会发现很大的负的。

If you have a quantity which is constant over any closed path, that quantity is a thermodynamics state function.

如果有一个物理量,对任何闭合回路积分是常数，这个物理量就是一个热力学态函数。

So in some sense, the first law would suggest you can sort of break even.

初看起来，热力学第一定律,可以保证这个过程是可行的。

Now, last day, we looked at the energetics of the ionic bond, right?

昨天，我们讲的是离子键的热力学，对么？

Now let's look at the energetics graphically now.

现在我们来看看热力学。

Thermodynamicstalks about equilibrium systems and how to go from one state of equilibrium to another state of equilibrium.

热力学研究的是平衡系统,以及如何,从一个平衡态转变到另一个平衡态。

So now let's go around the cycle and just compare notes on what happens to the thermodynamic quantities as we do that.

现在让我们推导一下这个循环,比较一下这个过程中,热力学性质的变化。

So he grabbed his thermometer, and went and made a couple of measurements and discovered the first law of thermodynamics.

所以他拿来了温度计，进行测量,后来就发现了热力学第一定律。

And the bigger lesson from that is that entropy, unlike energy u or enthalpy H, we could define an absolutely number for it.

热力学第三定律的一个更重要的推论是,与内能和自由焓不同，我们可以给上定义一个绝对的数值。

So thermodynamics, based on these four laws now, requires an edifice, and it's a very mature science, and it requires that we define things carefully.

热力学是一座，建立在这四条定律上的大厦,它是一门非常成熟的科学，也要求我们在定义东西时非常小心。

This is an abstract and powerful mathematical statement of the first law of thermodynamics.

这是热力学第一定律的一个抽象,而且具有很强数学性的表述。

And the cause of some thermodynamics have even been applied to economics, systems out of equilibrium, like big companies like Enron, you know, completely out of equilibrium, crash and burn.

热力学中的一些观点,甚至被应用到经济学中，非平衡态系统，比如像安永那样大公司,彻底偏离平衡态,最后破产了。

So, thermo is also a big tease, as you can see from my descriptions of these laws here.

因此，热力学也是个大玩笑，从我下面对,这些定律的描述。

And we can do that by going through and deriving What we'll call the fundamental equations of thermodynamics.

通过推导,所谓的,基本热力学方程可以做到这一点。

It's not going to be zero this time because we have non zero heat exchange between the system and the environment, right.?

热力学量，但是现在让我们看一下,我们的特殊函数，这次它不会是零,因为系统与外界的热量交换并不是零，对吧？

So, over the last few lectures we've worked and struggled so formulate the second and third laws of thermodynamics in addition to the first.

在前几次课中,我们通过努力明确的,给出了热力学,第一，第二和第三定律。

Fairly powerful statement, and that's another form of the first law of thermodynamics.

这是一个相当有用的表述,是热力学第一定律的另外一种形式。

We could choose any two quantities, and, in fact, it turns out that these are going to prove, after we have the second law, not to be the best choice.

我们可以任选两个物理量，其实，在学习了热力学第二定律之后，我们可以证明，这样的选择并不是最好的。

That's for a different lecture So, anyway, thermodynamics dates from the same period as getting fossil fuels out of the ground.It's universal.

这是另一堂课的内容,不管怎么说,热力学与开采化石燃料,起源于同一时期，它是普适的。

and added a structure of math upon it, to build this edifice, which is a very solid edifice of thermodynamics as a science of equilibrium systems.

了这座热力学的坚固大厦，这是一门，平衡态系统,的科学。

The only way you could possibly contemplate it is to be working at absolute zero Kelvin.

在绝对零度下工作,猜一下热力学第三定律告诉我们什么？

And this is just an incredibly important area that thermodynamics allows us to speak to.

这是热力学中我们需要讨论的一个,很重要的领域。

It turns out that when you're talking about macroscopic properties of matter, you don't need very many variables to describe the system completely thermodynamically.

实际上,当你谈及物质的宏观性质时，你并不需要很多变量才能从热力学上,完整地描述这个系统，’

That is, it gives us the relationship between energy and work and heat.

热力学第一定律阐述了,能量，功和热之间的关系。

So it applies to macroscopic systems that are in equilibrium, and how to go from one equilibrium state to another equilibrium state, and it's entirely empirical in its foundation.

因此，热力学研究的是平衡态的宏观系统,以及如何从,一个平衡态过渡到另一个平衡态，它完全是建立在经验的基础上的。

热力的网络释义

很抱歉，暂无字的网络释义。

以上关于热力的英语翻译来自英汉大词典，希望对您学习热力的英语有帮助。