机械设计师英语怎么说
㈠ 机械类英语翻译(很急)
FPGA实现
该控制法在这工作的实施是一个标准的PID。该算法是类似(Galil运动运动)将在本节中的商业开发板所用的1。这项工作的主要贡献是通过一个地区高效FPGA实现高速数字结构。在FPGA器件的发展,使取得如DSP或微控制器的其他处理器比较高(伺服回路更新时间)采样率。另一方面,FPGA的集成性和便携性是非常适合硬件设计的互补结构,如配置文件生成,计数器,反馈系统接口是在同一个SoC技术的嵌入式集成电路,重要的,而需要单独DSP或微控制器并专门为这些外设逻辑。这也是必须注意的是FPGA的可重构,这意味着,每当一个数字上的内部结构修饰是必需的,对PID控制算法,甚至重大的修改,额外的控制结构时,PID控制是不够的,可以做到不改变由FPGA上的软件一样通过硬件描述语言的重新配置硬件。虽然DSP可以通过软件实现的控制算法中的变化,处理器的连续性质不能保证高采样率时,算法需要更多的计算周期,而FPGA的没有,由于其固有的并行结构的问题。 4.1。控制器的硬件设计
4.1.1。 PID的硬件
在这项工作中开发的设计进行了一些控制,如在法律一般可重构硬件控制器的目的:比例(P)的,比例积分(PI)的,比例,微分(PD)的,比例积分导数( PID控制),铅过滤器,过滤器和滞后导致滞后的过滤器。前面提到的所有法律,以更高的采样率允许更高的分辨率。该法律对这些控制的硬件设计,开发了基于数字上的一个关于二阶无限脉冲响应分歧方程(原居民)过滤显示(1),其中b和a是可以改变根据具体控制常系数法律中,x(k)为激励和y(k)是系统的输出:
(公式省略)
㈡ 怎么用英语翻译机械工程师,机械工程师用英语怎么说
机械工程师
mechanical engineer
㈢ 机械师用英语怎么说
机械师的英文:mechanician
mechanician 读法 英[mekə'nɪʃ(ə)n]
n. 机械学者,机械技师
短语:
1、 mechanician理论力学
2、Mechanician Engineer机械工程师
3、terrain mechanician地面力学
4、Senior Mechanician高级技工
5、mechanician mechanist机械技师
例句:
Weberis workinginagarageas amechanician.
韦伯在汽车修理厂作机械师。
(3)机械设计师英语怎么说扩展阅读
mechanician的相关词语:mechanic
mechanic 读法 英[mɪ'kænɪk]美[mə'kænɪk]
1、n. 技工,机修工
2、adj. 手工的
短语:
1、mechanic design机械设计
2、car mechanic 汽车修理师
例句:
1、What are the mechanics of this new process?
这一新工序的运作方式是什么?
2、He has not studied mechanics or engineering.
他没有学习过力学或者工程学。
㈣ 求机械类 英文翻译,急~~~谢谢了
机械
http://books.google.com.sg/books?hl=en&id=LmAV8q_OOOgC&dq=Mechanics&printsec=frontcover&source=web&ots=cG5UPfTZht&sig=CuTgwRZvwMOsDyyVeUKPxWAAJQU
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华文版本
http://zh.wikipedia.org/wiki/%E5%8A%9B%E5%AD%A6
Mechanics is the branch of physics concerned with the behaviour of physical bodies when subjected to forces or displacements, and the subsequent effect of the bodies on their environment.
The discipline has its roots in several ancient civilizations. During the early modern period, scientists such as Galileo, Kepler, and especially Newton, laid the foundation for what is now known as Classical mechanics.
Significance
Mechanics is the original discipline of physics, dealing with the macroscopic world that humans perceive. It is therefore a huge body of knowledge about the natural world. Mechanics encompasses the movement of all matter in the universe under the four fundamental interactions (or forces): gravity, the strong and weak interactions, and the electromagnetic interaction.
Mechanics also constitutes a central part of technology, the application of physical knowledge for humanly defined purposes. In this connection, the discipline is often known as engineering or applied mechanics. In this sense, mechanics is used to design and analyze the behavior of structures, mechanisms, and machines. Important aspects of the fields of mechanical engineering, aerospace engineering, civil engineering, structural engineering, materials engineering, biomedical engineering and biomechanics were spawned from the study of mechanics.
Classical versus quantum
The major division of the mechanics discipline separates classical mechanics from quantum mechanics.
Historically, classical mechanics came first, while quantum mechanics is a comparatively recent invention. Classical mechanics originated with Isaac Newton's Laws of motion in Principia Mathematica, while quantum mechanics didn't appear until 1900. Both are commonly held to constitute the most certain knowledge that exists about physical nature. Classical mechanics has especially often been viewed as a model for other so-called exact sciences. Essential in this respect is the relentless use of mathematics in theories, as well as the decisive role played by experiment in generating and testing them.
Quantum mechanics is of a wider scope, as it encompasses classical mechanics as a sub-discipline which applies under certain restricted circumstances. According to the correspondence principle, there is no contradiction or conflict between the two subjects, each simply pertains to specific situations. Quantum mechanics has superseded classical mechanics at foundational level and is indispensable for the explanation and prediction of processes at molecular and (sub)atomic level. However, for macroscopical processes classical mechanics is able to solve problems which are unmanageably difficult in quantum mechanics and hence remains useful and well used.
Einsteinian versus Newtonian
Analogous to the quantum versus classical reformation, Einstein's general and special theories of relativity have expanded the scope of mechanics beyond the mechanics of Newton and Galileo, and made small corrections to them. Relativistic corrections were also needed for quantum mechanics, although relativity is categorized as a classical theory.
There are no contradictions or conflicts between the two, so long as the specific circumstances are carefully kept in mind. Just as one could, in the loosest possible sense, characterize classical mechanics as dealing with "large" bodies (such as engine parts), and quantum mechanics with "small" ones (such as particles), it could be said that relativistic mechanics deals with "fast" bodies, and non-relativistic mechanics with "slow" ones. However, "fast" and "slow" are subjective concepts, depending on the state of motion of the observer. This means that all mechanics, whether classical or quantum, potentially needs to be described relativistically. On the other hand, as an observer, one may frequently arrange the situation in such a way that this is not really required.
Types of mechanical bodies
Thus the often-used term body needs to stand for a wide assortment of objects, including particles, projectiles, spacecraft, stars, parts of machinery, parts of solids, parts of fluids (gases and liquids), etc.
Other distinctions between the various sub-disciplines of mechanics, concern the nature of the bodies being described. Particles are bodies with little (known) internal structure, treated as mathematical points in classical mechanics. Rigid bodies have size and shape, but retain a simplicity close to that of the particle, adding just a few so-called degrees of freedom, such as orientation in space.
Otherwise, bodies may be semi-rigid, i.e. elastic, or non-rigid, i.e. fluid. These subjects have both classical and quantum divisions of study.
For instance: The motion of a spacecraft, regarding its orbit and attitude (rotation), is described by the relativistic theory of classical mechanics. While analogous motions of an atomic nucleus are described by quantum mechanics.
Sub-disciplines in mechanics
The following are two lists of various subjects that are studied in mechanics.
Note that there is also the "theory of fields" which constitutes a separate discipline in physics, formally treated as distinct from mechanics, whether classical fields or quantum fields. But in actual practice, subjects belonging to mechanics and fields are closely interwoven. Thus, for instance, forces that act on particles are frequently derived from fields (electromagnetic or gravitational), and particles generate fields by acting as sources. In fact, in quantum mechanics, particles themselves are fields, as described theoretically by the wave function.
Classical mechanics
The following are described as forming Classical mechanics:
Newtonian mechanics, the original theory of motion (kinematics) and forces (dynamics)
Lagrangian mechanics, a theoretical formalism
Hamiltonian mechanics, another theoretical formalism
Celestial mechanics, the motion of stars, galaxies, etc.
Astrodynamics, spacecraft navigation, etc.
Solid mechanics, elasticity, the properties of (semi-)rigid bodies
Acoustics, sound in solids, fluids, etc.
Statics, semi-rigid bodies in mechanical equilibrium
Fluid mechanics, the motion of fluids
Soil mechanics, mechanical behavior of soils
Continuum mechanics, mechanics of continua (both solid and fluid)
Hydraulics, fluids in equilibrium
Applied / Engineering mechanics
Biomechanics, solids, fluids, etc. in biology
Statistical mechanics, large assemblies of particles
Relativistic or Einsteinian mechanics, universal gravitation
Quantum mechanics
The following are categorized as being part of Quantum mechanics:
Particle physics, the motion, structure, and reactions of particles
Nuclear physics, the motion, structure, and reactions of nuclei
Condensed matter physics, quantum gases, solids, liquids, etc.
Quantum statistical mechanics, large assemblies of particles
Professional organizations
Applied Mechanics Division, American Society of Mechanical Engineers
Fluid Dynamics Division, American Physical Society
㈤ 机械设计助理工程师 怎么翻译
机械设计助理工程师 assistant mechanical layout engineer
㈥ 机械类英语翻译
1.在制作电子/电气产品声明的工作中,设备规格、生产能力、尺寸范围、吨位等是必不可少的。
2.即使设备不是很关键,产品的包装部分等也必须保持。类型相似的设备通常可以用来制造、加工或组装这些产品。
3.非关键设备----类型相似的设备可以用来制造、加工或组装这些产品。
envelope在机械上,是个技术性的词汇,指机械或其它设备的性能范围,或者功用极限,特别是在短语push the envelope中;另外在机械上还有包络的意思,比如addenm envelope指齿顶包络面(螺旋齿轮的)。
在第一句中,可以引申为“范围”(你也可以从信封的本意来想)。从以下附的解释中也可以看出这一点。
在第二句中,语序应该是这样的 the part proction envelopes etc must be maintained,however (the) equipment (is)less critical
这一句中,因为没有别的上下文可参考,从此意思上看我觉得envelopes应该是指包装。这个你可以参考你的原文出处。
附上一些关于envelope的解释:
n.
信封, 纸袋; 封[外]皮; 包封[皮, 装]
外[机]壳, 壳层; 包(围)层, 炉墙, 围砌; (电子射线管)泡
【数】包迹[线], 包络(线, 面), 方框(图)
【航空】气囊;【天】包层;【生】, 包被
floral envelope
【植】花被
例句
flight envelope
飞行包线
nuclear envelope
核膜
Self-addressed stamped envelope.
回邮信封贴足邮资写明发信人(自己)姓名地址的回信信封
damp-proofing for outer envelope
外围护结构防潮
An enveloping sheath or envelope.
外皮或包膜一个包装壳或外壳
㈦ 机械类专业英语中译英
Automatic fish feeding machine I design is mainly on account of an automatic fish feeding, but also guarantee the feed dry, try to ensure the use of low cost, after considering the decision to adopt a simple gear mechanism drives the eccentric wheel to thereby cause a slide block mechanism of reciprocating motion to meet a feeding process. The agencies with reference to a shaper of reciprocating movement of the body, such a mechanism is mainly to meet the simple structure and can complete the feed, and drying is used directly in the material box is placed in a separate drying box, outlet since the feeding end and closed automatically to ensure feed drying. This mechanism through a PLC system to control a feed feeding time, the motor control PLC a rotation, the motor drives the gear mechanism, gear mechanism driven by a crank slide block mechanism to complete a process of feeding. The PLC program timing cycle also ensures that the institution of a timed feeding, thereby completing a whole task requirements. Such a mechanism to meet the automatic feeding and drying, and low cost requirement. Key words: automatic fish feeding dry simple structure low price automatic timing
㈧ 机械类英语翻译(急急急)
这个ZOH代表的效果,运动控制过程中取样刷新以来每采样周期t高速加工要求更快的采样率比传统的加工(1),微软的采样周期中使用这种设计是百分之百的女士。因此,传递函数的ZOH在这个研究是通过以下方程描述。
PID控制器参数进行分析
这个模型是一个提议由塔尔(1989)运动控制器用于商业Galil运动控制板。塔尔声称,该模型具有传递函数的D(z)如图(8)和一个采样周期t滤波器参数K,a和C是由KP,KD和亲吻,分别指示。滤波系数之间的关系及其相关指令见表2。之后,塔尔显示的等价关系与传统的PID滤波器传递函数的G(s),在(9)随着表哪里比例(P),整体的(我)和衍生品(D)获得有关,KD和亲吻KP指令。最后,(10)所获得的替代物指示表2成(8),这是这个数字PID的表情,KD和亲吻KP。如图所示的连续模型(9),它是实现数字相当于在硬件,表现在传递函数(8),(10)。作为
方法通过频率响应调谐PID调节
该方法是基于两个重要方面的系统响应的品位和响应速度稳定性…一个系统的稳定性,而自然的反应显示系统的响应速度进行小订正能力而不引起振动。这个级别的稳定性是表达的相位边缘,系统的响应速度,直接关系到十字路口的频率。这是假设的设计目的可以用函数的交叉频率(oc)和相位保证金(ym)。因此Eqs。(十一)和(12):
(公式略11、12)。
这是在哪儿(小)的开环系统传递函数的伺服系统,如图6,代表了一种识别。B(s)产品,获得了ZOH数模转换器,功能H(s)和PID数字滤波器。
㈨ 见习机械设计工程师用英文怎么翻译
应该是student mechanical design engineer
㈩ 机械类英文翻译~~
电动起锚系缆绞盘
Electric anchor winch cable line
液压绞盘
Hydraulic windlass
液压起锚机 液压绞盘
Hydraulic windlass hydraulic windlass
电动液压起锚绞内盘
Electrically operated hydraulic pressure anchor capstan
电动起锚绞盘
Electrically operated anchor capstan
起锚系容缆绞盘
Raises anchor the lashing rope capstan