compressure

简明释义

英[/kəmˈprɛʃər/]美[/kəmˈprɛʃər/]

n. 压缩，抑制；压缩力

英英释义

单词用法

同义词

反义词

例句

1.Be responsible for parparing management procedure and work instructions on air compressure system, boiler, air conditioning system, water treatment system, pressure vessel and pressure pipeline.

负责编制空压系统、锅炉、空调系统、水处理设施、厂内机动车辆、压力容器、压力管道等设备的操作规程、作业指导书、管理制度。

2.Calibration relationship between compressure ratio and digital counter reading can be used to evaluate the spark-ignition engine.

采用压缩比与数字计数器的对应检索校正关系来评定检查火花点燃式发动机的机械状况。

3.It is showed that the exergy loss ofthe compressure is nearly50% of total input exergy and the bed column almost30% the coler 9.39% the waste gas 5.73% the total energy efficiency is only8.51%.

结果表明，压缩机（火用）损失接近系统总输入（火用）的50%，床层（火用）损失接近30%，冷却器（火用）损失为9。 39%，废气带走的（火用）为5。 73%； 总（火用）效率为8。 51%。

4.Be responsible for parparing management procedure and work instructions on air compressure system, boiler, air conditioning system, water treatment system, pressure vessel and pressure pipeline.

负责编制空压系统、锅炉、空调系统、水处理设施、厂内机动车辆、压力容器、压力管道等设备的操作规程、作业指导书、管理制度。

5.In this experiment, we will measure the compressure (压缩) of different gases.

在这个实验中，我们将测量不同气体的compressure（压缩）。

6.The technician noticed that the compressure (压缩) levels were too high, causing potential damage.

技术员注意到compressure（压缩）水平过高，可能导致损坏。

7.To improve performance, the team focused on optimizing compressure (压缩) settings.

为了提高性能，团队专注于优化compressure（压缩）设置。

8.The engineer explained how the compressure (压缩) in the system affects the overall efficiency.

工程师解释了系统中的compressure（压缩）如何影响整体效率。

9.During the meeting, we discussed the importance of compressure (压缩) in reducing energy costs.

在会议中，我们讨论了compressure（压缩）在降低能源成本中的重要性。

作文

In the realm of physics and engineering, the concept of compressure plays a crucial role in understanding how materials behave under different conditions. Compressure refers to the act of applying pressure to an object or substance, leading to a reduction in volume. This phenomenon is essential in various applications, including the design of engines, the creation of compressed gases, and even the development of new materials. One of the most common examples of compressure can be found in the field of hydraulics. Hydraulic systems rely on the principles of compressure to transmit force through incompressible fluids. When pressure is applied to a fluid, it exerts force equally in all directions, allowing for the efficient transfer of energy. This principle is utilized in machinery such as excavators, forklifts, and even car brakes, where the ability to control force through compressure is vital for functionality and safety.Moreover, compressure is also significant in the study of gases. According to Boyle's Law, when the pressure on a gas increases, its volume decreases, provided the temperature remains constant. This relationship highlights the importance of compressure in various scientific and industrial processes. For instance, in refrigeration systems, gases are compressed to lower their temperature, which is then used to cool the surrounding environment. Understanding compressure allows engineers to design more efficient cooling systems and improve energy consumption.In addition to practical applications, compressure has implications in the natural world. The Earth's atmosphere is a prime example of how compressure affects our environment. As altitude increases, atmospheric pressure decreases, resulting in lower compressure levels. This difference in pressure can significantly impact weather patterns and climate. Meteorologists study these variations to predict storms, understand wind patterns, and analyze climate change effects.Furthermore, compressure is not limited to physical sciences; it also finds relevance in the biological realm. In human physiology, the lungs demonstrate the principles of compressure during respiration. When we inhale, the diaphragm contracts, creating a negative pressure within the thoracic cavity. This compressure allows air to flow into the lungs, facilitating the exchange of oxygen and carbon dioxide. Understanding this process is essential for medical professionals, especially in fields related to respiratory health.To conclude, the concept of compressure is integral to multiple disciplines, from engineering and physics to biology and environmental science. Its applications are vast and varied, demonstrating the interconnectedness of different fields of study. As technology advances and our understanding of materials and forces deepens, the principles of compressure will continue to play a pivotal role in innovation and discovery. By grasping the significance of compressure, we can appreciate the complexities of the world around us and harness this knowledge for future advancements.

在物理和工程领域，compressure的概念在理解材料在不同条件下的行为中发挥着至关重要的作用。Compressure指的是对物体或物质施加压力的行为，导致体积减少。这种现象在各种应用中至关重要，包括发动机设计、压缩气体的产生，甚至新材料的开发。Compressure的一个常见例子可以在液压学领域找到。液压系统依赖于compressure的原理，通过不可压缩的流体传递力量。当对流体施加压力时，它会在各个方向均匀地施加力，从而实现能量的高效传递。这个原理被用于挖掘机、叉车甚至汽车刹车等机械中，在这些机械中，通过compressure控制力量对功能和安全至关重要。此外，compressure在气体研究中也具有重要意义。根据波义耳定律，当对气体施加压力时，其体积会减小，前提是温度保持不变。这种关系突显了compressure在各种科学和工业过程中的重要性。例如，在制冷系统中，气体被压缩以降低其温度，然后用于冷却周围环境。理解compressure使工程师能够设计更高效的冷却系统并改善能源消耗。除了实际应用，compressure在自然界中也有影响。地球的大气层就是一个如何影响我们环境的典型例子。随着海拔的增加，大气压力降低，导致compressure水平降低。这种压力差异可以显著影响天气模式和气候。气象学家研究这些变化以预测风暴、理解风向模式以及分析气候变化的影响。此外，compressure不仅限于物理科学；它在生物领域也具有相关性。在人体生理学中，肺部在呼吸过程中展示了compressure的原理。当我们吸气时，横膈膜收缩，胸腔内产生负压。这种compressure使空气流入肺部，促进氧气和二氧化碳的交换。理解这一过程对医疗专业人员尤为重要，尤其是在与呼吸健康相关的领域。总之，compressure的概念在多个学科中都是不可或缺的，从工程和物理到生物和环境科学。它的应用广泛而多样，展示了不同研究领域之间的相互联系。随着技术的进步和我们对材料和力量的理解加深，compressure的原理将继续在创新和发现中发挥关键作用。通过掌握compressure的重要性，我们可以欣赏周围世界的复杂性，并利用这些知识推动未来的发展。