maximum operation pressure
简明释义
最高工作压力
英英释义
The maximum operational pressure refers to the highest pressure at which a system, equipment, or component can safely operate without risk of failure or damage. | 最大操作压力是指系统、设备或组件可以安全运行而不风险故障或损坏的最高压力。 |
例句
1.The engineer adjusted the settings to maintain the maximum operation pressure (最大工作压力) during the test.
工程师调整了设置,以在测试过程中保持最大工作压力 (最大工作压力)。
2.Before starting the pump, check the maximum operation pressure (最大工作压力) indicated on the label.
在启动泵之前,检查标签上指示的最大工作压力 (最大工作压力)。
3.The specifications state that the maximum operation pressure (最大工作压力) is 150 psi.
规格说明中指出,最大工作压力 (最大工作压力)为150 psi。
4.Exceeding the maximum operation pressure (最大工作压力) can lead to equipment failure.
超过最大工作压力 (最大工作压力)可能导致设备故障。
5.The hydraulic system must not exceed the maximum operation pressure (最大工作压力) to ensure safety.
液压系统必须不超过最大工作压力 (最大工作压力)以确保安全。
作文
Understanding the concept of maximum operation pressure is essential in various engineering fields, particularly in the design and operation of pressure vessels and piping systems. The term refers to the highest pressure that a system can withstand during normal operations without failing or sustaining any damage. This limit is critical for ensuring safety and reliability in industrial applications.In many industries, such as oil and gas, chemical processing, and power generation, equipment operates under high pressures. For example, in a chemical reactor, maintaining the maximum operation pressure is crucial for the reaction to proceed efficiently while preventing leaks or catastrophic failures. Engineers must carefully calculate and select materials that can endure these pressures throughout the equipment's lifespan.The determination of maximum operation pressure involves several factors, including the material properties, temperature, and the nature of the fluid being handled. Materials must be chosen based on their tensile strength and resistance to corrosion, especially in environments that may expose them to harsh chemicals or extreme temperatures. Additionally, safety factors are incorporated into the design to account for unexpected conditions that could lead to pressure surges.Regulatory standards and codes, such as those established by the American Society of Mechanical Engineers (ASME) and the American Petroleum Institute (API), provide guidelines for determining the maximum operation pressure of equipment. Compliance with these standards ensures that systems are designed with safety in mind, minimizing the risk of failure. Regular inspections and maintenance are also necessary to monitor the condition of equipment and ensure it operates within the specified limits.In practice, exceeding the maximum operation pressure can lead to severe consequences, including equipment rupture, explosions, and environmental disasters. For instance, in a high-pressure pipeline system, a sudden increase in pressure can cause the pipe to burst, resulting in hazardous spills and potential injuries to personnel. Therefore, operators must continuously monitor pressure levels and implement control measures to prevent exceeding the established limits.Moreover, advancements in technology have led to the development of smart sensors and monitoring systems that provide real-time data on pressure levels. These innovations help operators make informed decisions and take immediate action if pressure approaches the maximum operation pressure. By leveraging these technologies, industries can enhance safety and operational efficiency.In conclusion, the concept of maximum operation pressure is a fundamental aspect of engineering that plays a vital role in ensuring the safety and functionality of pressure-related systems. Understanding its implications allows engineers and operators to design better systems, adhere to safety regulations, and ultimately protect both human lives and the environment. As industries continue to evolve, the importance of managing maximum operation pressure will remain a priority, necessitating ongoing education and technological advancements in the field.
理解最大操作压力的概念在各个工程领域中至关重要,特别是在压力容器和管道系统的设计和操作中。该术语指的是系统在正常操作期间能够承受而不发生故障或损坏的最高压力。这一限制对于确保工业应用中的安全性和可靠性至关重要。在许多行业中,如石油和天然气、化学加工以及发电,设备在高压下运行。例如,在化学反应器中,维持最大操作压力对于反应的有效进行至关重要,同时可以防止泄漏或灾难性故障。工程师必须仔细计算并选择能够在设备整个使用寿命内承受这些压力的材料。最大操作压力的确定涉及多个因素,包括材料特性、温度和所处理流体的性质。材料必须根据其抗拉强度和耐腐蚀性进行选择,尤其是在可能暴露于严酷化学品或极端温度的环境中。此外,设计中还会加入安全系数,以应对可能导致压力激增的意外情况。监管标准和规范,例如美国机械工程师协会(ASME)和美国石油协会(API)制定的标准,为确定设备的最大操作压力提供了指导。遵守这些标准确保系统在设计时考虑到安全性,最大限度地减少故障风险。定期检查和维护也是必要的,以监测设备的状况并确保其在规定的限制内运行。在实践中,超过最大操作压力可能导致严重后果,包括设备破裂、爆炸和环境灾难。例如,在高压管道系统中,压力的突然增加可能导致管道破裂,从而造成危险的泄漏和对人员的潜在伤害。因此,操作人员必须持续监测压力水平,并实施控制措施以防止超过既定限制。此外,技术的进步导致智能传感器和监测系统的发展,这些系统提供实时数据来监测压力水平。这些创新帮助操作人员做出明智的决策,并在压力接近最大操作压力时立即采取行动。通过利用这些技术,行业可以提高安全性和操作效率。总之,最大操作压力的概念是工程的一个基本方面,在确保与压力相关的系统的安全性和功能性方面发挥着重要作用。理解其影响使工程师和操作人员能够设计更好的系统,遵守安全法规,并最终保护人类生命和环境。随着行业的不断发展,管理最大操作压力的重要性将继续成为优先事项,迫切需要在该领域进行持续教育和技术进步。
相关单词
