maximum operational weight

简明释义

最大运行重量

英英释义

例句

1.Before takeoff, the pilot checks that the total cargo does not surpass the maximum operational weight (最大操作重量) limit.

在起飞前，飞行员检查总货物是否超过了最大操作重量（最大操作重量）限制。

2.The aircraft can safely carry a maximum load, but it must not exceed the maximum operational weight (最大操作重量) specified by the manufacturer.

这架飞机可以安全地运输一个最大载荷，但不得超过制造商规定的最大操作重量（最大操作重量）。

3.The construction crew was reminded that the crane's maximum operational weight (最大操作重量) should never be exceeded to avoid accidents.

施工队被提醒，起重机的最大操作重量（最大操作重量）绝不能超过，以避免事故。

4.In order to ensure safety, all vehicles must adhere to the maximum operational weight (最大操作重量) guidelines set by transportation authorities.

为了确保安全，所有车辆必须遵守交通当局设定的最大操作重量（最大操作重量）指南。

5.When loading the truck, the driver must calculate the total weight to remain under the maximum operational weight (最大操作重量).

在装载卡车时，司机必须计算总重量，以保持在最大操作重量（最大操作重量）之下。

作文

Understanding the concept of maximum operational weight is crucial in various fields, particularly in aviation, logistics, and engineering. The term refers to the highest weight at which a vehicle, aircraft, or structure can safely operate without risking safety or performance. This weight limit is determined by several factors, including design specifications, materials used, and safety regulations. In aviation, for instance, the maximum operational weight is vital for ensuring that an aircraft can take off, fly, and land safely. Exceeding this weight can lead to catastrophic failures, such as structural damage or loss of control during flight.In the context of logistics, understanding the maximum operational weight of transport vehicles is essential for efficient loading and unloading processes. Trucks and shipping containers have weight limits that must be adhered to in order to prevent accidents on the road or at sea. Overloading a truck can result in increased wear and tear on the vehicle, reduced fuel efficiency, and higher risks of accidents. Therefore, logistics companies meticulously calculate the maximum operational weight to ensure compliance with safety regulations and to optimize their operations.Similarly, in construction and civil engineering, the maximum operational weight of structures like bridges and buildings is a critical factor in their design and safety assessments. Engineers must consider the weight of the materials used in construction, the expected loads from occupants and equipment, and environmental factors such as wind and seismic activity. By accurately determining the maximum operational weight, engineers can ensure that structures are built to withstand the forces they will encounter throughout their lifespan.Moreover, the implications of not adhering to the maximum operational weight can be severe. In aviation, for example, exceeding the weight limit can lead to accidents, resulting in loss of life and significant financial repercussions. In logistics, overloading can cause delays, fines, and damage to goods, ultimately affecting a company’s reputation and profitability. In construction, failing to respect the weight limits can lead to structural failures, posing risks to human life and causing costly repairs.To summarize, the maximum operational weight is a fundamental concept across various industries that ensures safety, efficiency, and reliability. By understanding and adhering to these weight limits, professionals can mitigate risks and enhance the performance of vehicles, structures, and systems. It is essential for individuals working in these fields to be educated about the implications of weight limits and to prioritize safety in all operational decisions. As we continue to advance technologically, the importance of understanding the maximum operational weight will only grow, reinforcing the need for rigorous standards and practices in engineering, logistics, and aviation.In conclusion, the maximum operational weight serves as a guiding principle that underscores the importance of safety and efficiency in various sectors. Whether it is in the sky, on the road, or within the confines of a building, respecting this limit is essential for successful operation. Professionals must remain vigilant and knowledgeable about these constraints to ensure that they operate within safe parameters, thereby safeguarding lives and enhancing productivity.

理解最大操作重量的概念在多个领域中至关重要，特别是在航空、物流和工程领域。该术语指的是车辆、飞机或结构可以安全操作而不危及安全或性能的最高重量。这个重量限制是由多个因素决定的，包括设计规格、使用的材料和安全法规。例如，在航空领域，最大操作重量对于确保飞机能够安全起飞、飞行和着陆至关重要。超过这个重量可能导致灾难性的故障，如结构损坏或飞行控制失效。在物流方面，了解运输工具的最大操作重量对于高效的装卸过程至关重要。卡车和集装箱有必须遵循的重量限制，以防止在道路或海上发生事故。超载卡车可能导致车辆磨损加剧、燃油效率降低以及更高的事故风险。因此，物流公司会仔细计算最大操作重量以确保遵守安全法规并优化运营。同样，在建筑和土木工程中，像桥梁和建筑物这样的结构的最大操作重量是其设计和安全评估中的关键因素。工程师必须考虑建材的重量、预期的居住者和设备的负荷，以及风和地震等环境因素。通过准确确定最大操作重量，工程师可以确保结构能够承受其在整个生命周期中将遇到的力量。此外，不遵守最大操作重量的后果可能是严重的。例如，在航空领域，超过重量限制可能导致事故，造成生命损失和重大财务损失。在物流中，超载可能导致延误、罚款和货物损坏，最终影响公司的声誉和盈利能力。在建筑中，未能遵守重量限制可能导致结构失效，给人身安全带来风险，并造成昂贵的维修费用。总之，最大操作重量是各行业的基本概念，确保安全、高效和可靠。通过理解和遵守这些重量限制，专业人士可以减轻风险，提高车辆、结构和系统的性能。在这些领域工作的人必须接受有关重量限制影响的教育，并在所有操作决策中优先考虑安全。随着技术的不断进步，理解最大操作重量的重要性只会增加，从而加强在工程、物流和航空领域的严格标准和实践的必要性。最后，最大操作重量作为一个指导原则，强调了在各个部门安全和效率的重要性。无论是在空中、在路上，还是在建筑物内，尊重这一限制对于成功运营至关重要。专业人士必须保持警惕，了解这些限制，以确保他们在安全范围内操作，从而保障生命安全并提高生产力。