defective tightness

简明释义

不够紧密性

英英释义

例句

1.Due to defective tightness in the valve, the system experienced significant pressure loss.

由于阀门的密封性缺陷，系统出现了显著的压力损失。

2.The technician adjusted the bolts to correct the defective tightness in the assembly.

技术员调整了螺栓以修正装配中的密封性缺陷。

3.Inspectors found defective tightness in several joints during the safety audit.

检查员在安全审计中发现多个接头存在密封性缺陷。

4.The engineer reported that the pipe fittings had defective tightness, leading to leaks.

工程师报告说管道接头存在密封性缺陷，导致漏水。

5.The manufacturer recalled the product because of defective tightness in its seals.

制造商因产品密封件存在密封性缺陷而召回了该产品。

作文

In the realm of engineering and manufacturing, the term defective tightness refers to a situation where components do not fit together as intended, leading to potential failures or inefficiencies. This issue is particularly critical in industries like automotive, aerospace, and construction, where precision and reliability are paramount. When we talk about defective tightness (不合格的紧密度), we are often addressing problems that arise from poor design, substandard materials, or inadequate assembly processes.For instance, consider the case of an automobile engine. The various parts of the engine must be tightly fitted to ensure that they function correctly and efficiently. If there is defective tightness (不合格的紧密度) in the assembly of these parts, it could lead to oil leaks, overheating, and ultimately engine failure. This not only compromises the safety of the vehicle but also results in significant financial losses for manufacturers and consumers alike.Moreover, defective tightness (不合格的紧密度) can have serious implications in the aerospace industry. Aircraft components are subjected to extreme conditions, and any failure in tightness can lead to catastrophic outcomes. Engineers must conduct rigorous testing to ensure that all parts meet the required specifications. Any sign of defective tightness (不合格的紧密度) must be addressed immediately to maintain the integrity of the aircraft.In construction, the concept of defective tightness (不合格的紧密度) is equally important. Buildings must be constructed with materials that fit together perfectly to withstand environmental pressures such as wind, rain, and seismic activity. Poorly fitted components can lead to structural weaknesses, which may result in costly repairs or even disasters. Therefore, quality control measures are essential to identify and rectify issues related to defective tightness (不合格的紧密度) during the construction process.To prevent defective tightness (不合格的紧密度), companies invest in advanced technologies and methodologies. For example, the use of computer-aided design (CAD) allows engineers to create precise models that can be tested for fit before actual production begins. Additionally, implementing quality management systems can help organizations monitor their processes and ensure that all components are manufactured and assembled to the highest standards.Training and educating employees about the importance of achieving the correct tightness in assemblies is also crucial. Workers should be aware of how defective tightness (不合格的紧密度) can affect the overall performance of the product. Regular workshops and training sessions can help instill a culture of quality and attention to detail within the organization.In conclusion, understanding and addressing defective tightness (不合格的紧密度) is vital for ensuring the reliability and safety of products across various industries. By focusing on quality control, investing in technology, and educating workers, companies can minimize the risks associated with this issue. Ultimately, the goal is to deliver products that not only meet customer expectations but also adhere to the highest safety standards. As industries continue to evolve, the importance of maintaining tightness in assemblies will remain a critical factor in achieving success.

在工程和制造领域，术语不合格的紧密度指的是组件未能按照预期紧密配合，从而导致潜在的故障或低效率。这一问题在汽车、航空航天和建筑等行业尤为关键，因为这些行业对精度和可靠性要求极高。当我们谈论不合格的紧密度时，通常是在解决由于设计不良、材料不合格或组装过程不当而引发的问题。例如，考虑汽车发动机的情况。发动机的各个部件必须紧密配合，以确保它们正常高效地运作。如果这些部件的组装存在不合格的紧密度，可能会导致机油泄漏、过热，最终导致发动机故障。这不仅危及车辆的安全，还会给制造商和消费者带来巨大的经济损失。此外，不合格的紧密度在航空航天工业中也可能产生严重影响。飞机部件要承受极端条件，任何紧密度的失败都可能导致灾难性后果。工程师必须进行严格的测试，以确保所有部件符合所需的规格。任何不合格的紧密度的迹象都必须立即处理，以维护飞机的完整性。在建筑中，不合格的紧密度同样重要。建筑物必须用紧密配合的材料建造，以承受风、雨和地震等环境压力。配件配合不良可能导致结构弱点，这可能导致昂贵的维修甚至灾难。因此，质量控制措施对于在施工过程中识别和纠正与不合格的紧密度相关的问题至关重要。为了防止不合格的紧密度，公司在先进技术和方法上进行投资。例如，使用计算机辅助设计（CAD）可以让工程师在实际生产开始之前创建精确的模型并进行配合测试。此外，实施质量管理体系可以帮助组织监控其流程，确保所有组件按照最高标准制造和组装。培训和教育员工关于实现正确紧密度的重要性也至关重要。工人应该意识到不合格的紧密度如何影响产品的整体性能。定期的研讨会和培训课程可以帮助在组织内部培养质量和关注细节的文化。总之，理解和解决不合格的紧密度对于确保各行业产品的可靠性和安全性至关重要。通过关注质量控制、投资于技术以及教育工人，公司可以最大限度地减少与此问题相关的风险。最终目标是交付不仅满足客户期望且符合最高安全标准的产品。随着各行业的不断发展，保持组件紧密度的重要性仍将是成功的关键因素。