defective tightness

简明释义

不紧密;

英英释义

例句

1.During the quality control inspection, we found defective tightness in several containers.

在质量控制检查中，我们发现几个容器存在密封性缺陷。

2.We must address the defective tightness issue before proceeding with the project.

在继续项目之前，我们必须解决密封性缺陷的问题。

3.The engineer reported that the pipeline had a defective tightness, which could lead to leaks.

工程师报告说管道存在密封性缺陷，这可能导致泄漏。

4.The technician identified defective tightness in the gasket, necessitating immediate replacement.

技术人员发现垫圈存在密封性缺陷，需要立即更换。

5.The manufacturer had to recall products due to defective tightness in the seals.

由于密封处存在密封性缺陷，制造商不得不召回产品。

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 in performance and safety. This concept is crucial in various industries, including automotive, aerospace, and consumer electronics. Understanding defective tightness is essential for engineers and manufacturers to ensure that products are reliable and safe for consumers.One common example of defective tightness can be found in the assembly of machinery. When parts are supposed to be tightly fitted but instead have gaps or loose connections, this can lead to vibrations, excessive wear, and ultimately, mechanical failure. For instance, if the bolts holding a machine together are not tightened properly or if the components themselves are manufactured with tolerances that are too loose, the result is defective tightness. This not only compromises the functionality of the machine but can also pose serious safety risks to operators and users.Furthermore, defective tightness is not limited to mechanical systems. In the construction industry, buildings and structures must maintain a certain level of integrity to withstand environmental pressures. If a building’s joints are not sealed correctly, it can lead to water leaks, energy inefficiency, and structural damage over time. This highlights the importance of quality control measures during the construction phase to prevent defective tightness from occurring.In the context of product design, addressing defective tightness involves meticulous planning and testing. Engineers must consider various factors such as material properties, thermal expansion, and the effects of wear over time. By utilizing advanced technologies like computer-aided design (CAD) and finite element analysis (FEA), designers can predict how components will interact under different conditions. This proactive approach helps to minimize the risk of defective tightness and ensures that products meet safety and performance standards.Moreover, the implications of defective tightness extend beyond just the immediate product. In many cases, companies face significant financial losses due to recalls, repairs, and damage to their reputation when defective tightness leads to product failures. Consumers expect high-quality products, and any deviation from this expectation can result in a loss of trust and loyalty. Therefore, it is imperative for businesses to prioritize quality assurance processes to identify and rectify issues related to defective tightness before products reach the market.In conclusion, defective tightness is a critical issue that affects various industries and has far-reaching consequences. From mechanical systems to construction projects and consumer products, ensuring that components fit together securely is vital for safety, performance, and customer satisfaction. By understanding the causes and implications of defective tightness, engineers and manufacturers can take the necessary steps to mitigate risks and deliver high-quality products that meet the expectations of their users. As technology continues to advance, the tools available for detecting and correcting defective tightness will only improve, leading to safer and more reliable products in the future.

在工程和制造领域，术语defective tightness指的是组件未能按预期紧密配合的情况，这可能导致性能和安全性的潜在故障。这个概念在汽车、航空航天和消费电子等多个行业中至关重要。理解defective tightness对于工程师和制造商来说是确保产品可靠和安全的重要环节。一个关于defective tightness的常见例子可以在机械组装中找到。当零件应该紧密贴合但实际上存在间隙或松动连接时，这可能导致振动、过度磨损，最终导致机械故障。例如，如果固定机器的螺栓没有正确拧紧，或者组件本身的制造公差过于松弛，结果就是defective tightness。这不仅会损害机器的功能，还可能对操作员和用户构成严重的安全风险。此外，defective tightness并不仅限于机械系统。在建筑行业中，建筑物和结构必须保持一定的完整性，以承受环境压力。如果建筑的接缝没有正确密封，随着时间的推移可能会导致漏水、能源效率低下和结构损坏。这突显了在施工阶段实施质量控制措施以防止defective tightness发生的重要性。在产品设计的背景下，解决defective tightness问题涉及到细致的规划和测试。工程师必须考虑各种因素，例如材料特性、热膨胀以及随时间变化的磨损影响。通过利用计算机辅助设计（CAD）和有限元分析（FEA）等先进技术，设计师可以预测组件在不同条件下的相互作用。这种前瞻性的方法有助于最小化defective tightness的风险，并确保产品符合安全和性能标准。此外，defective tightness的影响不仅限于直接产品。在许多情况下，当defective tightness导致产品故障时，公司面临着因召回、维修和声誉受损而造成的重大财务损失。消费者期望高质量的产品，任何偏离这一期望的情况都可能导致信任和忠诚度的下降。因此，企业必须优先考虑质量保证流程，以便在产品上市之前识别和纠正与defective tightness相关的问题。总之，defective tightness是一个影响多个行业并具有深远后果的关键问题。从机械系统到建筑项目，再到消费产品，确保组件安全地配合在一起对于安全、性能和客户满意度至关重要。通过理解defective tightness的原因和影响，工程师和制造商可以采取必要措施来降低风险，并提供满足用户期望的高质量产品。随着技术的不断进步，用于检测和修正defective tightness的问题的工具只会不断改善，从而在未来提供更安全、更可靠的产品。