jacket loss

简明释义

水套损失

英英释义

例句

1.The clothing retailer reported a significant jacket loss 夹克损失 due to inadequate storage conditions.

由于储存条件不足，这家服装零售商报告了显著的jacket loss 夹克损失。

2.We need to address the issue of jacket loss 夹克损失 in our inventory management system.

我们需要解决库存管理系统中的jacket loss 夹克损失问题。

3.The team conducted an analysis of the jacket loss 夹克损失 during transportation to improve their shipping methods.

团队对运输过程中的jacket loss 夹克损失进行了分析，以改善他们的运输方式。

4.Our latest report shows that jacket loss 夹克损失 has increased by 15% this quarter.

我们的最新报告显示，本季度jacket loss 夹克损失增加了15%。

5.To minimize jacket loss 夹克损失, we implemented better packaging solutions.

为了减少jacket loss 夹克损失，我们实施了更好的包装解决方案。

作文

In the world of engineering and thermodynamics, the term jacket loss refers to the loss of heat that occurs in systems with a jacketed design. These systems are often used in processes where temperature control is crucial, such as in chemical reactors or heat exchangers. The jacket serves as an outer layer that circulates a heating or cooling medium, helping to maintain the desired temperature within the inner vessel. However, despite its intended purpose, there are instances where heat can be lost through the jacket itself, leading to inefficiencies in the system. This phenomenon is what we refer to as jacket loss (夹套损失). Understanding jacket loss is essential for engineers and designers who aim to optimize thermal efficiency in their systems. When designing a jacketed vessel, it is crucial to consider factors such as insulation, the material of the jacket, and the flow rate of the heating or cooling medium. Poor insulation can lead to significant jacket loss, as heat escapes from the system rather than being utilized effectively. Additionally, the choice of materials can impact how much heat is retained within the system. For instance, metals with high thermal conductivity may exacerbate jacket loss if not properly insulated.Another aspect to consider is the flow dynamics within the jacket. If the flow rate of the heating or cooling medium is too low, it may not effectively transfer heat to or from the inner vessel, resulting in further jacket loss. Engineers must strike a balance between adequate flow rates and energy consumption to minimize this loss while maintaining system efficiency.To quantify jacket loss, engineers often use mathematical models that take into account the temperature differential between the inner vessel and the jacket, as well as the properties of the materials involved. These models help in predicting how much heat will be lost during operation, allowing for better design choices and operational strategies. By minimizing jacket loss, facilities can improve their energy efficiency, reduce operational costs, and lower their environmental impact.In practical applications, industries such as pharmaceuticals, food processing, and petrochemicals rely heavily on jacketed vessels. In these sectors, even small reductions in jacket loss can lead to significant cost savings and improved product quality. For example, in pharmaceutical manufacturing, maintaining precise temperatures is critical for the efficacy of certain compounds. By addressing jacket loss, manufacturers can ensure that their processes remain within optimal temperature ranges, thereby enhancing product consistency and safety.In conclusion, jacket loss represents a critical challenge in the design and operation of jacketed systems. By understanding the mechanisms behind this phenomenon, engineers can implement strategies to minimize heat loss, thus improving the overall efficiency of their processes. As industries continue to seek ways to enhance energy efficiency and sustainability, addressing jacket loss will remain a key focus in engineering practices. Ultimately, the goal is to create systems that not only perform effectively but also contribute positively to environmental stewardship.

在工程和热力学的世界中，术语夹套损失指的是在夹套设计的系统中发生的热量损失。这些系统通常用于温度控制至关重要的过程，例如化学反应器或换热器。夹套作为外层，循环加热或冷却介质，帮助维持内腔所需的温度。然而，尽管其目的明确，但在某些情况下，热量可能通过夹套本身流失，从而导致系统效率降低。这种现象就是我们所称的夹套损失。理解夹套损失对希望优化系统热效率的工程师和设计师至关重要。在设计夹套容器时，必须考虑绝缘、夹套材料以及加热或冷却介质的流速等因素。较差的绝缘会导致显著的夹套损失，因为热量从系统中逸出，而不是被有效利用。此外，材料的选择也会影响系统内热量的保留。例如，如果没有适当的绝缘，高导热性的金属可能会加剧夹套损失。另一个需要考虑的方面是夹套内的流动动态。如果加热或冷却介质的流速过低，可能无法有效地将热量传递到内腔，导致进一步的夹套损失。工程师必须在适当的流速和能耗之间寻找平衡，以最小化这种损失，同时保持系统效率。为了量化夹套损失，工程师通常使用数学模型，这些模型考虑了内腔与夹套之间的温差以及涉及材料的性质。这些模型有助于预测在操作过程中将损失多少热量，从而允许更好的设计选择和操作策略。通过最小化夹套损失，设施可以提高能源效率，降低运营成本，并减少环境影响。在实际应用中，制药、食品加工和石油化工等行业严重依赖夹套容器。在这些领域，即使是小幅度减少夹套损失也能带来显著的成本节约和产品质量改善。例如，在制药制造中，维持精确的温度对于某些化合物的有效性至关重要。通过解决夹套损失问题，制造商可以确保其过程保持在最佳温度范围内，从而提高产品的一致性和安全性。总之，夹套损失代表了夹套系统设计和操作中的一个关键挑战。通过理解这一现象背后的机制，工程师可以实施策略以最小化热量损失，从而提高其过程的整体效率。随着各行业继续寻求提高能源效率和可持续性，解决夹套损失将始终是工程实践中的一个重点。最终目标是创建不仅有效运作，而且对环境管理产生积极贡献的系统。