engineering system

简明释义

工程系统

英英释义

例句

1.The new engineering system is designed to optimize resource allocation in urban planning.

新的工程系统旨在优化城市规划中的资源分配。

2.The engineering system for the new bridge includes innovative safety features.

新桥的工程系统包括创新的安全功能。

3.Our team is developing a robust engineering system for monitoring environmental changes.

我们的团队正在开发一个强大的工程系统来监测环境变化。

4.To improve efficiency, we need to upgrade the existing engineering system in our manufacturing plant.

为了提高效率，我们需要升级我们制造工厂中现有的工程系统。

5.The engineering system used in this project integrates advanced software and hardware components.

这个项目中使用的工程系统集成了先进的软件和硬件组件。

作文

In today's rapidly evolving world, the term engineering system (工程系统) has gained significant importance across various fields. An engineering system is essentially a combination of physical components, processes, and human interactions designed to achieve specific goals or functions. These systems can be found in multiple domains, including civil engineering, mechanical engineering, electrical engineering, and even software engineering. Understanding the intricacies of an engineering system is crucial for engineers and professionals who aim to create efficient and effective solutions to complex problems.To illustrate the concept of an engineering system, consider the example of a transportation network. This network consists of roads, bridges, traffic signals, vehicles, and the people who use them. Each component plays a vital role in ensuring that the transportation system operates smoothly. Engineers must analyze how these components interact with one another and optimize their performance to reduce congestion, improve safety, and enhance overall efficiency. This holistic approach is what defines an engineering system.Another important aspect of engineering systems is their ability to adapt and evolve over time. As technology advances and societal needs change, so too must the systems we design. For instance, the rise of electric vehicles has prompted engineers to rethink traditional transportation systems, leading to the development of charging infrastructure and smart traffic management systems. This adaptability is essential for the long-term sustainability of any engineering system.Moreover, the integration of various disciplines within an engineering system is crucial for its success. Engineers often collaborate with professionals from other fields, such as environmental science, economics, and social sciences, to ensure that the systems they design are not only technically sound but also socially responsible and economically viable. This interdisciplinary approach fosters innovation and leads to more comprehensive solutions that address the multifaceted challenges we face today.In addition to technical skills, understanding an engineering system requires strong analytical and problem-solving abilities. Engineers must be adept at modeling and simulating different scenarios to predict how changes in one part of the system can affect the whole. For example, if a new bridge is constructed, engineers must assess how this will impact traffic patterns, environmental factors, and even local economies. By employing systems thinking, engineers can make informed decisions that benefit all stakeholders involved.Furthermore, the importance of sustainability in engineering systems cannot be overstated. As we confront global challenges such as climate change and resource depletion, engineers are tasked with designing systems that minimize environmental impact while maximizing efficiency. This may involve incorporating renewable energy sources, utilizing sustainable materials, and implementing waste reduction strategies. A well-designed engineering system not only meets the immediate needs of society but also considers the long-term health of our planet.In conclusion, the concept of an engineering system (工程系统) is fundamental to the field of engineering and beyond. It encompasses a wide range of components and interactions that must be carefully analyzed and optimized to achieve desired outcomes. As the world continues to change, so too must our approach to designing engineering systems. By embracing interdisciplinary collaboration, sustainability, and innovative thinking, we can create systems that not only solve today's problems but also pave the way for a better future.

在当今快速发展的世界中，术语工程系统（engineering system）在各个领域变得越来越重要。工程系统本质上是由物理组件、过程和人际互动组成的，旨在实现特定目标或功能。这些系统可以在多个领域中找到，包括土木工程、机械工程、电气工程，甚至软件工程。理解工程系统的复杂性对于那些旨在创造高效和有效解决方案的工程师和专业人士至关重要。为了说明工程系统的概念，考虑交通网络的例子。这个网络由道路、桥梁、交通信号、车辆和使用它们的人组成。每个组件在确保交通系统顺利运行中发挥着至关重要的作用。工程师必须分析这些组件如何相互作用，并优化其性能，以减少拥堵、提高安全性并增强整体效率。这种整体方法定义了工程系统。工程系统的另一个重要方面是其随着时间的推移而适应和演变的能力。随着技术的发展和社会需求的变化，我们设计的系统也必须随之改变。例如，电动车的兴起促使工程师重新思考传统交通系统，导致充电基础设施和智能交通管理系统的开发。这种适应性对于任何工程系统的长期可持续性至关重要。此外，工程系统内各学科之间的整合对于其成功至关重要。工程师通常与环境科学、经济学和社会科学等其他领域的专业人士合作，以确保他们设计的系统不仅在技术上是合理的，而且在社会责任和经济可行性方面也是如此。这种跨学科的方法促进了创新，并导致更全面的解决方案，解决我们今天面临的多方面挑战。除了技术技能之外，理解工程系统还需要强大的分析和解决问题的能力。工程师必须擅长建模和模拟不同场景，以预测系统某一部分的变化如何影响整体。例如，如果新建一座桥，工程师必须评估这将如何影响交通模式、环境因素，甚至地方经济。通过采用系统思维，工程师可以做出有利于所有相关方的明智决策。此外，在工程系统中可持续性的重要性不容小觑。随着我们面临全球性挑战，如气候变化和资源枯竭，工程师被要求设计尽量减少环境影响同时最大化效率的系统。这可能涉及整合可再生能源、利用可持续材料以及实施废物减少策略。一个设计良好的工程系统不仅满足社会的即时需求，还考虑到我们星球的长期健康。总之，工程系统（engineering system）的概念是工程及其他领域的基础。它包含了必须仔细分析和优化的广泛组件和交互，以实现所需的结果。随着世界的不断变化，我们对设计工程系统的方法也必须随之改变。通过拥抱跨学科合作、可持续性和创新思维，我们可以创建不仅解决今天问题的系统，还为更美好的未来铺平道路。