turbulators

简明释义

英[ˈtɜː.bjʊ.leɪ.təz]美[ˈtɜr.bjʊ.leɪ.tɚz]

[流][制冷]紊流器

扰流器（turbulator 的名词复数）

英英释义

单词用法

同义词

反义词

例句

1.The Elfin manufacturing process also imparts the ability to incorporate many enhancements such as louvers, air turbulators and vortex generators.

小巧的制作工艺，附加诸如天窗，空气涡流发生器、稳流器等许多功能。使得我们公司的翅片式热交换器性能更加优越。

2.An experimental investigation on the flow and heat transfer characteristics in rectangular channel with internal netted rib turbulators is conducted.

本文对网格式肋化内冷通道在静止状态下的强化传热与流动阻力特性进行了实验研究。

3.An experimental investigation on the flow and heat transfer characteristics in rectangular channel with internal netted rib turbulators is conducted.

本文对网格式肋化内冷通道在静止状态下的强化传热与流动阻力特性进行了实验研究。

4.By adding turbulators in the air duct, we improved the airflow efficiency significantly.

通过在空气管道中添加扰流器，我们显著提高了气流效率。

5.The engineers installed turbulators to enhance the mixing process in the chemical reactor.

工程师在化学反应器中安装了扰流器以增强混合过程。

6.The use of turbulators in the heat exchanger helped to increase the heat transfer rate.

在热交换器中使用扰流器有助于提高热传递率。

7.In our latest model, we incorporated turbulators to reduce turbulence in the fluid flow.

在我们的最新模型中，我们加入了扰流器以减少流体流动中的湍流。

8.The turbulators installed on the wings of the aircraft improve lift and reduce drag.

安装在飞机机翼上的扰流器提高了升力并减少了阻力。

作文

In the world of engineering and fluid dynamics, understanding the concept of turbulators is essential for optimizing flow characteristics and enhancing performance in various systems. A turbulator is a device or feature that is used to create turbulence in a fluid flow, which can significantly improve the mixing, heat transfer, and overall efficiency of processes involving liquids or gases. This essay will explore the role of turbulators in different applications, their benefits, and how they contribute to advancements in technology.Turbulators are commonly found in heat exchangers, where they help to disrupt the laminar flow of fluids. In a typical heat exchanger, fluid flows smoothly, which can lead to inefficient heat transfer due to the formation of boundary layers. By introducing turbulators, engineers can increase the turbulence of the fluid, promoting better mixing and enhancing the heat exchange process. This is particularly important in industries such as chemical processing, power generation, and HVAC systems, where maximizing thermal efficiency is crucial.Another significant application of turbulators is in the field of aerodynamics. For instance, aircraft wings are often designed with specific features that act as turbulators to control airflow over the surface. These features can help to delay flow separation, reduce drag, and improve lift, ultimately leading to better fuel efficiency and performance. The study of turbulators in aerodynamics has led to innovative designs that enhance the flight capabilities of modern aircraft, making them more efficient and environmentally friendly.Moreover, turbulators are also utilized in the automotive industry to improve the performance of engines and exhaust systems. By creating turbulence in the intake air or exhaust gases, turbulators can enhance mixing and combustion efficiency, resulting in better fuel economy and reduced emissions. This is particularly relevant in the context of stringent environmental regulations, where manufacturers are constantly seeking ways to minimize their ecological footprint while maintaining performance standards.In addition to their practical applications, turbulators also play a vital role in research and development. Engineers and scientists often conduct experiments using turbulators to study fluid behavior under various conditions. This research helps to inform the design of new technologies and improve existing systems. By understanding how turbulators influence fluid dynamics, researchers can develop more effective solutions for a wide range of engineering challenges.In conclusion, turbulators are indispensable components in many engineering applications, offering significant benefits in terms of efficiency, performance, and innovation. Whether in heat exchangers, aerodynamics, or automotive engineering, the ability to manipulate fluid flow through the use of turbulators has profound implications for technology and industry. As we continue to advance in our understanding of fluid dynamics, the role of turbulators will undoubtedly remain a focal point for engineers and researchers alike, driving further improvements and breakthroughs in various fields. Understanding and mastering the concept of turbulators is not just beneficial; it is essential for anyone involved in the design and optimization of fluid systems.

在工程和流体动力学的世界中，理解turbulators的概念对于优化流动特性和提高各种系统的性能至关重要。turbulator是一个装置或特征，用于在流体流动中产生湍流，这可以显著改善液体或气体涉及的过程中的混合、热传递和整体效率。本文将探讨turbulators在不同应用中的作用、它们的好处以及它们如何促进技术进步。turbulators通常出现在热交换器中，它们有助于扰动流体的层流。在典型的热交换器中，流体平稳流动，这可能导致由于边界层的形成而导致的热传递效率低下。通过引入turbulators，工程师可以增加流体的湍流，促进更好的混合并增强热交换过程。这在化学加工、发电和暖通空调系统等行业中特别重要，在这些行业中，最大化热效率至关重要。另一个重要的turbulators应用是在空气动力学领域。例如，飞机机翼通常设计有特定的特征，作为turbulators来控制流经表面的气流。这些特征可以帮助延迟流动分离、减少阻力并改善升力，最终导致更好的燃油效率和性能。对空气动力学中turbulators的研究促进了现代飞机的创新设计，使其更加高效和环保。此外，turbulators还在汽车工业中用于改善发动机和排气系统的性能。通过在进气空气或废气中产生湍流，turbulators可以增强混合和燃烧效率，带来更好的燃油经济性和减少排放。这在严格的环境法规背景下尤为相关，制造商不断寻求在保持性能标准的同时，尽量减少生态足迹。除了实际应用，turbulators在研究和开发中也发挥着重要作用。工程师和科学家经常使用turbulators进行实验，以研究不同条件下的流体行为。这项研究有助于为新技术的设计提供信息，并改善现有系统。通过了解turbulators如何影响流体动力学，研究人员可以为各种工程挑战开发更有效的解决方案。总之，turbulators在许多工程应用中是不可或缺的组成部分，在效率、性能和创新方面提供显著的好处。无论是在热交换器、空气动力学还是汽车工程中，通过利用turbulators操控流体流动的能力，对技术和工业具有深远的影响。随着我们对流体动力学理解的不断深入，turbulators的角色无疑将继续成为工程师和研究人员关注的焦点，推动各个领域进一步的改进和突破。理解和掌握turbulators的概念不仅有益，而且对任何参与流体系统设计和优化的人来说都是必不可少的。