throttle resistance

简明释义

节流阻力

英英释义

例句

1.During testing, we noticed increased throttle resistance 油门阻力 when the engine temperature rose.

在测试中，我们注意到当发动机温度升高时，throttle resistance 油门阻力增加。

2.The engineer explained that the throttle resistance 油门阻力 in the system could affect the vehicle's acceleration.

工程师解释说，系统中的throttle resistance 油门阻力可能会影响车辆的加速。

3.High throttle resistance 油门阻力 can lead to poor fuel efficiency and slower speeds.

高throttle resistance 油门阻力可能导致燃油效率低下和速度较慢。

4.Adjusting the carburetor can help reduce throttle resistance 油门阻力 for better performance.

调整化油器可以帮助减少throttle resistance 油门阻力以提高性能。

5.The technician measured the throttle resistance 油门阻力 to diagnose the issue with the fuel injection system.

技术员测量了throttle resistance 油门阻力以诊断燃油喷射系统的问题。

作文

In the world of engineering and mechanics, understanding various terms is crucial for effective communication and implementation of designs. One such term that often arises in discussions about engine performance and fluid dynamics is throttle resistance. This term refers to the opposition that a throttle valve presents to the flow of air or fuel within an engine, which directly affects the engine's efficiency and power output. The concept of throttle resistance can be observed in various types of engines, including internal combustion engines found in automobiles and gas turbines used in aircraft.When we discuss the functioning of an engine, the throttle valve plays a vital role in regulating the amount of air and fuel mixture that enters the combustion chamber. A properly functioning throttle allows for optimal combustion, leading to maximum power output and fuel efficiency. However, when there is excessive throttle resistance, it can hinder this process, resulting in decreased performance. This could be due to several factors, such as mechanical wear, improper calibration, or even design flaws.For example, consider a car that is experiencing sluggish acceleration. A mechanic may diagnose the problem as stemming from high throttle resistance. In this case, the throttle valve may not be opening fully, restricting the airflow and consequently limiting the engine's ability to generate power. By addressing the issue—whether through cleaning, recalibrating, or replacing the throttle valve—the mechanic can reduce the throttle resistance and restore the vehicle’s performance.Moreover, throttle resistance is not just a concern in automotive applications; it also has implications in the aerospace industry. Aircraft engines, particularly jet engines, rely on precise control of airflow to maintain thrust and efficiency. Any increase in throttle resistance can lead to a loss of performance, which is critical during takeoff and landing phases. Engineers must carefully design throttle systems to minimize resistance while ensuring safety and reliability.In addition to its technical implications, understanding throttle resistance can also enhance our appreciation of how machines operate. When we grasp the significance of this term, we can better understand the intricacies involved in engine design and optimization. For those interested in pursuing careers in engineering or mechanics, having a solid grasp of terms like throttle resistance is essential for success in the field.Furthermore, as technology continues to advance, the importance of minimizing throttle resistance becomes even more pronounced. With the rise of electric vehicles and hybrid systems, engineers are tasked with finding innovative ways to improve efficiency. Understanding how traditional concepts like throttle resistance apply to new technologies will be key in driving future advancements.In conclusion, throttle resistance is a fundamental concept in the realm of mechanical engineering that has far-reaching implications across various industries. Whether in automotive engineering or aerospace, the impact of throttle resistance on performance cannot be overstated. By comprehensively understanding this term, we not only enhance our knowledge of engine mechanics but also equip ourselves with the tools necessary for innovation in the ever-evolving landscape of technology.

在工程和机械的世界中，理解各种术语对于有效沟通和设计实施至关重要。其中一个常常出现在关于发动机性能和流体动力学讨论中的术语是节气门阻力。这个术语指的是节气门阀对进入发动机的空气或燃料流动所产生的阻力，这直接影响着发动机的效率和功率输出。节气门阻力的概念可以在各种类型的发动机中观察到，包括汽车中的内燃机和飞机中使用的燃气涡轮。当我们讨论发动机的工作时，节气门阀在调节进入燃烧室的空气和燃料混合物的数量方面起着至关重要的作用。正常工作的节气门允许最佳燃烧，从而导致最大的功率输出和燃油效率。然而，当存在过高的节气门阻力时，它可能会阻碍这一过程，导致性能下降。这可能是由于多种因素，例如机械磨损、不当校准甚至设计缺陷。例如，考虑一辆加速迟缓的汽车。机械师可能会诊断出问题源于高节气门阻力。在这种情况下，节气门阀可能无法完全打开，限制了气流，从而限制了发动机产生功率的能力。通过解决这个问题——无论是清洁、重新校准还是更换节气门阀——机械师可以降低节气门阻力，恢复车辆的性能。此外，节气门阻力不仅仅是汽车应用中的一个问题；它在航空航天工业中也有影响。飞机发动机，特别是喷气发动机，依赖于精确控制气流以保持推力和效率。任何增加的节气门阻力都可能导致性能损失，这在起飞和着陆阶段至关重要。工程师必须仔细设计节气门系统，以最小化阻力，同时确保安全性和可靠性。除了其技术含义外，理解节气门阻力还可以增强我们对机器运行方式的欣赏。当我们掌握这个术语的重要性时，我们可以更好地理解发动机设计和优化中涉及的复杂性。对于那些有意从事工程或机械职业的人来说，牢固掌握像节气门阻力这样的术语对成功至关重要。此外，随着技术的不断进步，最小化节气门阻力的重要性变得更加突出。随着电动车和混合动力系统的兴起，工程师们被要求寻找创新的方法来提高效率。理解传统概念如节气门阻力如何适用于新技术将是推动未来进步的关键。总之，节气门阻力是机械工程领域的一个基本概念，具有跨行业的深远影响。无论是在汽车工程还是航空航天，节气门阻力对性能的影响都不容小觑。通过全面理解这个术语，我们不仅增强了对发动机机械的知识，而且为在不断发展的技术领域的创新提供了必要的工具。