number of turns of winding

简明释义

绕组匝数

英英释义

例句

1.The designer specified a specific number of turns of winding 绕组匝数 to optimize performance.

设计师指定了一个特定的绕组匝数 number of turns of winding 以优化性能。

2.The efficiency of the transformer is affected by the number of turns of winding 绕组匝数 used in its design.

变压器的效率受到其设计中使用的绕组匝数 number of turns of winding 的影响。

3.In an electric motor, the number of turns of winding 绕组匝数 determines the strength of the magnetic field.

在电动机中，绕组匝数 number of turns of winding 决定了磁场的强度。

4.Adjusting the number of turns of winding 绕组匝数 can help fine-tune the frequency response of the circuit.

调整绕组匝数 number of turns of winding 可以帮助微调电路的频率响应。

5.To increase the voltage output, you can increase the number of turns of winding 绕组匝数 on the secondary coil.

要增加电压输出，可以增加次级线圈的绕组匝数 number of turns of winding。

作文

The design and functionality of electrical devices often rely on various technical specifications, one of which is the number of turns of winding. This term refers to the total count of wire loops that are coiled around a core in an electromagnetic device, such as a transformer or an electric motor. Understanding the number of turns of winding is crucial because it directly influences the performance and efficiency of these devices. For instance, in a transformer, the ratio of the number of turns of winding between the primary and secondary coils determines the voltage transformation. A higher number of turns of winding on the primary side compared to the secondary side will result in a step-down transformer, while the opposite will create a step-up transformer.Moreover, the number of turns of winding can affect the inductance of a coil. Inductance is a property that quantifies the ability of a coil to store energy in a magnetic field when current flows through it. The relationship is straightforward: as the number of turns of winding increases, the inductance also increases, leading to greater energy storage capabilities. This characteristic is particularly important in applications such as radio frequency circuits and power supply systems, where managing energy flow is essential.In addition to its effects on voltage and inductance, the number of turns of winding also plays a role in determining the resistance of the winding itself. Each loop of wire adds to the overall length of the conductor, which in turn increases the resistance. Therefore, engineers must carefully balance the number of turns of winding with the desired electrical characteristics to optimize performance without incurring excessive energy losses due to resistance.Furthermore, the material used for the winding can influence how the number of turns of winding impacts the device's efficiency. Copper is commonly used due to its excellent conductivity, but other materials like aluminum may be chosen for cost-effectiveness despite having higher resistance. The choice of material, combined with the number of turns of winding, affects the heat generated during operation, which is a critical factor in the design of any electrical device. Excessive heat can lead to failure or reduced lifespan, making it imperative to calculate the optimal number of turns of winding based on the specific application requirements.Ultimately, understanding the number of turns of winding is essential for anyone involved in the design or maintenance of electrical devices. It is a fundamental aspect that engineers must consider when developing efficient and reliable products. By mastering this concept, one can ensure that devices operate within their intended parameters, providing the necessary power and functionality while minimizing waste and potential hazards. In conclusion, the number of turns of winding is not just a mere specification; it is a vital component that underpins the effectiveness of many electrical systems, influencing everything from performance to safety.

电气设备的设计和功能往往依赖于各种技术规格，其中之一就是绕组匝数。这个术语指的是在电磁设备（如变压器或电动机）中绕在核心上的电线圈的总圈数。理解绕组匝数至关重要，因为它直接影响这些设备的性能和效率。例如，在变压器中，初级和次级绕组的绕组匝数比率决定了电压转换。初级侧的绕组匝数高于次级侧将导致降压变压器，而反之则会产生升压变压器。此外，绕组匝数还会影响线圈的电感。电感是一个特性，量化了当电流通过线圈时，线圈在磁场中存储能量的能力。这个关系很简单：随着绕组匝数的增加，电感也会增加，从而导致更大的能量存储能力。这个特性在射频电路和电源系统等应用中尤为重要，这些地方需要管理能量流动。除了对电压和电感的影响外，绕组匝数还会影响绕组本身的电阻。每一圈电线都会增加导体的总长度，从而增加电阻。因此，工程师必须仔细平衡绕组匝数与所需的电气特性，以优化性能而不产生过多的因电阻造成的能量损失。此外，绕组使用的材料也会影响绕组匝数如何影响设备的效率。由于其优良的导电性，铜通常被使用，但铝等其他材料可能因成本效益而被选择，尽管其电阻较高。材料的选择结合绕组匝数，影响设备在运行过程中产生的热量，这是任何电气设备设计中的关键因素。过多的热量可能导致故障或缩短使用寿命，因此必须根据具体应用要求计算最佳的绕组匝数。最终，理解绕组匝数对于任何参与电气设备设计或维护的人来说都是至关重要的。这是工程师在开发高效可靠产品时必须考虑的基本方面。通过掌握这一概念，可以确保设备在预期参数内运行，提供必要的功率和功能，同时最小化浪费和潜在风险。总之，绕组匝数不仅仅是一个简单的规格；它是许多电气系统有效性的基础，影响从性能到安全的方方面面。