piezoceramic material
简明释义
压电陶瓷材料
英英释义
例句
1.In medical ultrasound machines, 压电陶瓷材料 is crucial for generating and receiving sound waves.
在医学超声波机器中,压电陶瓷材料对于生成和接收声波至关重要。
2.The sensors in this device utilize 压电陶瓷材料 to convert mechanical stress into electrical signals.
该设备中的传感器利用压电陶瓷材料将机械应力转化为电信号。
3.Researchers are exploring the use of 压电陶瓷材料 in energy harvesting applications.
研究人员正在探索在能量收集应用中使用压电陶瓷材料。
4.The durability of 压电陶瓷材料 makes it ideal for industrial sensors.
由于耐用性,压电陶瓷材料使其非常适合工业传感器。
5.The new actuator design incorporates 压电陶瓷材料 for improved responsiveness.
新的执行器设计采用了压电陶瓷材料以提高响应速度。
作文
In the field of materials science, the term piezoceramic material refers to a category of ceramics that exhibit piezoelectric properties. These materials have the unique ability to generate an electric charge in response to mechanical stress. This phenomenon makes piezoceramic materials incredibly valuable in various applications, particularly in sensors and actuators. For example, when pressure is applied to a piezoceramic material, it produces a voltage that can be measured and utilized in electronic devices. One of the most common uses of piezoceramic materials is in ultrasonic transducers, which are widely employed in medical imaging techniques such as ultrasound. The piezoceramic material converts electrical energy into ultrasonic waves, allowing for the visualization of internal body structures. This application has revolutionized medical diagnostics, providing a non-invasive method for examining patients. Moreover, piezoceramic materials are also crucial in the development of actuators, which are devices that convert electrical energy into mechanical motion. In robotics, for instance, piezoceramic materials can be used to create precise movements due to their ability to deform under an electric field. This precision is essential in applications ranging from industrial automation to advanced prosthetics, where accurate control is vital. The versatility of piezoceramic materials extends beyond medical and robotic applications. They are also found in consumer electronics, such as microphones and speakers. In microphones, piezoceramic materials convert sound waves into electrical signals, enabling clear audio capture. In speakers, they perform the opposite function, converting electrical signals back into sound waves. This dual functionality showcases the significant role of piezoceramic materials in enhancing our everyday technology. Research into piezoceramic materials continues to advance, with scientists exploring new compositions and structures to improve their performance. Innovations in this field could lead to even more efficient energy conversion and greater sensitivity in sensors. Furthermore, the integration of piezoceramic materials with other technologies, such as nanotechnology, may yield groundbreaking applications that we have yet to imagine. In conclusion, piezoceramic materials are integral to numerous technological advancements due to their piezoelectric properties. Their ability to convert mechanical energy into electrical energy and vice versa opens up a world of possibilities across various industries. As research progresses, the potential applications of piezoceramic materials will likely expand, solidifying their importance in the future of technology and innovation.
在材料科学领域,术语压电陶瓷材料指的是一种具有压电特性的陶瓷类别。这些材料具有在机械应力作用下产生电荷的独特能力。这种现象使得压电陶瓷材料在各种应用中极具价值,特别是在传感器和执行器中。例如,当施加压力于压电陶瓷材料时,它会产生一个可以被测量并用于电子设备的电压。压电陶瓷材料最常见的用途之一是超声波传感器,这在医学成像技术如超声中得到广泛应用。压电陶瓷材料将电能转换为超声波,使内部身体结构的可视化成为可能。这一应用彻底改变了医学诊断,提供了一种非侵入性的方法来检查患者。此外,压电陶瓷材料在执行器的发展中也至关重要,执行器是将电能转换为机械运动的设备。例如,在机器人技术中,压电陶瓷材料可以用来创造精确的运动,因为它们能够在电场下变形。这种精确性在工业自动化到先进假肢等应用中至关重要,其中准确控制至关重要。压电陶瓷材料的多功能性不仅限于医疗和机器人应用。它们还出现在消费电子产品中,如麦克风和扬声器。在麦克风中,压电陶瓷材料将声波转换为电信号,从而实现清晰的音频捕捉。在扬声器中,则执行相反的功能,将电信号转换回声波。这种双重功能展示了压电陶瓷材料在增强我们日常技术中的重要作用。对压电陶瓷材料的研究仍在不断推进,科学家们正在探索新的成分和结构以改善其性能。该领域的创新可能会导致更高效的能量转换和传感器的更高灵敏度。此外,压电陶瓷材料与其他技术(如纳米技术)的结合可能会产生我们尚未想象的突破性应用。总之,由于其压电特性,压电陶瓷材料在众多技术进步中至关重要。它们将机械能转换为电能及反之的能力为各个行业开辟了无限可能。随着研究的进展,压电陶瓷材料的潜在应用可能会扩展,巩固它们在未来技术和创新中的重要性。
