电磁声换能器充磁装置参数的优化

IF 0.2 Q4 INSTRUMENTS & INSTRUMENTATION Devices and Methods of Measurements Pub Date : 2023-08-09 DOI:10.21122/2220-9506-2023-14-2-81-95
V. A. Strizhak, A. V. Pryakhin
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引用次数: 0

摘要

与接触式换能器相比,非接触式电磁声换能器具有一系列显著的优点,但与此同时,它们也有显著的缺点,需要开发有效的磁化装置。与使用永磁体的磁化装置相比,电流磁化装置很容易从测试对象上移除并清除金属颗粒的污染。不幸的是,这种换能器具有显著的尺寸和重量。研制了一种换能器,该换能器包含由电流线圈磁化的磁路和位于磁路中心部分与被测对象之间空隙中的两个独立的电磁电感器。电感器是两个扁平线圈,每个线圈的形状都像蝴蝶。位于工作区内的电感导体具有相互垂直的方向;它们允许激发和接收横向极化声波而无需重新排列换能器。为了减小换能器的整体尺寸和质量,在主动测量阶段对被测对象进行磁化时,对磁化装置的质量和尺寸参数进行了优化。在被动测量阶段(时间是主动测量阶段的三倍),磁化装置冷却下来。主动和被动相位交替的循环模式使换能器的重量减轻了3倍以上。在尺寸为15×15 mm的换能器的工作区域,磁场集中器与测试对象之间的间隙为1 mm,创建一个法向分量为2.4 T的场。换能器具有防止磁化装置过热的保护,循环操作模式允许在20°C的环境温度下每分钟连续进行多达30次测量。所研制的磁化装置可以在精确测量弹性波在被测物体中的传播时间的基础上,用于解决电磁声法的结构检查、测厚、探伤等一系列问题。
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Optimization of the Parameters of the Magnetizing Device of the Electromagnetic-Acoustic Transducer
Contactless electromagnetic-acoustic transducers have a set of significant advantages over contact transducers, but at the same time they have significant disadvantages that require the development of effective magnetizing devices. Compared to magnetizing devices that are using permanent magnets, electric current magnetization devices are easily removed from the object of testing and cleaned from contamination by metal particles. Unfortunately, such transducers have significant dimensions and weight.A transducer containing a magnetic circuit magnetized by an electric current coil and two independent electromagnetic inductors located in the gap between the central part of the magnetic circuit and the object of testing has been developed. Inductors are two flat coils, each of them has form like a butterfly. The inductor conductors located in the working area have mutually perpendicular directions; they allow exciting and receiving the transversely polarized acoustic waves without rearranging the transducer. In order to reduce the overall dimensions and mass of the transducer, the mass and dimensional parameters of the magnetizing device were optimized for operating conditions when the magnetization of the object of testing and measurement are performed during the active measurement phase. During the passive measurement phase, which is three times longer than the active phase in time, the magnetizing device cools down. The cyclic mode with alternating active and passive phases made it possible to reduce the weight of the transducer by more than 3 times. In the working area of the transducer with a size of 15×15 mm, with a gap of 1 mm between the magnetic field concentrator and the object of testing, a field with a normal component of 2.4 T is created. The transducer has protection of the magnetization device from overheating, and the cyclic mode of operation allows for continuous performance of up to 30 measurements per minute at an ambient temperature of 20 °C.The developed magnetizing device can be used in solving a number of problems of structuroscopy, thickness measurement, flaw detection by electromagnetic-acoustic methods based on accurate measurement of the propagation time of elastic waves in the object of testing. 
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来源期刊
Devices and Methods of Measurements
Devices and Methods of Measurements INSTRUMENTS & INSTRUMENTATION-
自引率
25.00%
发文量
18
审稿时长
8 weeks
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