基于LDC1614的磁浮电涡流位移传感器设计
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摘要
为精确控制悬浮的高度,采用新型数字式非接触电感传感器LDC1614检测悬浮的间隙。LDC1614是具有内部集成电路(IIC)接口的4通道、28 bits的数字式电感传感器,采用4个自制的电感线圈,均匀分布在同一条直线上,检测4个通道的数字量并查表得到对应的悬浮间隙,在软件中加入数值有效判断,可以保证过轨缝时不会出现间隙值无穷大的情况。同时电路中加入温度传感器,实现对温度的补偿,并采用重复性校准的方法,使得数字电涡流传感器的重复性和精度达到要求。
In order to accurately control the height of the suspension,a novel digital non-contact inductance sensor LDC1614 is adopted to detect the suspension clearance. LDC1614 is a four-channel,28 bits digital inductance sensor with inter-integrated circuit(IIC) interface. Digital quantity of 4 channels is tested by the four self-made inductance coils,evenly distributed on the same straight line. And corresponding suspension clearance is obtained by table look-up. It can ensure the rail gap will not appear infinite gap situation by adding numerical judgments in the software. At the same time,a temperature sensor is added to the circuit to achieve temperature compensation,and a repetitive calibration method is used to make the repeatability and precision of digital eddy current sensor meet the requirements.
In order to accurately control the height of the suspension,a novel digital non-contact inductance sensor LDC1614 is adopted to detect the suspension clearance. LDC1614 is a four-channel,28 bits digital inductance sensor with inter-integrated circuit(IIC) interface. Digital quantity of 4 channels is tested by the four self-made inductance coils,evenly distributed on the same straight line. And corresponding suspension clearance is obtained by table look-up. It can ensure the rail gap will not appear infinite gap situation by adding numerical judgments in the software. At the same time,a temperature sensor is added to the circuit to achieve temperature compensation,and a repetitive calibration method is used to make the repeatability and precision of digital eddy current sensor meet the requirements.
引文
[1]贾民平.测试技术[M].北京:高等教育出版社,2009.
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[3]黄健,张善文.基于LDC1614的精密刻度盘设计[J].深圳大学学报:理工版,2017,34(2):188-194.
[4]张刘泽,吴峻.中低速磁悬浮列车电涡流间隙传感器设计[J].仪表技术与传感器,2010(1):1-3,17.
[5]ROJAS D,BARRETT J.A novel 3D embedded module for displacement measurement in metal structures[J].IEEE Transactions on Components Packaging&Manufacturing Technology,2017(99):1-9.
[6]张刘泽.磁浮列车间隙传感器模型分析与电路改进[D].长沙:国防科学技术大学,2009.
[7]樊树江,吴俊,杨光,等.电涡流传感器温度漂移分析及补偿实现[J].传感技术学报,2004(9):427-430.
[8]何飞,靖永志,张昆仑.基于Lab VIEW的磁浮车气隙传感器测试系统设计[J].传感器与微系统,2016,35(1):85-87.
[9]刘会森,张玉莲,董全林,等.电磁感应式位置传感器研究[J].传感器与微系统,2017,36(4):51-53,56.
[2]吴峻,李中秀.悬浮间隙传感器的电磁兼容设计[J].计算机测量与控制,2010,18(4):933-934,937.
[3]黄健,张善文.基于LDC1614的精密刻度盘设计[J].深圳大学学报:理工版,2017,34(2):188-194.
[4]张刘泽,吴峻.中低速磁悬浮列车电涡流间隙传感器设计[J].仪表技术与传感器,2010(1):1-3,17.
[5]ROJAS D,BARRETT J.A novel 3D embedded module for displacement measurement in metal structures[J].IEEE Transactions on Components Packaging&Manufacturing Technology,2017(99):1-9.
[6]张刘泽.磁浮列车间隙传感器模型分析与电路改进[D].长沙:国防科学技术大学,2009.
[7]樊树江,吴俊,杨光,等.电涡流传感器温度漂移分析及补偿实现[J].传感技术学报,2004(9):427-430.
[8]何飞,靖永志,张昆仑.基于Lab VIEW的磁浮车气隙传感器测试系统设计[J].传感器与微系统,2016,35(1):85-87.
[9]刘会森,张玉莲,董全林,等.电磁感应式位置传感器研究[J].传感器与微系统,2017,36(4):51-53,56.
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