US 12,222,380 B2
Electromagnetic immunity test system and control method thereof
Zuguang Huang, Beijing (CN); Shuai Ji, Beijing (CN); Jinjiang Wang, Beijing (CN); Ruijuan Xue, Beijing (CN); Tianliang Hu, Beijing (CN); Hepeng Ni, Beijing (CN); and Chengrui Zhang, Beijing (CN)
Assigned to CHINA NATIONAL MACHINE TOOL QUALITY SUPERVISION TESTING CENTER, Beijing (CN); and SHANDONG JIANZHU UNIVERSITY, Jinan (CN)
Filed by China National Machine Tool Quality Supervision Testing Center, Beijing (CN); and Shandong Jianzhu University, Jinan (CN)
Filed on Jul. 4, 2022, as Appl. No. 17/857,167.
Application 17/857,167 is a continuation in part of application No. PCT/CN2021/112822, filed on Aug. 16, 2021.
Claims priority of application No. 202010881277.5 (CN), filed on Aug. 27, 2020.
Prior Publication US 2022/0334161 A1, Oct. 20, 2022
Int. Cl. G01R 29/08 (2006.01); G05B 19/401 (2006.01)
CPC G01R 29/0814 (2013.01) [G05B 19/401 (2013.01); G05B 2219/31034 (2013.01); G05B 2219/34024 (2013.01); G05B 2219/34242 (2013.01); G05B 2219/35316 (2013.01); G05B 2219/37045 (2013.01)] 6 Claims
OG exemplary drawing
 
1. An electromagnetic immunity test system for a numerical control system, the numerical control system comprising a numerical control machine tool comprising a sliding table, and the electromagnetic immunity test system comprising:
1) a data acquisition and control device;
2) a linear module;
3) an electromagnetic disturbance simulator; and
4) an upper computer;
wherein:
the data acquisition and control device is in a data connection to the linear module, the electromagnetic disturbance simulator, and the upper computer;
the linear module comprises a grating ruler; and the linear module is disposed on the numerical control machine tool to measure location data of the sliding table of the numerical control machine tool and transmit the location data to the data acquisition and control device;
the electromagnetic disturbance simulator is configured to generate and transmit an electromagnetic signal to the numerical control system;
the data acquisition and control device is configured to read the location data in real time and transfer the real-time location data to the upper computer; according to the real-time location data and a direction of movement of the grating ruler, the data acquisition and control device controls the electromagnetic disturbance simulator to generate and transmit the electromagnetic signal to the numerical control system;
the upper computer communicates with the data acquisition and control device and is configured to receive the real-time location data, compare data of location, speed, and acceleration of the linear module before and after being exposed to an electromagnetic disturbance, and quantitatively analyze the influence of the electromagnetic disturbance on the performance of the numerical control system through a preset test method;
the data acquisition and control device comprises a grating input interface, a real-time Ethernet interface, a digital output interface, and a field-programmable gate array (FPGA) chip; the FPGA chip is electrically connected to the grating input interface, the real-time Ethernet interface, and the digital output interface; the grating input interface is in a data connection to the grating ruler; the real-time Ethernet interface is in a network connection to the upper computer; and the digital output interface is connected to the electromagnetic disturbance simulator and triggers the electromagnetic disturbance simulator to generate the electromagnetic disturbance to interfere in the numerical control machine tool; and
the FPGA chip comprises an event trigger that triggers the digital output interface according to the real-time location data and the direction of the movement of the grating ruler to regulate an output level thus controlling the electromagnetic disturbance simulator to generate the electromagnetic disturbance to interfere in the numerical control machine tool.