CN204576263U - For the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring - Google Patents

For the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring Download PDF

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Publication number
CN204576263U
CN204576263U CN201520245772.1U CN201520245772U CN204576263U CN 204576263 U CN204576263 U CN 204576263U CN 201520245772 U CN201520245772 U CN 201520245772U CN 204576263 U CN204576263 U CN 204576263U
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China
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main body
small
climbing robot
nuclear power
monitoring
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Expired - Fee Related
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CN201520245772.1U
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徐文福
关达
黄志雄
王洪涛
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Shenzhen Graduate School Harbin Institute of Technology
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Shenzhen Graduate School Harbin Institute of Technology
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Abstract

A kind of small-sized wall-climbing robot for the monitoring of nuclear power plant containment shell environment comprises two legs foot (10) and first main body (20) of being set up by these two legs foot (10) and the second main body (30), this small-sized wall-climbing robot also comprises the first driving mechanism (40) controlling leg bar portion (11) and horizontally rotate, for controlling second driving mechanism (50) of the first main body (20) and the second main body (30) to four-wheel drive mechanism (70), comprise probe portion (80) and control part (90) further.Small-sized wall-climbing robot in the utility model carries multiple sensor, can carry out omnibearing detection; Integrated level is high, and mechanism is compact, adopts wireless+wired mode during operated from a distance, overcomes the shielding of containment to the communication information.

Description

For the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring
Technical field
The utility model relates to Robotics, particularly for carrying out the small scale robot of environmental monitoring in nuclear power plant containment shell.
Background technology
Since First nuclear power generating sets run, the whole world there occurs repeatedly nuclear accident, the Chernobyl accident having USSR (Union of Soviet Socialist Republics) in 1986 of especially severe, and the Fukushima nuclear accident of Japan in 2011, all cause earth shaking casualties and property loss, cause the mankind worried for the height of nuclear safety.According to the principle of " preventing trouble before it happens ", the monitoring of nuclear power station and early warning are most important rings in nuclear plant safety, particularly current, a lot of nuclear power station after running for a long time, equipment aging, wear problem is more and more serious.
According to the principle of depth defense, current nuclear power station is provided with four road barriers between nuclear fuel and extraneous air, and it is also last one barrier that containment is the 4th road, as shown in Figure 1.Once pressure vessel and pipeline run-down, radiomaterial will be inclusive in containment, be unlikely to leak outside.By the ambient condition in monitoring containment, comprise radiation dose, density of hydrogen, smog, density of hydrogen, temperature, humidity, air pressure, the safe condition of nuclear power station can be known, when an accident occurs, can tackle early, avoid causing tremendous influence.
Utilize robot to replace people to enter nuclear power station and carry out safety monitoring and early warning, have following benefit: (1) pinpoints the problems early, wins emergency repair time, the sufficient time at least can be had to turn off nuclear reactor, alleviate the consequence that accident produces as far as possible; (2) greatly reduce a staff suffered nuclear radiation, ensures personal security; (3) utilize monitoring robot to carry the equipment of video surveillance camera or other advanced persons, can the most direct monitoring result be provided, compared with the result obtained with indirect monitoring means (as by temperature, humidity, radiant quantity etc.), more intuitively, accurately.
Current nuclear industrial robot is mainly used in ongoing operations, comprises steam generator, the inspection of reactor vessel, installation, maintenance, and the sealing up for safekeeping, bury or dismantle, the operations such as Radwastes treatment of retired reactor; Partial robotic can be used for nuclear accident process and rescue etc., namely utilizes wheeled, caterpillar mobile robot, carries operating equipment, enter the scene of the accident, carries out accident treatment and rescue related work.And the research of monitoring robot relatively lags behind.More typically Spain's development can be used for detect column shape container (as steam generator) and the climbing robot Robicen of large-diameter pipeline, have at present 3 generation product.Robicen robot provides absorption affinity by the vacuum cup that 4 can adapt to curved wall, synchronous or asynchronous flexible by two cylinders on body, complete straight line and turning motion (the Briones L of robot, Bustamante P, Serna M A. Robicen:A Wall-Climbing Pneumatic Robot for Inspection in Nuclear Power Plants [J]. Robotics and Computer-Integrated Manufacturing. 1994,11 (4): 287-292.).This research team still further developed the small autonomous robot MonoCaRob checked for boiling water reactor dry wall, this robot is along specific placement in the guide rail movement of pipeline enclosure, the video camera that carries and other sensors are utilized to carry out routine examination (Savall J, Avello A, Briones L. Two Compact Robots for Remote Inspection of Hazardous Areas in Nuclear Power Plants [C]. IEEE International Conference on Robotics and Automation, Detroit, MI, USA, 1999:1993-1998.).Nuclear electric company of Britain employs remote crawl trolley Nero (the Luk B L of two types the nineties in 20th century on Magnox nuclear power plant reactor pressure vessel, Collie A A, White T. NERO:A Teloperated Wall Climbing Vehicle for Assisting Inspection of a Nuclear Reactor Pressure Vessel [C]. ASME International Computers Engineering Conference, 1993.).The people such as Choi devise robot (the Choi C monitored the feedwater piping of steam generator, Park B, Jung S. The Design and Analysis of a Feeder Pipe Inspection Robot With an Automatic Pipe Tracking System [J]. IEEE/ASME Transactions on Mechatronics. 2010,15 (5): 736-745). in existing document, not yet find the robot system of carrying out complete detection for nuclear power plant containment shell environment.
Patented claim aspect, application number be 2012101719639 patent propose a kind of nuclear power station robot localization method based on nuclear radiation, adopted robot transposition is not discussed; Application number is 2014102136542 patent discloses and a kind ofly carry out for nuclear power station steam generator secondary side the method that the climbing robot of cleanliness detection and people thereof detect nuclear power station steam generator secondary side, this robot is adsorbed on the cylinder inboard wall of nuclear power station steam generator secondary side, do not possess the ability that wall is climbed on the multiple difformity surface of simultaneous adaptation, the ability of particularly not transition between coplanar.
Prior art does not have special robot system of carrying out complete detection for nuclear power plant containment shell environment, the robot for nuclear power station inside in the past also mainly adopts the mode of wired connection, process operation, limits locomitivity and the monitoring range of robot.
Utility model content
The utility model disclose a kind ofly to carry out in real time for nuclear radiation in nuclear power plant containment shell, density of hydrogen, air pressure, temperature, humidity, the climbing robot of dynamic monitoring, on surface by distinct device in containment, and climb between different surfaces, realize the environmental monitoring of regional area and global area, solve the technical matters that in prior art, locomitivity is not strong and monitoring range is limited.
The utility model is solve the problems of the technologies described above design this to comprise for nuclear power plant containment shell environment monitoring small-sized wall-climbing robot two legs landed and be enough to and first main body of being set up by this two legs foot and the second main body, described first main body and the second main body are hinged with the top of two leg foots respectively, be articulated and connected between first main body and the second main body, described two legs foot includes leg bar portion, foot end and be arranged at foot end adsorption section, this small-sized wall-climbing robot also comprises and being arranged between leg bar portion and sufficient end for controlling the first driving mechanism that leg bar portion horizontally rotates, be arranged between a supporting leg foot top and the first main body for controlling the second driving mechanism of the first main body luffing, be arranged at the 3rd driving mechanism that controls the first main body or the second main body luffing between the first main body and the second main body and be arranged at the four-wheel drive mechanism controlling the second main body luffing between an other supporting leg foot top and the second main body, this small-sized wall-climbing robot also comprises further and is arranged at the first main body, probe portion on second main body or two legs foot and the control part of control each portion work.Described first driving mechanism, the second driving mechanism, the 3rd driving mechanism and four-wheel drive mechanism are the steering wheel directly controlling corresponding joint, and described adsorption section comprises the vacuum cup being arranged at foot end and the air pump connecting described vacuum cup.
The utility model improves further and is: described probe portion comprises environment conventional sense portion for detecting ambient environmental conditions, the accident early warning monitoring portion for early warning accident and the synkinesia probe portion for detecting obstacles thing.Described environment conventional sense portion comprises the temperature monitoring unit, humidity-monitoring unit and the visual monitoring unit that are connected to described control part; Described accident early warning monitoring portion comprises the fire monitoring unit, Leakage Gas monitoring means and the seismic monitoring unit that are connected to described control part; Described synkinesia probe portion comprises distance measuring unit, and described distance measuring unit is ultrasonic distance-measuring sensor.
The utility model further improves and is: described control part comprises main control unit, connects radio communication unit and the power module of this main control unit respectively, and described main control unit is Embedded controller.
Small-sized wall-climbing robot in the utility model carries multiple sensors such as radiation detection, harmful gas detection, smog, flame, air pressure, temperature, humidity, can carry out omnibearing detection to the environment in nuclear power station; Robot body possesses locomitivity, the two ends employing vacuum cup of 5DOF, can stablize, reliably be adsorbed on different surfaces, and can carry out climbing walking between different surfaces; Adopt modularization, integrated design method, make the integrated level of robot high, mechanism is compact, quality is light, volume is little; The mode that control system adopts host computer to combine with embedded Control, makes the operation of people be intended to meet with a response in robot quickly and efficiently; Wireless+wired mode is adopted during further utilization operated from a distance, overcome the shielding of containment to the communication information, make the operator outside containment can carry out controlling in real time, effectively to the robot in containment, this robot size is less than 240 mm × 98, mm × 140 mm, and quality is less than 1.4 kg; Creep speed is greater than 60 mm/s.
Accompanying drawing explanation
Fig. 1 is the utility model small-sized wall-climbing robot overall plan schematic diagram.Fig. 2 is the schematic perspective view of the utility model small-sized wall-climbing robot.Fig. 3 is each articulated way schematic diagram of the utility model small-sized wall-climbing robot.Fig. 4 is the schematic diagram of the utility model small-sized wall-climbing robot control part.Fig. 5 is the utility model upper and lower computer control mode schematic diagram.Fig. 6 is the schematic diagram that the utility model works in nuclear power plant containment shell.
Embodiment
Accompanying drawings specific embodiment of the utility model.
From in Fig. 1 to Fig. 5, the small-sized wall-climbing robot that the utility model is used for the monitoring of nuclear power plant containment shell environment comprises two the leg foots 10 landed and first main body 20 and second main body 30 of being set up by this two leg foots 10, described first main body 20 and the second main body 30 are hinged with the top of two leg foots 10 respectively, be articulated and connected between first main body 20 and the second main body 30, described two legs foot 10 includes leg bar portion 11, foot end 12 and be arranged at foot end adsorption section 13, described adsorption section 13 comprises the vacuum cup 131 being arranged at foot end and the air pump 132 connecting described vacuum cup 131, this small-sized wall-climbing robot also comprises and being arranged between leg bar portion 11 and sufficient end 12 for controlling the first driving mechanism 40 that leg bar portion 11 horizontally rotates, be arranged between supporting leg foot 10 tops and the first main body 20 for controlling the second driving mechanism 50 of the first main body 20 luffing, be arranged at the 3rd driving mechanism 60 that controls the first main body 20 or the second main body 30 luffing between the first main body 20 and the second main body 30 and be arranged at the four-wheel drive mechanism 70 controlling the second main body 30 luffing between other supporting leg foot 10 tops and the second main body 30, this small-sized wall-climbing robot also comprises further and is arranged at the first main body 20, probe portion 80 on second main body 30 or two legs foot 10 and the control part 90 of control each portion work, described first driving mechanism 40, second driving mechanism 50, the 3rd driving mechanism 60 and four-wheel drive mechanism 70 are the steering wheel directly controlling corresponding joint.
The target of power plant safety shell environment monitoring robot systematic study is the function that can realize at nuclear power station internal motion and monitoring nuclear power station internal environment.Be three subsystems according to function by nuclear power plant containment shell environment monitoring robot system divides: mechanical system, sensing and monitoring system, control system.These three subsystems are combined as a whole by interface, mutual cooperation.
Mechanical system is according to the requirement of robot to locomitivity, and adopt leg foot absorption type travel mechanism, body has 5 rotary joints, and each rotary joint is by servo driving, and body possesses 5DOF functipnal capability; Robot two ends are sucker, adopt wall strong adaptability and the large vacuum cup suction type of absorption affinity, realize climbing and walking by the absorption of sucker and surface of contact.First driving mechanism 40 described in the utility model controls the ankle-joint on two leg foots, second driving mechanism 50 and four-wheel drive mechanism 70 control the shoulder joint between leg foot and two main bodys, and the 3rd driving mechanism 60 then controls the middle joint between two main bodys.Above-mentioned configuration makes robot can realize the motions such as ground running, turning, obstacle detouring, multiaspect leap, mode of motion of the present utility model comprises crossing type and advances: adsorb ground (or wall or body surface) with leg foot, two are carried out 180 degree of upsets (middle joint can participate in upset or not participate in upset) shoulder joint (3 joints around Y-axis) cooperation, and realize convertible motion of advancing.Torsional mode is advanced: then a leg foot adsorbs ground, ankle-joint on ground terminal leg foot reverses, also reverse after another leg foot lands, ankle-joint is around 2 degree of freedom of Z axis, can alternating movement, drive machines human body is that torsional mode is advanced, and this mode movement velocity compared with crossing type is fast and stable, and required space is little.Normally advance: adsorb ground with a leg foot, two shoulder joint and middle joint luffing, drive machines human agent advance.Move back foot part sucker suction in relevant position, after absorption is stable, has carried out next step motion.In motion, with the movement of robot biped, the sucker alternating sorbent bottom biped, release.
Driving moment is of crucial importance for robot stabilized reliable movement, by analyzing the gait making joint driven torque maximum in motion process, carries out theory calculate and Adams emulation, to determine joint driven torque.Operating mode comprises: 1) one sucker suction ground during walking, and leg motion (shoulder joint torque analysis) is lifted by the second driving mechanism 50 and four-wheel drive mechanism 70; 2) sucker suction is in wall, and multi-joint coordinates flip-flop movement (shoulder joint torque analysis); 3) sucker suction is in wall, the first driving mechanism 40 twisting motion (torque of ankle analysis).Finally determine, during walking, ankle-joint need provide maximum moment to be 9.7 kgcm, and when crossing, ankle-joint need provide maximum moment to be 10 kgcm, and on wall, during twisting motion, ankle-joint need provide maximum moment to be 10.2 kgcm.Therefore, maximum moment demand in joint is 10.2 kgcm.Consider to select after surplus nominal torque to be the steering wheel of 17 kgcm.
Described probe portion 80 comprises environment conventional sense portion 81 for detecting ambient environmental conditions, for the accident early warning monitoring portion 82 of early warning accident and the synkinesia probe portion 83 for detecting obstacles thing.Described environment conventional sense portion 81 comprises the temperature monitoring unit, humidity-monitoring unit and the visual monitoring unit that are connected to described control part 90; Described accident early warning monitoring portion 82 comprises the fire monitoring unit, Leakage Gas monitoring means and the seismic monitoring unit that are connected to described control part 90; Described synkinesia probe portion 83 comprises distance measuring unit, and described distance measuring unit is ultrasonic distance-measuring sensor.The function of sensor-based system mainly comprises three aspects: the routine monitoring of (1) nuclear power plant environment.Routine monitoring mainly comprises inner temperature, humidity, vision; (2) nuclear power station emergency situations early warning.Emergency situations comprises fire, earthquake and harmful gas leakage etc.; (3) motion control of robot, arranges ultrasonic distance-measuring sensor at the shoulder of robot, can the distance of robot measurement distance preceding object thing, for motion control provides foundation.Therefore, in hardware system, corresponding sensor and camera is configured with.Sensing system hardware aspect comprises Temperature Humidity Sensor, shock sensor, flame sensor, harmful gas sensor etc. for the monitoring to surrounding environment, wherein Temperature Humidity Sensor is analog sensor, the temperature of real-time display environment and humidity, shock sensor, flame sensor, harmful gas sensor are digital sensors, the timely early warning when the inner breaking out of fire of nuclear power station, earthquake or harmful gas are revealed.
Described control part 90 comprises main control unit 91, connects radio communication unit 92 and the power module 93 of this main control unit 91 respectively, and described main control unit 91 is Embedded controller.Control system is the nerve center of robot, selects to adopt the control system of two-stage master-slave mode to realize Long-distance Control.Namely adopt master and slave two stages for the treatment of device to realize whole controlling functions of system, principal and subordinate's two-stage adopts wireless mode communication.
Nuclear power plant containment shell environment monitoring robot works in nuclear power station inside, and operating personnel are controlled by tele-control system, and tele-control system is primarily of host computer and remote control table and slave computer and embedded control platform two part composition.Wherein host computer is common PC, comprises man-machine interface and operating terminal, is responsible for the setting of motion control parameter, the selection of mode of motion, the control, the display of nuclear power plant environment Contents for Monitoring etc. of motion.Slave computer is embedded control system (control part 90), be connected with motion and sensor-based system, be responsible for receiving control command, parameter that host computer sends, and realize respective operations, simultaneously the environmental information of receiving sensor feedback and the motion state of robot send to host computer.Formed wireless interconnected between host computer and slave computer by wireless communication module.
Containment can resist the shock of the external force such as earthquake, wind spout and jet plane impact.The nearly 100cm of wall thickness constructed by containment vessel prestressed reinforced concrete, and inside surface is added with the steel lining of 0.6cm, can resist, from the inner or extraneous thing that flies out, to prevent radiomaterial entered environment.So thick containment, shielding action for radio communication is very huge, radio communication outside containment and in containment is almost isolated, in the state of the art, remote operating mode based on radio communication is feasible hardly, therefore, the utility model adopts wired+wireless communication system (as shown in Figure 6), namely radio communication route device is installed in containment, equipment in containment can adopt radio communication, and this equipment adopts wired form to be connected to outside containment, with the powerful screening ability overcome due to containment, Wireless Telecom Equipment cannot normally be worked.
Above content is in conjunction with concrete preferred implementation further detailed description of the utility model, can not assert that concrete enforcement of the present utility model is confined to these explanations.For the utility model person of an ordinary skill in the technical field, without departing from the concept of the premise utility, some simple deduction or replace can also be made, all should be considered as belonging to protection domain of the present utility model.

Claims (10)

1. the small-sized wall-climbing robot for the monitoring of nuclear power plant containment shell environment, it is characterized in that: this small-sized wall-climbing robot comprises two legs foot (10) landed and first main body (20) of being set up by these two legs foot (10) and the second main body (30), described first main body (20) and the second main body (30) are hinged with the top of two legs foot (10) respectively, be articulated and connected between first main body (20) and the second main body (30), described two legs foot (10) include leg bar portion (11), foot end (12) and be arranged at foot end adsorption section (13), this small-sized wall-climbing robot also comprises and being arranged between leg bar portion (11) and sufficient end (12) for controlling the first driving mechanism (40) that leg bar portion (11) horizontally rotates, be arranged between supporting leg foot (10) top and the first main body (20) for controlling second driving mechanism (50) of the first main body (20) luffing, be arranged at the 3rd driving mechanism (60) that controls the first main body (20) or the second main body (30) luffing between the first main body (20) and the second main body (30) and be arranged at the four-wheel drive mechanism (70) controlling the second main body (30) luffing between other supporting leg foot (10) top and the second main body (30), this small-sized wall-climbing robot also comprises further and is arranged at the first main body (20), probe portion (80) on second main body (30) or two legs foot (10) and the control part (90) of control each portion work.
2. according to claim 1 for the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring, it is characterized in that: described adsorption section (13) comprise the vacuum cup (131) being arranged at foot end and the air pump (132) connecting described vacuum cup (131).
3. according to claim 1 for the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring, it is characterized in that: described probe portion (80) comprises environment conventional sense portion (81) for detecting ambient environmental conditions, the accident early warning monitoring portion (82) for early warning accident and the synkinesia probe portion (83) for detecting obstacles thing.
4., according to claim 3 for the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring, it is characterized in that: described environment conventional sense portion (81) comprises the temperature monitoring unit, humidity-monitoring unit and the visual monitoring unit that are connected to described control part (90).
5., according to claim 3 for the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring, it is characterized in that: described accident early warning monitoring portion (82) comprises the fire monitoring unit, Leakage Gas monitoring means and the seismic monitoring unit that are connected to described control part (90).
6., according to claim 3 for the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring, it is characterized in that: described synkinesia probe portion (83) comprises distance measuring unit.
7., according to claim 6 for the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring, it is characterized in that: described distance measuring unit is ultrasonic distance-measuring sensor.
8. according to any one of claim 1 to 7 for nuclear power plant containment shell environment monitoring small-sized wall-climbing robot, it is characterized in that: described control part (90) comprises main control unit (91), connect radio communication unit (92) and the power module (93) of this main control unit (91) respectively.
9., according to claim 8 for the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring, it is characterized in that: described main control unit (91) is Embedded controller.
10. according to any one of claim 1 to 7 for the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring, it is characterized in that: described first driving mechanism (40), the second driving mechanism (50), the 3rd driving mechanism (60) and four-wheel drive mechanism (70) are the steering wheel directly controlling corresponding joint.
CN201520245772.1U 2015-04-22 2015-04-22 For the small-sized wall-climbing robot of nuclear power plant containment shell environment monitoring Expired - Fee Related CN204576263U (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104777840A (en) * 2015-04-22 2015-07-15 哈尔滨工业大学深圳研究生院 Small-size wall-climbing robot applied to monitoring internal environment of nuclear power station containment
CN105158654A (en) * 2015-08-24 2015-12-16 大连世有电力科技有限公司 Intelligent robot for partial discharge diagnosis of transformer
CN106826831A (en) * 2017-02-27 2017-06-13 武汉科技大学 Detect the walking robot control system and control method of steel construction wall
CN108646612A (en) * 2018-03-20 2018-10-12 中国核电工程有限公司 A kind of N-16 monitors data acquisition process platform
CN111301546A (en) * 2019-11-22 2020-06-19 广东省智能制造研究所 Control system and control method of wall-climbing robot
CN112326072A (en) * 2021-01-04 2021-02-05 成都威尔森科技发展有限责任公司 Stress detection device

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104777840A (en) * 2015-04-22 2015-07-15 哈尔滨工业大学深圳研究生院 Small-size wall-climbing robot applied to monitoring internal environment of nuclear power station containment
CN105158654A (en) * 2015-08-24 2015-12-16 大连世有电力科技有限公司 Intelligent robot for partial discharge diagnosis of transformer
CN105158654B (en) * 2015-08-24 2017-09-26 大连世有电力科技有限公司 The intelligent robot diagnosed for partial discharge of transformer
CN106826831A (en) * 2017-02-27 2017-06-13 武汉科技大学 Detect the walking robot control system and control method of steel construction wall
CN108646612A (en) * 2018-03-20 2018-10-12 中国核电工程有限公司 A kind of N-16 monitors data acquisition process platform
CN111301546A (en) * 2019-11-22 2020-06-19 广东省智能制造研究所 Control system and control method of wall-climbing robot
CN111301546B (en) * 2019-11-22 2023-11-21 广东省智能制造研究所 Control system and control method of wall climbing robot
CN112326072A (en) * 2021-01-04 2021-02-05 成都威尔森科技发展有限责任公司 Stress detection device

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