CN112683553A - New energy automobile test system and test method - Google Patents

Abstract

The application discloses new energy automobile's test system and test method, wherein, this test system includes: the system comprises a remote control terminal and a test site, wherein the test site comprises a detection room, at least one test room and a travelling crane; the detection chamber includes: the system comprises at least one detection platform and a travelling crane, wherein the at least one detection platform is used for detecting one or more performances of a sample to be detected before an experiment, and the travelling crane is used for transporting the sample to be detected after detection in a detection chamber to a test chamber; any one of the laboratories includes: the test bench is used for performing one or more tests on the tested sample; and the remote control terminal is used for controlling the transportation path of the travelling crane and receiving the detection result and the test result.

Description

New energy automobile test system and test method

Technical Field

The application relates to the technical field of automobile tests, in particular to a test system and a test method for a new energy automobile.

Background

At present, in the electric drive development and test stage of a new energy automobile, the current situation of an automobile host factory and an electric drive component factory to a test room is still in the standard of a traditional automobile enterprise engine test room, and the traditional automobile enterprise engine test room needs a tester to physically locate the test room to install, test and disassemble a tested sample.

However, the operation of the tested sample in the laboratory at the position of the tester has two defects for the development and the test of the new energy electric drive:

one, extremely large hazard coefficient: the voltage of the electric drive input end of the new energy automobile is about 350V direct current power supply, development and testing are carried out at the stage that the product is not completed in function, and great electric shock risks exist in short-distance operation; in the testing stage of new energy components, the rotating speed of components such as a motor, a half shaft and a dynamometer is high, so that great danger exists; the test personnel easily collide, get an electric shock and other dangers in the process of installing and dismantling the tested sample.

Secondly, the test efficiency is low: when testing is carried out in a laboratory, testers are required to monitor the condition of the laboratory all the day, and labor waste exists; for disassembly and insulation and voltage resistance tests, multiple persons are required to perform cooperatively, and personal errors easily exist in test results; when a tested sample fails or testing equipment fails in the testing process, the test data is difficult to be fed back to a test engineer in time; the durable data processing is completely realized by screening important information by a tester, needs great manpower resources and has slow processing time.

Disclosure of Invention

The embodiment of the application aims to provide a new energy automobile testing system and a new energy automobile testing method, and the problems of large risk coefficient and low efficiency of an existing new energy automobile laboratory system can be solved.

In order to solve the above problems, the following technical solutions are adopted in the present application:

in a first aspect, the embodiment of the application discloses a test system of a new energy automobile, which comprises a remote control terminal and a test site, wherein the test site comprises a detection room, at least one test room and a traveling crane; the detection chamber comprises a first robot hand and at least one detection platform, wherein the at least one detection platform is used for detecting one or more performances of a sample piece to be detected before an experiment and transmitting detection result data to the remote control terminal; the first manipulator is used for fixing the detected sample to be detected on the travelling crane; the travelling crane is used for transporting the tested sample detected by the detection chamber to the test chamber; any one of the test rooms comprises a test bench and a second robot, wherein the second robot is used for placing the tested sample on the test bench; the test bench is used for executing one or more tests on the tested sample and transmitting test results to the remote control terminal; the second robot hand is also used for placing the tested sample on the travelling crane after the test; the travelling crane is also used for transporting the tested sample after the test to the next test room; the remote control terminal is used for sending a control instruction to the travelling crane to control the transportation path of the travelling crane and receive the detection result and the test result, and the remote control terminal is also used for controlling the first robot hand and the second robot hand to realize the action of the robot hands. .

In a second aspect, the embodiment of the application discloses a test method for a new energy automobile, wherein a detection chamber of a test system performs performance detection on a placed tested sample and transmits a detection result to a remote control terminal of the test system; the crane of the test system transports the tested sample after performance detection to a target test room, wherein the target test room is one of at least one test room of the test system; the target test room executes a corresponding target test on the tested sample and transmits a test result to the remote control terminal; the travelling crane transports the tested sample to the next target laboratory for testing; and the remote control terminal receives the detection result and the test result and generates a test report at least according to the detection result and the test result.

In a third aspect, an embodiment of the present application provides an electronic device, which includes a processor, a memory, and a program or instructions stored on the memory and executable on the processor, and when executed by the processor, the program or instructions implement the steps of the method according to the second aspect.

In a fourth aspect, the present application provides a computer-readable storage medium, on which a program or instructions are stored, which when executed by a processor implement the steps of the method according to the second aspect.

In a fifth aspect, the present application provides a chip, where the chip includes a processor and a communication interface, where the communication interface is coupled to the processor, and the processor is configured to execute a program or instructions to implement the method according to the second aspect.

The technical scheme adopted by the application can achieve the following beneficial effects:

the embodiment of the application discloses a test system and a test method of a new energy automobile, the test system comprises a remote control terminal and a test site, the remote control terminal performs operations such as detection and test on a tested sample through the remote control test site, and receives a detection result and a test result of the test site on the tested sample. The test site is controlled through the remote control terminal, and a test result is obtained, so that the problems of large risk coefficient and low efficiency of the existing new energy automobile laboratory system can be effectively solved.

Drawings

Fig. 1 is a schematic structural diagram of a test system of a new energy vehicle disclosed in an embodiment of the present application;

FIG. 2 is a schematic diagram of a configuration of a test site of the test system disclosed in the embodiments of the present application;

FIG. 3 is a schematic structural diagram of a remote control terminal of the testing system disclosed in the embodiment of the present application;

FIG. 4 is a schematic structural diagram of a remote control terminal of the testing system disclosed in the embodiment of the present application;

FIG. 5 is a schematic flow chart of the testing method disclosed in the embodiments of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some, but not all, embodiments of the present application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The terms first, second and the like in the description and in the claims of the present application are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application are capable of operation in sequences other than those illustrated or described herein. In addition, "and/or" in the specification and claims means at least one of connected objects, a character "/" generally means that a preceding and succeeding related objects are in an "or" relationship.

The test system of the new energy vehicle provided by the embodiment of the present application is described in detail below with reference to the accompanying drawings through specific embodiments and application scenarios thereof.

Fig. 1 is a schematic structural diagram of a testing system of a new energy vehicle, as shown in fig. 1, the testing system includes a remote control terminal 200 and a test site 100, the test site 100 includes a detection room 110, at least one test room 120 and a traveling crane 130, the detection room 110 includes a first robot arm 111 and at least one detection platform 112, and any one of the test rooms 120 includes a test bench 122 and a second robot arm 121.

In the embodiment of the present application, the detection chamber 110 includes a first robot arm 111 and at least one detection platform 112, wherein the detection platform 112 is configured to detect one or more properties of a sample to be detected before a test, and transmit detection result data to the remote control terminal 200, and the first robot arm 111 is configured to place the detected sample on the trolley 130; the trolley 130 is used for transporting the sample to be tested after being tested by the testing chamber 110 to a testing chamber 120. For example, a tester places a tested sample on the detection platform 112 of the detection chamber 110, the detection platform 112 detects the correlation performance of the tested sample before testing, after the tested sample is detected, the detection platform 112 transmits detection result data to the remote control terminal 200, and then the first robot 111 places the tested sample on the traveling crane 130 and transports the tested sample to a target test chamber where testing needs to be performed.

Any one of the test rooms 120 comprises a test bench 122 and a second robot 121, wherein the second robot 121 is used for placing a tested sample on the test bench 122, the test bench 122 is used for performing one or more tests on the tested sample and transmitting the test result to the remote control terminal 200, and the second robot 121 is also used for placing the tested sample on the travelling crane 130 after the test; the trolley 130 is also used to transport the tested sample after testing to the target test room. For example, after a sample to be tested detected in the detection chamber 110 is placed on the trolley 130 by the first robot 111, the trolley 130 transports the sample to be tested to one of the laboratories 120, the second robot 121 fixes the sample to be tested to the test rack 122, the test rack 122 performs one or more tests on the sample to be tested, after the tests are completed, the test result is transmitted to the remote control terminal 200, then the sample to be tested is placed on the trolley 130 by the second robot 121, and the trolley 130 transports the sample to be tested to the next laboratory 120.

In the embodiment of the present application, the remote control terminal 200 is configured to send a control instruction to the traveling crane 130 to control the transportation path of the traveling crane 130, and receive the detection result and the test result.

In a particular application, the first robot hand 111 and the second robot hand 121 may be used with simple tools via manual handles. For example, tightening or loosening bolts, attaching or detaching water pipes, knocking, pressing, and the like. In addition, simple measurement work can be performed by the manual handle, such as torque setting and measurement of the torque wrench, dimensional measurement, parallelism measurement, and the like. In addition, movement of the sample piece in three-dimensional spatial position within the laboratory 120 may also be accomplished by manual manipulation of the handle. In addition, the first robot arm 111 and the second robot arm 121 can feed back the current tool use state, the measured value and the state of the mobile sample to the data terminal in real time through the front-end cameras thereof. In addition, the first robot arm 111 and the second robot arm 121 can timely judge the safety of the test system through the alarm system, and can perform work such as fire protection, power switch and the like. The first robot hand 111 and the second robot hand 121 can also automatically perform corresponding operations through the intrinsic program set by the remote control terminal 200, without the need for a tester to perform real-time operations.

In the embodiment of the application, the test system of the new energy automobile controls the test site 100 through the remote control terminal 200 and receives corresponding data, so that the risk coefficient of the tester in the laboratory 120 for operating the tested sample is reduced, and the test efficiency is improved.

In one possible implementation, as shown in fig. 2, the lab further includes a dismantling chamber 140, where the dismantling chamber 140 includes a third robot 141 and at least one dismantling platform 142. The third robot 141 is controlled by the remote control terminal 200, and is configured to place the tested sample on the disassembling platform 142, and the disassembling platform 142 is configured to disassemble the tested sample after the test, inspect the state of the tested sample, and transmit an inspection result to the remote control terminal 200.

In a specific application, after a tested sample is tested in at least one testing room 120, a tester determines whether the tested sample needs to be disassembled according to specific conditions, if the tested sample needs to be disassembled, the traveling crane 130 transports the tested sample to the disassembling room 140 after the test, the third robot 141 places the tested sample on one of the disassembling platforms 142, the disassembling platform 142 disassembles the tested sample and checks the state of the disassembled tested sample, and the checking result is transmitted to the remote control terminal 200.

Further, as shown in fig. 2, the at least one laboratory 120 may be at least one of: a drag test room 1201, an electric drive assembly test room 1202, a triple-integrated vibration test room 1203, a high-speed motor test room 1204, a water channel pressure pulsation test room 1205, and a Power Thermal Cycle Endurance (PTCE) test room 1206.

The counter-dragging test room 1201 is internally provided with a counter-dragging rack 1221 for testing the motor performance of the tested sample; the electric drive assembly laboratory 1202 is provided with an electric drive assembly frame 1222 for testing the three-in-one performance of the motor, the motor controller and the speed reducer; a three-comprehensive vibration table 1223 is arranged in the three-comprehensive vibration test chamber 1203 and used for simulating the vibration of the tested sample under a certain temperature and humidity, namely the three-comprehensive vibration test chamber 1203 is a test chamber integrating the temperature, the humidity and the vibration; a high-speed motor rack 1224 is arranged in the high-speed motor laboratory 1204 and used for testing the performance of a tested sample motor under high-speed rotation; a water channel pressure pulsation stand is arranged in the water channel pressure pulsation laboratory 1205 and used for testing the fatigue performance of the water channel of the tested sample and testing whether water leakage occurs; a stator-rotor PTCE bench 1126 is arranged in the stator-rotor PTCE laboratory 1206 and used for simulating the adaptability of a tested sample under the impact of high current and high voltage for a long time. Specifically, after the detected sample is detected in the detection chamber 110, the first robot arm 111 places the detected sample on the traveling crane 130 according to specific needs, and the traveling crane 130 is controlled by the remote control terminal 200 to transport the detected sample to a target laboratory, that is, one of the laboratories 120 for testing.

In the above possible implementation manners, the at least one test room 120 may include not only the above test rooms, but also other test rooms, which are not illustrated here, and the present embodiment does not limit the specific test rooms and the number of test rooms.

In a possible implementation manner, the first robot 111 is provided with a first camera, the second robot 121 is provided with a second camera, the third robot 141 is provided with a third camera, and the first camera, the second camera, and the third camera are connected with the remote control terminal 200.

In the above possible implementation manner, the first camera, the second camera and the third camera are used for collecting image information of the test site 100 and transmitting the collected image information to the remote control terminal 200. Specifically, first camera, second camera and third camera can be the camera at 360 no dead angles. The first camera, the second camera and the third camera can monitor the detection chamber 110, the test chamber 120 and the disassembly chamber 140, and faults occurring in the detection, test and disassembly processes can be timely processed.

In one possible implementation, as shown in fig. 3, the remote control terminal 200 may include a gantry remote operation module 210 and a detection platform remote operation module 220, a disassembly platform remote operation module 230, and a robot remote operation module 240.

The rack remote operation module 210 is configured to display a first control interface of the test rack 122 of the laboratory 120, and transmit a control command input on the first control interface to the test rack 122 to control the test rack 122 to perform a test; the detection platform remote operation module 220 is configured to display a second control interface of the detection platform 112 of the detection chamber 110, and transmit a control instruction input on the second control interface to the detection platform 112, so as to control the detection platform 112 to detect the sample to be detected; the disassembling platform remote operation module 230 is configured to display a third control interface of the disassembling platform 142 of the disassembling chamber 140, and transmit a control instruction input on the third control interface to the disassembling platform 142, so as to control the disassembling platform 142 to disassemble the measured sample.

In a specific application, a tester controls the test site 100 at the remote control terminal 200, the first control interface of the test bed 122 of each test room 120 is projected to the bed remote operation module 210 through remote screen projection, the tester inputs a control instruction to the first control interface, and the bed remote operation module 210 transmits the control instruction to the test bed 122, so as to control the test bed 122 to perform a test; the second control interface of each detection platform 112 of the detection chamber 110 is projected to the detection platform remote operation module 220 through remote screen projection, a tester inputs a control instruction to the second control interface, and the detection platform remote operation module 220 transmits the control instruction to the corresponding detection platform 112, so that the detection platform 112 is controlled to detect the detected sample; the third control interfaces of the dismantling platforms 142 of the dismantling chamber 140 are projected to the dismantling platform remote operation module 230 through remote projection, a tester inputs a control instruction to the third control interfaces, and the dismantling platform remote operation module 230 transmits the control instruction to the corresponding dismantling platforms 142, so that the dismantling platforms 142 are controlled to dismantle the tested sample; the fourth control interface of the robot is projected to the robot remote operation module 240 through remote screen projection, the tester inputs a control instruction to the fourth control interface, and the robot remote operation module 240 transmits the control instruction to the first robot 111, the second robot 121, or the third robot 141 to control the first robot 111, the second robot 121, or the third robot 141 to perform corresponding operations.

In the embodiment of the present application, as shown in fig. 4, the remote control terminal 200 may further include a remote control module 250, and the remote control module 250 is configured to send a control instruction to the traveling crane 130 to control the transportation path of the traveling crane 130.

In an alternative scheme, the remote control module 250 may be further configured to send a fault message to a terminal of a tester when the test site 100 fails, where the failure of the test site 100 includes at least one of: the failure of the tested sample, the failure of the trolley 130, the failure of the test stand 122, the failure of the detection platform 112, and the failure of the disassembly platform 142.

Optionally, the terminal of the tester may be a mobile phone terminal or a computer terminal, and the remote control module 250 may feed back the fault information to the tester in the form of an email.

In a possible implementation manner, the remote control module 250 may also be configured to send alarm information to a terminal of a laboratory administrator when a dangerous condition occurs in the test site 100, and feed the alarm information back to the robot remote operation module 240; the robot remote operation module 240 may also be configured to send a control command to the first robot 111, the second robot 121, or the third robot 141 to command the first robot 111, the second robot 121, or the third robot 141 to perform a corresponding safety protection measure.

In a specific application, if the test site 100 has the situations of electric leakage, fire, smoke, water leakage, etc., the remote control module 250 may feed the alarm information back to the laboratory administrator in time through the terminal, and feed the alarm information back to the robot remote operation module 240, and the robot remote operation module 240 may instruct the first robot 111, the second robot 121, or the third robot 141 to perform corresponding safety protection measures.

In a possible implementation manner, the remote control terminal 200 further includes a data processing module 260, configured to receive the detection result, the test result, and the inspection result, and process the detection result, the test result, and the inspection result according to a predetermined processing manner to obtain a test data report. Specifically, the tester writes a test script, and the test data processes the data according to the script written by the tester and makes a specified data report.

In the above application embodiment, control test scene 100 through remote control terminal 200, on the one hand, the tester need not the low coverage to leave the operation high voltage electricity, high rotational speed is surveyed the sample piece, the life safety of tester has been guaranteed, on the other hand, the tester realizes the installation of being surveyed the sample piece through the robot is long-range fast, dismantle and disassemble, need not to come and go the operation rack between laboratory and office position, edit the test condition, only need realize the operation at remote control terminal, the office efficiency has been improved, the product development cycle has been practiced thrift, and the script automatic operation that test data processing edited through the tester, can shorten data processing time, the failure discovery rate is improved, can the most probable discovery problem in the product development process, greatly improved test efficiency.

The embodiment of the application also provides a test method of the new energy automobile, and the method can be applied to the test system of the new energy automobile in the embodiment.

Fig. 5 is a schematic flow chart of a testing method of a new energy vehicle according to an embodiment of the present application, and as shown in fig. 5, the testing method 500 mainly includes the following steps.

S510: and the detection chamber of the test system performs performance detection on the placed tested sample and transmits the detection result to the remote control terminal of the test system.

In a specific application, step S510 may be performed according to the detection chamber 110 shown in fig. 1 to fig. 2, and specific implementation manners may refer to the description of the above embodiment of the testing system, which is not described herein again.

S520: and the running crane of the test system transmits the tested sample with the performance detected to a target test room.

In a specific application, step S520 may be performed according to the traveling crane 130 shown in fig. 1 to fig. 2, and specific implementation manners may refer to the description of the above test system embodiment, which is not described herein again.

S530: the target test room executes a corresponding target test on the tested sample and transmits a test result to the remote control terminal;

in a specific application, step S530 is performed according to the laboratory 120 shown in fig. 1 to fig. 2, and specific implementation manners may refer to the description of the above-mentioned embodiment of the testing system, which is not described herein again.

S540: and the travelling crane transports the tested sample to the next target laboratory for testing.

In the embodiment of the present application, the traveling crane 130 may automatically transmit the measured sample to the next target laboratory according to a preset program, or may transmit the measured sample to the next target laboratory after receiving a control instruction sent by the remote control terminal 200. That is, in the present application, the test flow may be a fully automatic flow or a semi-automatic flow.

Similarly, other steps in the present application may be fully automatic or semi-automatic, and are not described in detail to avoid repetition.

In one implementation, after the test is performed on the tested sample, the tester determines whether the tested sample needs to be disassembled to check the state of the tested sample according to specific needs, if so, the second robot 121 places the tested sample on the traveling crane 130, the traveling crane 130 transports the tested sample to the disassembling chamber 140, the third robot 141 places the tested sample on the disassembling platform 142, the disassembling platform 142 disassembles the tested sample, checks the state of the disassembled tested sample, and transmits the checking result to the remote control terminal 200.

In a specific application, step S540 may be performed according to the traveling crane 130 shown in fig. 1 to fig. 2, and specific implementation manners may refer to the description of the above test system embodiment, which is not described herein again.

S550: and the remote control terminal 200 receives the detection result and the test result and generates a test report according to the detection result and the test result.

In this step, if the sample to be measured is disassembled and inspected in the previous step, the remote control terminal 200 further needs to receive the inspection result and generate an experiment report on the inspection result.

In a specific application, step S550 may be executed according to the remote control terminal 200 shown in fig. 1 to fig. 2, and specific implementation may refer to the description of the above test system embodiment, which is not described herein again.

In the above possible implementation manner, the target laboratory may be one of the at least one laboratory 120 of the testing system, and may also be other laboratories not mentioned in the embodiment of the present application.

The embodiment of the application provides a new energy automobile's test method, through remote control terminal 200 control test scene 100, the tester need not closely carry out experimental operation, tester's life safety has been guaranteed, in addition, the tester passes through the long-range quick installation of the realization of manipulator by the sample under test, dismantle and disassemble, realize corresponding operation at distal end control terminal, very big improvement office efficiency, and the script automatic operation that experimental data processing was edited through the tester, can shorten data processing time, improve the fault discovery rate.

While the present embodiments have been described with reference to the accompanying drawings, it is to be understood that the invention is not limited to the precise embodiments described above, which are meant to be illustrative and not restrictive, and that various changes may be made therein by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides a new energy automobile's test system which characterized in that includes: the system comprises a remote control terminal and a test site, wherein the test site comprises a detection room, at least one test room and a travelling crane; wherein the content of the first and second substances,

the detection chamber comprises a first robot hand and at least one detection platform, wherein the at least one detection platform is used for detecting one or more performances of a sample piece to be detected before an experiment and transmitting detection result data to the remote control terminal; the first manipulator is used for placing the detected sample on the travelling crane;

the travelling crane is used for transporting the tested sample detected by the detection chamber to the test chamber;

any one of the test rooms comprises a test bench and a second robot, wherein the second robot is used for placing the tested sample on the test bench; the test bench is used for executing one or more tests on the tested sample and transmitting test results to the remote control terminal; the second robot hand is also used for placing the tested sample on the travelling crane after the test;

the travelling crane is also used for transporting the tested sample after the test to the next test room;

the remote control terminal is used for sending a control instruction to the travelling crane so as to control the transportation path of the travelling crane and receive the detection result and the test result;

the remote control terminal is further used for controlling the first robot hand and the second robot hand to achieve actions of the robot hands.

2. The testing system of claim 1, wherein the test site further comprises a disassembly chamber comprising a third robot and at least one disassembly platform, wherein,

the third robot is controlled by a remote control terminal and is used for placing the tested sample on the disassembling platform;

and the disassembling platform is used for disassembling the tested sample after the test, checking the state of the tested sample and transmitting the checking result to the remote control terminal.

3. The testing system of claim 1, wherein the at least one test chamber comprises at least one of: the test system comprises a butt-dragging test chamber, an electric drive assembly test chamber, a three-comprehensive vibration test chamber, a high-speed motor test chamber, a water channel pressure pulsation test chamber and a stator and rotor on-load temperature cycle endurance test chamber.

4. The testing system of claim 2,

the first robot hand is provided with a first camera, and the first camera is connected with the remote control terminal and used for collecting image information and transmitting the image information to the remote control terminal; and/or the presence of a gas in the gas,

the second robot hand is provided with a second camera which is connected with the remote control terminal and used for collecting image information and transmitting the image information to the remote control terminal; and/or the presence of a gas in the gas,

the third robot is provided with a third camera, and the third camera is connected with the remote control terminal and used for collecting image information and transmitting the image information to the remote control terminal.

5. The testing system of claim 2, wherein the remote control terminal comprises:

the bench remote operation module is used for displaying a first control interface of the test bench of each test room and transmitting a control instruction input on the first control interface to the test bench so as to control the test bench to perform a test;

the detection platform remote operation module is used for displaying a second control interface of each detection platform of the detection chamber and transmitting a control instruction input on the second control interface to the corresponding detection platform so as to control the detection platform to detect the detected sample;

and the disassembly platform remote operation module is used for displaying a third control interface of each disassembly platform of the disassembly chamber and transmitting a control command input on the third control interface to the corresponding disassembly platform so as to control the disassembly platform to disassemble the tested sample.

6. The testing system of claim 5, wherein the remote control terminal further comprises:

and the robot remote operation module is used for displaying a fourth control interface of the robot and transmitting a control instruction input on the fourth control interface to the first robot hand, the second robot hand or the third robot hand so as to control the first robot hand, the second robot hand or the third robot hand to execute corresponding operation.

7. The testing system of claim 5, wherein the remote control terminal further comprises:

a remote control module to:

sending a control instruction to the travelling crane to control a travelling path of the travelling crane; andor or

When the test site has a fault, sending fault information to a terminal of a tester, wherein the fault of the test site comprises at least one of the following: the tested sample is failed, the travelling crane is failed, the test bench is failed, the detection platform is failed, and the disassembly platform is failed.

8. The testing system of claim 7,

the remote control module is also used for sending alarm information to a terminal of laboratory managers when dangerous conditions occur in the test site and feeding the alarm information back to the robot remote operation module;

the robot remote operation module is further configured to send a control command to the first robot hand, the second robot hand, or the third robot hand to command the first robot hand, the second robot hand, or the third robot hand to execute a corresponding safety protection measure.

9. The testing system of claim 5, wherein the remote control terminal further comprises:

and the data processing module is used for receiving the detection result, the test result and the inspection result, and processing the detection result, the test result and the inspection result according to a preset processing mode to obtain a test data report.

10. A new energy automobile test method applied to the test system of any one of claims 1 to 10, characterized by comprising the following steps:

the detection chamber of the test system performs performance detection on the placed tested sample and transmits the detection result to the remote control terminal of the test system;

the crane of the test system transports the tested sample after performance detection to a target test room, wherein the target test room is one of at least one test room of the test system;

the target test room executes a corresponding target test on the tested sample and transmits a test result to the remote control terminal;

the travelling crane transports the tested sample to the next target laboratory for testing;

and the remote control terminal receives the detection result, the test result and the inspection result and generates a test report at least according to the detection result and the test result.

Images