CN113253698A

CN113253698A - Detection device and electric automobile

Info

Publication number: CN113253698A
Application number: CN202110226612.2A
Authority: CN
Inventors: 孟凡良; 马松全; 刘健聪
Original assignee: Neusoft Reach Automotive Technology Shenyang Co Ltd
Current assignee: Neusoft Reach Automotive Technology Shenyang Co Ltd
Priority date: 2021-03-01
Filing date: 2021-03-01
Publication date: 2021-08-13

Abstract

The application provides a detection device and an electric automobile. The detection device comprises a labeling module, an information verification module and an information acquisition module. During detection, the marking module marks the EVCC, and the verification module verifies the marking information. Meanwhile, the information acquisition module sends information records of the EVCC in each engineering stage to the upper computer, so that the upper computer can master the working process of the EVCC in each engineering stage. It can be seen that, by applying the detection device and the electric vehicle provided by the embodiments of the present application, not only the detection operation of the EVCC can be simplified, but also the detection efficiency of the EVCC can be improved.

Description

Detection device and electric automobile

Technical Field

The application relates to the technical field of electric automobiles, in particular to a detection device and an electric automobile.

Background

The electric automobile is increasingly popular as a new energy automobile because the electric automobile can make up for social energy shortage and reduce the environmental pollution caused by automobile exhaust. As an important component of an electric Vehicle, a Communication Controller (hereinafter, abbreviated as "EVCC"), which is an acronym of an electric Vehicle Communication Controller, has multiple functions, and during production, corresponding functionality detection needs to be performed on various functions of the EVCC.

At present, in the prior art, detection equipment with a single function of detecting the EVCC is used to perform function detection on functions corresponding to the EVCC, which causes that detection equipment corresponding to each function is needed if function detection on each function of the EVCC is to be completed, so that detection operation is complicated, and detection efficiency is low.

Disclosure of Invention

The application provides an improved detection device and an electric automobile, so that the detection efficiency is improved.

In a first aspect, an embodiment of the present application provides a detection device, electrically connected to an electric vehicle communication controller EVCC and an upper computer, where the detection device includes: the system comprises a detection main body, and a marking module, an information verification module and an information acquisition module which are integrated in the detection main body;

the marking module, the information verification module and the information acquisition module are electrically connected with the EVCC and the upper computer; the marking module is used for sending marking information issued by an upper computer to the EVCC so that the EVCC writes corresponding marks according to the marking information; the information verification module is used for reading the label written in the EVCC to verify whether the read label is correct or not; and the information acquisition module is used for sending the information record of the EVCC in each engineering stage to the upper computer.

In one embodiment of the present application, the detection apparatus further includes: a parameter grabbing module for grabbing the parameters of the system,

the parameter grabbing module is used for sending parameter information indicated by the upper computer to the upper computer, wherein the parameter information is from a system log of the EVCC;

the parameter grabbing module is integrated in the detection main body and is electrically connected with the upper computer.

In one embodiment of the present application, the detection apparatus further includes: a simulation charging module for simulating the charging of the battery,

the simulation charging module is used for simulating a charger and the EVCC to finish a charging interaction process so that the EVCC reports preset key parameters to the upper computer and the EVCC is checked to have a charging interaction function;

the simulation charging module is integrated in the detection main body and electrically connected with the upper computer.

In one embodiment of the present application, the detection apparatus further includes: a physical gun lock action module integrated with the detection main body,

the entity gun lock action module is used for acquiring the driving voltage of an entity gun lock so as to determine whether to instruct the EVCC to drive the entity gun lock to implement a charging action or not according to the driving voltage; alternatively, the first and second electrodes may be,

the solid gun lock action module is electrically connected with the upper computer, the detection device also comprises a first detection mode selection module,

the entity gun lock action module comprises a first entity gun detection submodule and a second entity gun detection submodule, wherein the first entity gun detection submodule is used for acquiring the driving voltage of an entity gun lock and determining whether to instruct the EVCC to drive the entity gun lock to implement a charging action or not according to the driving voltage; the second entity gun detection submodule is used for acquiring the driving voltage of an entity gun lock and sending the driving voltage to the upper computer so that the upper computer can determine whether to instruct the EVCC to drive the entity gun lock to implement a charging action according to the driving voltage;

the first detection mode selection module is used for triggering the first entity gun detection submodule under the condition that the first entity detection mode is selected to work in, and triggering the second entity gun detection submodule under the condition that the second entity detection mode is selected to work in.

In one embodiment of the present application, the detection apparatus further includes: a virtual gun lock action module integrated with the detection body,

the virtual gun lock action module is used for detecting the output voltage of the EVCC to determine whether a signal representing that the gun lock is in place is issued or not according to the output voltage so as to charge the EVCC; alternatively, the first and second electrodes may be,

the virtual gun lock action module is electrically connected with the upper computer; the detection apparatus further comprises a second detection mode selection module,

the virtual gun lock action module comprises a first virtual gun detection submodule and a second virtual gun detection submodule, wherein the first virtual gun detection submodule is used for detecting the output voltage of the EVCC and determining whether to issue a signal representing that the gun lock is in place or not according to the output voltage so as to charge the EVCC; the second virtual gun detection submodule is used for detecting the output voltage of the EVCC and sending the output voltage to the upper computer, so that the upper computer determines whether to send a signal representing that a gun is locked in place or not according to the output voltage, and the EVCC is charged;

the second detection mode selection module is used for triggering the first virtual gun detection submodule under the condition that the first virtual detection mode is selected to work in, and triggering the second virtual gun detection submodule under the condition that the second virtual detection mode is selected to work in.

In one embodiment of the present application, the detection apparatus further includes: a temperature access module integrated with the detection body,

the temperature access module is used for accessing a preset temperature environment to the EVCC, sending a request for returning the current temperature to the EVCC, acquiring the current temperature value returned by the EVCC, and determining whether the temperature of the EVCC needs to be corrected according to the current temperature value.

In one embodiment of the present application, the detection apparatus further includes: a temperature calibration module integrated with the detection body,

the temperature calibration module is used for sending a target temperature value and the current temperature value belonging to a preset temperature environment to the EVCC under the condition that the temperature of the EVCC needs to be corrected, so that the EVCC carries out calibration processing according to the target temperature value and the current temperature value, whether the calibration processing result is accurate or not is determined after the calibration processing result returned by the EVCC is received, and the temperature access module is triggered if the calibration processing result is inaccurate; alternatively, the first and second electrodes may be,

the temperature calibration module is electrically connected with the upper computer; the detection device further comprises a temperature mode selection module integrated with the detection body,

the temperature calibration module comprises a first temperature calibration sub-module and a second temperature calibration sub-module, wherein the first temperature calibration sub-module is used for sending a target temperature value and a current temperature value which belong to a preset temperature environment to the EVCC under the condition that the temperature of the EVCC needs to be corrected, so that the EVCC carries out calibration processing according to the target temperature value and the current temperature value, determining whether the calibration processing result is accurate or not after receiving the calibration processing result returned by the EVCC, and triggering the temperature access module if the calibration processing result is not accurate;

the second temperature calibration sub-module is used for sending a target temperature value and the current temperature value which belong to a preset temperature environment to the EVCC under the condition that the temperature of the EVCC needs to be corrected, so that the EVCC carries out calibration processing according to the target temperature value and the current temperature value, and after receiving a calibration processing result returned by the EVCC, sending the calibration processing result to the upper computer, so that the upper computer determines whether the calibration processing result is accurate, and if the calibration processing result is inaccurate, triggering the temperature access module;

the temperature mode selection module is used for triggering the first temperature calibration sub-module under the condition that the temperature mode selection module works in a first temperature detection mode, and triggering the second temperature calibration sub-module under the condition that the temperature mode selection module works in a second temperature detection mode.

In one embodiment of the present application, the detection apparatus further includes: a signal inspection module integrated within the detection body,

the signal checking module is used for detecting whether the EVCC sends a high-level signal or not so as to determine whether the high-level value is a preset value or not according to the high-level value corresponding to the high-level signal; alternatively, the first and second electrodes may be,

the signal inspection module is electrically connected with the upper computer; the detection apparatus further comprises a signal pattern selection module,

the signal checking module comprises a first signal checking submodule and a second signal checking submodule, wherein the first signal checking submodule is used for determining whether a high level value is a preset value or not according to the high level value corresponding to the high level signal when the EVCC is detected to send the high level signal; the second signal checking submodule is used for sending a high-level signal to the upper computer when the EVCC is detected to send the high-level signal, so that the upper computer determines whether the high-level value is a preset value or not according to the high-level value corresponding to the high-level signal;

the signal mode selection module is used for triggering the first signal checking submodule under the condition that the signal mode selection module is selected to work in a first signal checking mode, and triggering the second signal checking submodule under the condition that the signal mode selection module is selected to work in a second signal checking mode.

In one embodiment of the present application, the labeling module includes: a part number labeling submodule;

the part number marking sub-module is used for sending part number information issued by an upper computer to the EVCC so that the EVCC writes the part number carried by the part number information;

the information verification module is specifically used for reading the part number written in by the EVCC to verify whether the read part number is correct or not; and/or the first and/or second light sources,

the labeling module further comprises: a bar code labeling sub-module which is connected with the bar code labeling sub-module,

the EVCC of the bar code labeling submodule sends bar code information issued by an upper computer so that the EVCC can edit and write in a bar code according to a preset bar code format carried by the bar code information;

the information verification module is specifically used for reading the bar code written in by the EVCC so as to verify whether the read bar code is correct.

In one embodiment of the present application, the detection apparatus further includes: a part number mode selection module for selecting a part number mode,

the information verification module comprises a first part number verification submodule and a second part number verification submodule,

the first part number verification submodule is used for reading the part number written in the EVCC and verifying whether the read part number is correct or not; the second part number verification submodule is used for reading the part number written in by the EVCC and sending the part number to the upper computer so that the upper computer verifies whether the read part number is correct or not;

the part number mode selection module is used for triggering the first part number verification submodule under the condition of selecting to work in a first labeling mode, and triggering the second part number verification submodule under the condition of selecting to work in a second labeling mode; and/or the first and/or second light sources,

the detection device also comprises a bar code mode selection module,

the information verification module comprises a first bar code verification sub-module and a second bar code verification sub-module,

the first bar code verification sub-module is used for reading the bar code written in by the EVCC and verifying whether the read bar code is correct or not; the second bar code verification sub-module is used for reading the bar code written in by the EVCC and sending the read bar code to the upper computer so that the upper computer verifies whether the bar code is correct or not;

the bar code mode selection module is used for triggering the first bar code verification sub-module under the condition of selecting to work in a first labeling mode, and triggering the second bar code verification sub-module under the condition of selecting to work in a second labeling mode.

In a second aspect, an embodiment of the present application provides an electric vehicle, including an EVCC and an upper computer, the electric vehicle further includes a detection apparatus according to any of the above embodiments.

The technical scheme provided by the application can at least achieve the following beneficial effects:

the application provides a detection device and an electric automobile, the detection device is provided with a labeling module, an information verification module and an information acquisition module, when detection is carried out, the labeling module labels an EVCC, the verification module verifies labeled information, meanwhile, the information acquisition module sends information records of the EVCC in each engineering stage to an upper computer, and the upper computer can master the working process of the EVCC in each engineering stage. It can be seen that, the detection device provided in the embodiment of the present application does not need to separately set special detection equipment to label, label verify and acquire information of the EVCC, and can realize labeling, label verifying and information acquiring of the EVCC only by using a separate detection device to complete labeling and inspection at each working stage, thereby simplifying detection operation of the EVCC and improving detection efficiency of the EVCC.

Drawings

FIG. 1 is a schematic diagram of a first exemplary detection device according to an exemplary embodiment of the present disclosure;

FIG. 2 is a schematic structural diagram of a labeling module shown in the embodiment of FIG. 1;

FIG. 3 is a schematic diagram of the structure of information verification shown in the embodiment of FIG. 1;

FIG. 4 is a schematic structural diagram of a second detection device shown in an exemplary embodiment of the present application;

FIG. 5 is a schematic diagram of a third exemplary detection device according to an exemplary embodiment of the present disclosure;

FIG. 6 is a schematic structural diagram of a fourth detecting device according to an exemplary embodiment of the present application;

FIG. 7 is a block diagram of the embodiment of FIG. 5 illustrating the physical gun lock actuation module;

FIG. 8 is a schematic diagram of a virtual gun lock actuation module shown in the embodiment of FIG. 6;

FIG. 9 is a schematic diagram of the temperature calibration module shown in the embodiment of FIG. 6;

fig. 10 is a schematic structural diagram of a signal detection module shown in the embodiment of fig. 6.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present application, as detailed in the appended claims.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. Unless otherwise defined, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this application belongs. The use of "first," "second," and similar terms in the description and claims of this application do not denote any order, quantity, or importance, but rather the terms are used to distinguish one element from another. Similarly, the terms "a" or "an" and the like do not denote a limitation of quantity, but rather denote the presence of at least one, and if only "a" or "an" is denoted individually. "plurality" or "a number" means two or more. Unless otherwise specified, "front", "back", "lower" and/or "upper", "top", "bottom", and the like are for ease of description only and are not limited to one position or one spatial orientation. The word "comprising" or "comprises", and the like, means that the element or item listed as preceding "comprising" or "includes" covers the element or item listed as following "comprising" or "includes" and its equivalents, and does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a detection apparatus 300 according to an exemplary embodiment of the present disclosure, the detection apparatus 300 is electrically connected to an electric vehicle communication controller (hereinafter referred to as "EVCC") 100 and an upper computer 200, and the detection apparatus 300 may include: the system comprises a detection main body 301, a labeling module 302, an information verification module 303 and an information acquisition module 304.

As shown in fig. 1, an injection mold block 302, an information verification module 303 and an information acquisition module 304 integrated in the detection main body 301 are electrically connected with the EVCC100 and the upper computer 200; the labeling module 302 is configured to send labeling information issued by the upper computer 200 to the EVCC100, so that the EVCC100 writes corresponding labels according to the labeling information; the information verification module 303 is configured to read the label written in the EVCC100 to verify whether the read label is correct; the information acquisition module 304 is configured to send information records of the EVCC100 at each engineering stage to the upper computer 200.

In this embodiment, the detection main body may have a detection device of a main board, and in addition, after the upper computer 200 obtains information records of the EVCC100 at each engineering stage, the substrate electrical inspection, the function detection, the aging detection, and the like of the EVCC100 may be implemented.

The EVCC100 and the upper computer 200 are both electrically connected to the detection device 300, and in such connection, the detection device 300 can acquire information from the EVCC100 and return the information to the upper computer 200, based on which, in some embodiments, the upper computer 200 completes detection of the EVCC100 according to the acquired information, in other embodiments, the detection device 300 can also realize various detections of the EVCC100 alone without the help of the upper computer 200, so that under the resource shortage, failure or special environment of the upper computer 200, the detection device 300 realizes various detections of the EVCC100 alone.

In this embodiment, as shown in fig. 2, the labeling module 302 may implement labeling of the part number of the EVCC100, may also implement labeling of the barcode of the EVCC100, and may also label the part number of the EVCC100 and the barcode of the EVCC100 at the same time, and for the case of labeling the part number of the EVCC100, in some embodiments, as shown in fig. 3, the labeling module 302 may include a part number labeling submodule 3021; the part number labeling sub-module 3021 is configured to send part number information issued by the upper computer 200 to the EVCC100, so that the EVCC100 writes the part number carried in the part number information; the information verification module 303 is specifically configured to read the part number written by the EVCC100 to verify whether the read part number is correct. In the above embodiment, the part number labeling sub-module 3021 receives the part number information sent by the upper computer 200, and it should be mentioned that the part number information may also be stored locally in the detection apparatus for use in labeling. And the above-mentioned part number information is sent to the EVCC100, the EVCC100 writes the part number carried in the part number information according to the received part number information, after the completion, the information verification module 303 reads the part number written in the EVCC100 to verify whether the read part number is correct, in this embodiment, verifying whether the read part number is correct may be implemented by the information verification module, or may be implemented by the upper computer 200, which is not limited in this embodiment. In this embodiment, the part number labeling submodule 3021 and the information verification module 303 may complete labeling and verification of the part number of the EVCC, so as to further improve the detection efficiency. In other embodiments, the labeling module 302 further includes a barcode labeling sub-module 3022, where the barcode labeling sub-module 3022 is configured to send barcode information issued by the upper computer 200 to the EVCC100, so that the EVCC100 edits and writes a barcode according to a preset barcode format carried by the barcode information; the information verification module 303 is specifically configured to read a barcode written by the EVCC100 to verify whether the read barcode is correct. In this embodiment, the verification of whether the read barcode is correct may be performed by the information verification module 303, or may be performed by an upper computer, which is not limited in this embodiment, and in this embodiment, the barcode labeling submodule 3022 and the information verification module 303 may finish labeling and verifying the barcode of the EVCC, so as to further improve the detection efficiency.

As an embodiment, as shown in fig. 1 to 6, the detection apparatus further includes a part number mode selection module 316, and in fig. 3, the information verification module 303 includes a first part number verification submodule 3031 and a second part number verification submodule 3032, where the first part number verification submodule 3031 is configured to read a part number written in the EVCC100 and verify whether the read part number is correct; the second part number verification submodule 3032 is configured to read the part number written by the EVCC100, and send the part number to the upper computer 200, so that the upper computer 200 verifies whether the read part number is correct; the part number mode selection module 316 is configured to trigger the first part number verification submodule 3031 when the selection module works in the first labeling mode, and trigger the second part number verification submodule 3032 when the selection module works in the second labeling mode. In this embodiment, the part number mode selection module 316 has two working modes, when the selection is made to work in the first labeling mode, the first part number verification submodule is triggered, and as can be seen from the implementation manner of the first part number verification submodule 3031, the first part number verification submodule 3031 does not need to interact with the upper computer 200, which means that the first part number verification submodule 3031 can independently complete the verification of the written part number. When the user selects to work in the second labeling mode, the second part number verification submodule 3032 is triggered, and as can be seen from the implementation manner of the second part number verification submodule 3032, the second part number verification submodule 3032 needs to interact with the upper computer 200, which means that the second part number verification submodule 3032 needs to interact with the upper computer 200 to complete the verification of the written part number. Therefore, in the technical scheme provided by the embodiment of the application, the part number mode selection module can be used for selecting whether to work in the first marking mode or the second marking mode, so that the EVCC part number can be verified under the condition that the upper computer 200 is busy or inconvenient to process, and the detection reliability can be improved.

As another embodiment, as shown in fig. 3 to 6, the detection apparatus further includes a barcode mode selection module 317, as shown in fig. 3, the information verification module 303 includes a first barcode verification sub-module 3033 and a second barcode verification sub-module 3034, where the first barcode verification sub-module 3033 is configured to read a barcode written by the EVCC100 and verify whether the read barcode is correct; the second barcode verification submodule 3034 is configured to read the barcode written in the EVCC100, and send the read barcode to the upper computer 200, so that the upper computer 200 verifies whether the barcode is correct; the barcode mode selecting module 317 is configured to trigger the first barcode verification sub-module 3033 when the barcode mode selecting module selects to operate in the first labeling mode, and trigger the second barcode verification sub-module 3034 when the barcode mode selecting module selects to operate in the second labeling mode. In this embodiment, the barcode mode selecting module 317 has two working modes, when the first marking mode is selected to work, the first barcode verification submodule 3033 is triggered, and as can be seen from the implementation manner of the first barcode verification submodule 3033, the first barcode verification submodule 3033 does not need to interact with the upper computer 200, which means that the first barcode verification submodule 3033 can independently complete the verification of the written barcode. When the user selects to work in the second labeling mode, the second barcode verification submodule 3034 is triggered, and as can be seen from the implementation manner of the second barcode verification submodule 3034, the second barcode verification submodule 3034 needs to interact with the upper computer 200, which means that the second barcode verification submodule 3034 needs to interact with the upper computer 200 to complete verification of the written part number. Therefore, in the technical scheme provided by the embodiment of the application, the barcode mode selection module 317 can be used for selecting the EVCC barcode to work in the first labeling mode or the second labeling mode, so that the EVCC barcode can be verified under the condition that the upper computer 200 is busy or inconvenient to process, and the detection reliability can be improved.

In some embodiments, as shown in fig. 3 to 4, the detection main body 301 of the detection apparatus 300 may further integrate a parameter capture module 305, the parameter capture module 305 is electrically connected to the upper computer 200, and the parameter capture module 305 is configured to send parameter information indicated by the upper computer 200 to the upper computer 200, where the parameter information is from a system log of the EVCC 100. In this embodiment, in the process of detecting the EVCC, if parameter information is needed, the host computer 200 may send request information for representing the required parameter information to the parameter capture module 305, after the parameter capture module 305 parses the request information, the request information for sending the required parameter information to the EVCC100, and after the parameter capture module 305 receives the parameter information fed back by the EVCC100, the parameter capture module 305 sends the parameter information to the host computer 200, so that the host computer 200 can complete the detection of the EVCC in time, and the detection efficiency is further improved.

In some embodiments, as shown in fig. 3 to 6, the detection apparatus 300 further includes a simulation charging module 306 integrated in the detection main body 301, the simulation charging module 306 is electrically connected to the upper computer 200, and the simulation charging module 306 is configured to simulate a charger to complete a charging interaction process with the EVCC100, so that the EVCC100 reports preset key parameters to the upper computer 200, and the EVCC100 is checked to have a charging interaction function. In this embodiment, the analog charging module 306 simulates interaction between the charger and the EVCC100, and in the handshaking process, if the analog charging module 306 informs the resistance accessed by the EVCC100 and corresponds to the current returned by the EVCC100, it indicates that the analog charging module 306 simulates successful handshaking between the charger and the EVCC100, and further interaction is possible, and CP (control pilot) is accessed to communicate through the CP, so that the CP enters a charging mode, and thus a preset value is reported to the upper computer 200. Therefore, the charging mode function of the EVCC100 can be detected synchronously, and the detection efficiency is further improved.

In order to improve the practicability of the EVCC100, in some embodiments, as shown in fig. 5, the detection apparatus 300 further includes an entity gun lock action module 307 integrated in the detection main body 301, where the entity gun lock action module 307 is configured to collect a driving voltage of the entity gun lock, so as to determine whether to instruct the EVCC100 to drive the entity gun lock to perform a charging action according to the driving voltage. As an embodiment, the entity gun lock action module 307 acquires a driving voltage of the entity gun lock, determines whether the driving voltage is within a preset range, and drives the entity gun lock to act if the driving voltage is within the preset range, so as to charge the electric vehicle. If the charging time is not within the preset range, the reminding information used for indicating that the charging cannot be carried out is fed back, so that the user can repair the charging time in time according to the reminding information. As another embodiment, the entity gun lock action module 307 is electrically connected to the upper computer 200, the entity gun lock action module 307 acquires a driving voltage of the entity gun lock and sends the driving voltage to the upper computer 200, and the upper computer 200 determines whether the driving voltage is within a preset range, and if the driving voltage is within the preset range, the entity gun lock is driven to act, so that the electric vehicle is charged. If the charging time is not within the preset range, the reminding information used for indicating that the charging cannot be carried out is fed back, so that the user can repair the charging time in time according to the reminding information. Thereby further improving the detection efficiency of the EVCC 100.

In some embodiments, as shown in fig. 6, the detection apparatus 300 further includes a virtual gun lock actuation module 309 integrated with the detection body 301, wherein the virtual gun lock actuation module 309 is configured to detect an output voltage of the EVCC100, and determine whether to issue a signal indicating that a gun is locked in place according to the output voltage, so as to enable the EVCC100 to perform charging. As an embodiment, the virtual gun lock action module 309 collects an output voltage of the virtual gun lock, determines whether the output voltage is within a preset range, and drives the virtual gun lock to act if the output voltage is within the preset range, so as to charge the electric vehicle. If the charging time is not within the preset range, the reminding information used for indicating that the charging cannot be carried out is fed back, so that the user can repair the charging time in time according to the reminding information. As another embodiment, the virtual gun lock action module 309 is electrically connected to the upper computer 200, the virtual gun lock action module 309 collects an output voltage of the virtual gun lock and sends the output voltage to the upper computer 200, and the upper computer 200 determines whether the output voltage is within a preset range, and if the output voltage is within the preset range, drives the virtual gun lock to act, thereby charging the electric vehicle. If the charging time is not within the preset range, the reminding information used for indicating that the charging cannot be carried out is fed back, so that the user can repair the charging time in time according to the reminding information. Thereby further improving the detection efficiency of the EVCC 100.

For the situation that the entity gun lock action module 307 is electrically connected with the upper computer 200, in some embodiments, as shown in fig. 5 and 7, the detection device further includes a first detection mode selection module 308, the entity gun lock action module 307 includes a first entity gun detection submodule 3071 and a second entity gun detection submodule 3072, the first entity gun detection submodule 3071 is used for acquiring a driving voltage of an entity gun lock, and determining whether to instruct the EVCC100 to drive the entity gun lock to perform a charging action according to the driving voltage; the second entity gun detection submodule 3072 is configured to collect a driving voltage of an entity gun lock, and send the driving voltage to the upper computer 200, so that the upper computer 200 determines whether to instruct the EVCC100 to drive the entity gun lock to perform a charging action according to the driving voltage; the first detection mode selection module 308 is configured to trigger the first entity gun detection submodule 3071 when the first detection mode is selected to operate in the first entity detection mode, and trigger the second entity gun detection submodule 3072 when the second detection mode is selected to operate in the second entity detection mode. In this embodiment, the first detection mode selection module 308 has two working modes, when the first entity detection mode is selected to work, the first entity gun detection submodule 3071 is triggered, and as can be seen from the implementation manner of the first entity gun detection submodule 3071, the first entity gun detection submodule 3071 does not need to interact with the upper computer 200, which means that the first entity gun detection submodule 3071 can independently drive the entity gun lock to implement the charging action. When the second entity gun detection mode is selected to work, the second entity gun detection submodule 3072 is triggered, and the second entity gun detection submodule 3072 needs to interact with the upper computer 200 according to the implementation mode of the second entity gun detection submodule 3072, which means that the second entity gun detection submodule 3072 needs to interact with the upper computer 200 to complete the action of driving the entity gun lock to implement charging. It can be seen that in the technical scheme provided in the embodiment of the present application, the first detection mode selection module 308 can be used to select whether to work in the first entity detection mode or the second entity detection mode, so that the driving of the entity gun lock to implement the charging action can be realized under the condition that the upper computer 200 is busy or inconvenient to handle, and further, the charging function of the EVCC100 applied to the entity gun can be detected, and the reliability of detection can be improved.

For the situation that the virtual gun lock action module 309 is electrically connected with the upper computer 200, as shown in fig. 6 and 8, the detection device further includes a second detection mode selection module 310, the virtual gun lock action module 309 includes a first virtual gun detection submodule 3091 and a second virtual gun detection submodule 3092, the first virtual gun detection submodule 3091 is used for detecting the output voltage of the EVCC100, and determining whether to issue a signal representing that the gun lock is in place according to the output voltage, so as to charge the EVCC 100; the second virtual gun detection submodule 3092 is configured to detect an output voltage of the EVCC100, and send the output voltage to the upper computer 200, so that the upper computer 200 determines whether to issue a signal indicating that a gun is locked in place according to the output voltage, so that the EVCC100 performs charging; the second detection mode selection module 310 is configured to trigger the first virtual gun detection submodule 3091 when the first virtual detection mode is selected to operate, and trigger the second virtual gun detection submodule 3092 when the second virtual detection mode is selected to operate. In this embodiment, the second detection mode selection module 310 has two working modes, when the first virtual detection mode is selected, the first virtual gun detection submodule 3091 is triggered, and as can be seen from the implementation manner of the first virtual gun detection submodule 3091, the first virtual gun detection submodule 3091 does not need to interact with the upper computer 200, which means that the first virtual gun detection submodule 3091 can independently drive the physical gun lock to implement the charging action. When the second virtual detection mode is selected to work, the second virtual gun detection submodule 3092 is triggered, and as can be seen from the implementation manner of the second virtual gun detection submodule 3092, the second virtual gun detection submodule 3092 needs to interact with the upper computer 200, which means that the second virtual gun detection submodule 3092 needs to interact with the upper computer 200 to complete driving of the virtual gun lock to implement a charging action. It can be seen that in the technical solution provided in this application embodiment, the second detection mode selection module 310 can be used to select whether to work in the first virtual detection mode or the second virtual detection mode, so that the virtual gun lock can be driven to implement a charging action under the condition that the upper computer 200 is busy or inconvenient to handle, and then the charging function when the EVCC is applied to the virtual gun can be detected, and the reliability of detection can be improved.

In some embodiments, as shown in fig. 6, the detection apparatus 300 further includes a temperature access module 311 integrated in the detection subject 301, where the temperature access module 311 is configured to access a preset temperature environment to the EVCC100, send a request for returning a current temperature to the EVCC100, obtain a current temperature value returned by the EVCC100, and determine whether to correct the temperature of the EVCC100 according to the current temperature value. In this embodiment, a temperature environment is built for the EVCC100, if the detection apparatus 300 accesses a preset curvature environment to the EVCC100, and then sends a check value of 25 degrees to the EVCC100, if the current temperature value returned by the EVCC100 is 25 degrees, it indicates that the temperature environment accessed by the EVCC100 is normal, and no correction is needed, if the current temperature value returned by the EVCC100 is 30 degrees, it indicates that the temperature environment accessed by the EVCC100 is abnormal, and further correction is needed, so as to implement the function of building the temperature environment for the EVCC100, and further improve the detection efficiency of the EVCC.

In some embodiments, as shown in fig. 6, the detecting apparatus 300 further includes a temperature calibration module 312 integrated in the detecting main body 301, where the temperature calibration module 312 is configured to, when it is determined that the temperature of the EVCC100 needs to be corrected, send a target temperature value and the current temperature value belonging to a preset temperature environment to the EVCC100, so that the EVCC100 performs calibration processing according to the target temperature value and the current temperature value, determine whether the calibration processing result is accurate after receiving the calibration processing result returned by the EVCC100, and trigger the temperature access module 311 if the calibration processing result is inaccurate. In this embodiment, determining whether the calibration processing result is accurate may be performed by the temperature calibration module 312 or by the upper computer 200, which is not limited in this embodiment. As an embodiment, the temperature calibration module 312 determines whether the calibration processing result is accurate after receiving the calibration processing result returned by the EVCC100, and if the calibration processing result is not accurate, triggers the temperature access module 311 to implement the establishment of the temperature environment of the EVCC100 alone without using the upper computer 200. As another embodiment, after receiving the calibration processing result returned by the EVCC100, the temperature calibration module 312 sends the calibration processing result returned by the EVCC100 to the upper computer 200, and the upper computer 200 determines whether the calibration processing result returned by the EVCC100 is correct, and if the calibration processing result is not accurate, triggers the temperature access module 311. In the technical solution provided in this embodiment, the establishment of the temperature environment of the EVCC100 is achieved through interaction between the temperature calibration module 312 and the upper computer 200.

As an example, as shown in fig. 9, the temperature calibration module 312 is electrically connected to the upper computer 200; the detection apparatus 300 further includes a temperature mode selection module 313 integrated with the detection subject 301, the temperature calibration module 312 includes a first temperature calibration submodule 3121 and a second temperature calibration submodule 3122, the first temperature calibration submodule 3121 is configured to send a target temperature value and the current temperature value belonging to a preset temperature environment to the EVCC100 under a condition that it is determined that the temperature of the EVCC100 needs to be corrected, so that the EVCC100 performs calibration processing according to the target temperature value and the current temperature value, and after receiving a calibration processing result returned by the EVCC100, determine whether the calibration processing result is accurate, and if the calibration processing result is not accurate, trigger the temperature access module 311; the second temperature calibration sub-module 3122 is configured to, under a condition that it is determined that the temperature of the EVCC100 needs to be corrected, send a target temperature value and the current temperature value belonging to a preset temperature environment to the EVCC100, so that the EVCC100 performs calibration processing according to the target temperature value and the current temperature value, and after receiving a calibration processing result returned by the EVCC100, send the calibration processing result to the upper computer 200, so that the upper computer 200 determines whether the calibration processing result is accurate, and if the calibration processing result is not accurate, trigger the temperature access module 311. The temperature mode selection module 313 is configured to trigger the first temperature calibration sub-module 3121 when the first temperature detection mode is selected, and trigger the second temperature calibration sub-module 3122 when the second temperature detection mode is selected. In this embodiment, the temperature mode selection module 313 has two working modes, when the first temperature detection mode is selected to work, the first temperature calibration submodule 3121 is triggered, and as can be seen from the implementation manner of triggering the first temperature calibration submodule 3121, the first temperature calibration submodule 3121 does not need to interact with the upper computer 200, which means that the first temperature calibration submodule 3121 can independently complete the establishment of the temperature environment of the EVCC 100. When the second temperature detection mode is selected to work, the second temperature calibration submodule 3122 is triggered, and as can be seen from the implementation manner of the second temperature calibration submodule 3122, the second temperature calibration submodule 3122 needs to interact with the upper computer 200, which means that the second temperature calibration submodule 3122 needs to interact with the upper computer 200 to complete the establishment of the temperature environment of the EVCC 100. Therefore, in the technical scheme provided by the embodiment of the application, the temperature mode selection module 313 can be used for selecting the first temperature detection mode or the second temperature detection mode, so that the temperature of the EVCC100 can be built under the condition that the upper computer 200 is busy or inconvenient to process, and the detection reliability can be improved.

In some embodiments, as shown in fig. 6, the detection device further comprises: a signal checking module 314 integrated with the detection body 301, wherein the signal checking module 314 is configured to detect whether the EVCC100 sends a high level signal, so as to determine whether the high level signal is a preset value according to a high level value corresponding to the high level signal. In this embodiment, determining whether the high level value is a preset value according to the high level value corresponding to the high level signal may be implemented by the signal checking module 314, or may be implemented by the upper computer 200, which is not limited in this embodiment. As an embodiment, after detecting the high level signal of the EVCC100, the signal checking module 314 determines a high level value corresponding to the high level signal, and determines whether the high level value is a preset value, so as to independently detect the high level value of the EVCC100 without using the upper computer 200. As another embodiment, the signal checking module 314 sends a high level signal to the upper computer 200 after detecting the high level signal sent by the EVCC100, and the upper computer 200 determines a high level value corresponding to the high level signal and determines whether the high level value is a preset value. In the technical solution provided in this embodiment, the detection of the high level value of the EVCC100 is achieved through interaction between the signal checking module 314 and the upper computer 200.

In other embodiments, as shown in fig. 6 and 10, the signal checking module 314 is electrically connected to the upper computer 200; the detection apparatus further includes a signal mode selection module 315, where the signal check module 314 includes a first signal check submodule 3141 and a second signal check submodule 3142, and the first signal check submodule 3141 is configured to, when detecting that the EVCC100 sends a high-level signal, determine whether the high-level signal is a preset value according to a high-level value corresponding to the high-level signal; the second signal checking sub-module 3142 is configured to send a high level signal to the upper computer 200 when it is detected that the EVCC100 sends the high level signal, so that the upper computer 200 determines whether the high level value is a preset value according to the high level value corresponding to the high level signal; the signal mode selection module 315 is configured to trigger the first signal checking submodule 3141 when the first signal checking mode is selected to operate, and trigger the second signal checking submodule 3142 when the second signal checking mode is selected to operate. In this embodiment, the signal checking module 314 has two working modes, when the first signal checking module is selected to work in the first signal checking mode, the first signal checking submodule 3141 is triggered, and as can be seen from the implementation manner of triggering the first signal checking submodule 3141, the first signal checking submodule 3141 does not need to interact with the upper computer 200, which means that the first signal checking submodule 3141 can independently complete the detection of the high level signal of the EVCC 100. When the second signal checking mode is selected to work, the second signal checking sub-module 3142 is triggered, and as can be seen from the implementation manner of the second signal checking sub-module 3142, the second signal checking sub-module 3142 needs to interact with the upper computer 200, which means that the second signal checking sub-module 3142 needs to interact with the upper computer 200 to complete the detection of the high-level signal of the EVCC 100. It can be seen that in the technical solution provided in the embodiment of the present application, the signal checking module 314 can select to work in the first signal checking mode or the second signal checking mode, so that the detection of the EVCC100 high-level signal can be realized under the condition that the upper computer 200 is busy or inconvenient to process, and the reliability of the detection can be further improved.

Therefore, the detection device provided by the embodiment of the application is provided with the labeling module, the information verification module and the information acquisition module, when detection is carried out, the labeling module labels the EVCC100, the verification module verifies the labeled information, and meanwhile, the information acquisition module sends the information record of the EVCC100 in each engineering stage to the upper computer, so that the upper computer can master the working process of the EVCC100 in each engineering stage. It can be seen that, the detection apparatus 300 provided in the embodiment of the present application does not need to separately set a special detection device to label, label verify and acquire information of the EVCC100, and only needs the separate detection apparatus 300 to implement labeling, label verifying and information acquiring of the EVCC100 to complete labeling and inspection at each working stage, which not only can simplify the detection operation on the EVCC100, but also can improve the detection efficiency on the EVCC 100.

In another aspect, an embodiment of the present application further provides an electric vehicle, which includes an EVCC100, an upper computer 200, and the detection apparatus 300 according to any of the above embodiments. The electric automobile in this application can adapt to the EVCC100 of different functions, detection device 300 that this electric automobile includes makes when detecting this electric automobile's EVCC100, needn't set up special check out test set separately and mark EVCC100 respectively, mark verification and information acquisition, only need solitary detection device 300 alright realize marking EVCC100, mark verification and information acquisition, in order to accomplish the mark and in the inspection of each working phase, not only can simplify the check-out operation to EVCC100, can also improve the detection efficiency to EVCC100, thereby can improve electric automobile's production efficiency.

The embodiments of the present application may complement each other without conflict.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the scope of protection of the present application.

Claims

1. A detection device is electrically connected with an EVCC (100) and an upper computer (200), and is characterized in that the detection device (300) comprises a detection main body (301), and a labeling module (302), an information verification module (303) and an information acquisition module (304) which are integrated in the detection main body (301);

the marking module (302), the information verification module (303) and the information acquisition module (304) are electrically connected with the EVCC (100) and the upper computer (200); the marking module (302) is used for sending marking information issued by an upper computer (200) to the EVCC (100) so that the EVCC (100) writes corresponding marks according to the marking information; the information verification module (303) is used for reading the label written by the EVCC (100) so as to verify whether the read label is correct; the information acquisition module (304) is used for sending information records of the EVCC (100) in each engineering stage to the upper computer (200).

2. The detection apparatus according to claim 1, characterized in that the detection apparatus further comprises a parameter grabbing module (305),

the parameter grabbing module (305) is used for sending parameter information indicated by the upper computer (200) to the upper computer (200), and the parameter information is from a system log of the EVCC (100);

the parameter grabbing module (305) is integrated with the detection main body (301) and is used for being electrically connected with the upper computer (200).

3. The detection apparatus according to claim 1, further comprising an analog charging module (306),

the simulation charging module (306) is used for simulating a charger to complete a charging interaction process with the EVCC (100), so that the EVCC (100) reports preset key parameters to the upper computer (200), and the EVCC (100) is checked to have a charging interaction function;

the simulation charging module (306) is integrated on the detection main body (301) and is electrically connected with the upper computer (200).

4. The detection device according to claim 1, characterized in that it further comprises a physical gun lock action module (307) integrated in the detection body (301),

the entity gun lock action module (307) is used for acquiring the driving voltage of an entity gun lock so as to determine whether to instruct the EVCC (100) to drive the entity gun lock to implement a charging action or not according to the driving voltage; alternatively, the first and second electrodes may be,

the entity gun lock action module (307) is electrically connected with the upper computer (200), the detection device also comprises a first detection mode selection module (308),

the entity gun lock action module (307) comprises a first entity gun detection submodule (3071) and a second entity gun detection submodule (3072), wherein the first entity gun detection submodule (3071) is used for collecting a driving voltage of an entity gun lock and determining whether to instruct the EVCC (100) to drive the entity gun lock to perform a charging action according to the driving voltage; the second entity gun detection submodule (3072) is used for acquiring a driving voltage of an entity gun lock and sending the driving voltage to the upper computer (200), so that the upper computer (200) determines whether to instruct the EVCC (100) to drive the entity gun lock to perform a charging action or not according to the driving voltage;

the first detection mode selection module (308) is configured to trigger the first entity gun detection submodule (3071) when the first entity gun detection module is selected to operate in a first entity detection mode, and trigger the second entity gun detection submodule (3072) when the second entity gun detection module is selected to operate in a second entity detection mode.

5. The detection device according to claim 1, characterized in that it further comprises a virtual gun lock action module (309) integrated in the detection body (301),

the virtual gun lock action module (309) is used for detecting the output voltage of the EVCC (100) so as to determine whether to issue a signal representing that a gun is locked in place or not according to the output voltage, so that the EVCC (100) carries out charging; or

The virtual gun lock action module (309) is electrically connected with the upper computer (200); the detection apparatus further comprises a second detection mode selection module (310),

the virtual gun lock action module (309) comprises a first virtual gun detection submodule (3091) and a second virtual gun detection submodule (3092), wherein the first virtual gun detection submodule (3091) is used for detecting the output voltage of the EVCC (100), and determining whether to issue a signal representing that a gun lock is in place or not according to the output voltage so as to charge the EVCC (100); the second virtual gun detection submodule (3092) is used for detecting the output voltage of the EVCC (100) and sending the output voltage to the upper computer (200), so that the upper computer (200) determines whether to send a signal representing that a gun is locked in place or not according to the output voltage, and the EVCC (100) is charged;

the second detection mode selection module (310) is configured to trigger the first virtual gun detection submodule (3091) when the first virtual detection mode is selected to operate in, and trigger the second virtual gun detection submodule (3092) when the second virtual detection mode is selected to operate in.

6. Detection device according to claim 1, characterized in that it further comprises a temperature access module (311) integrated in said detection body (301),

the temperature access module (311) is configured to access a preset temperature environment to the EVCC (100), send a request for returning the current temperature to the EVCC (100), obtain the current temperature value returned by the EVCC (100), and determine whether the temperature of the EVCC (100) needs to be corrected according to the current temperature value.

7. The detection device of claim 6, further comprising: a temperature calibration module (312) integrated in the detection body (301),

the temperature calibration module (312) is configured to send a target temperature value and the current temperature value belonging to a preset temperature environment to the EVCC (100) under the condition that it is determined that the temperature of the EVCC (100) needs to be corrected, so that the EVCC (100) performs calibration processing according to the target temperature value and the current temperature value, and after receiving a calibration processing result returned by the EVCC (100), determine whether the calibration processing result is accurate, and if the calibration processing result is not accurate, trigger the temperature access module (311); or

The temperature calibration module (312) is electrically connected with the upper computer (200); the detection device further comprises a temperature mode selection module (313) integrated to the detection body (301),

the temperature calibration module (312) comprises a first temperature calibration submodule (3121) and a second temperature calibration submodule (3122), wherein the first temperature calibration submodule (3121) is configured to, under a condition that it is determined that the temperature of the EVCC (100) needs to be corrected, send a target temperature value and the current temperature value belonging to a preset temperature environment to the EVCC (100), so that the EVCC (100) performs calibration processing according to the target temperature value and the current temperature value, and after receiving a calibration processing result returned by the EVCC (100), determine whether the calibration processing result is accurate, and if the calibration processing result is not accurate, trigger the temperature access module (311);

the second temperature calibration sub-module (3122) is configured to, under a condition that it is determined that the temperature of the EVCC (100) needs to be corrected, send a target temperature value and the current temperature value belonging to a preset temperature environment to the EVCC (100), so that the EVCC (100) performs calibration processing according to the target temperature value and the current temperature value, and after receiving a calibration processing result returned by the EVCC (100), send the calibration processing result to the upper computer (200), so that the upper computer (200) determines whether the calibration processing result is accurate, and if the calibration processing result is inaccurate, trigger the temperature access module (311);

the temperature mode selection module (313) is used for triggering the first temperature calibration sub-module (3121) when the first temperature detection mode is selected to work, and triggering the second temperature calibration sub-module (3122) when the second temperature detection mode is selected to work.

8. The detection device according to any one of claims 1 to 7, further comprising a signal checking module (314) integrated to the detection body (301),

the signal checking module (314) is configured to detect whether the EVCC (100) sends a high level signal, so as to determine whether the high level value is a preset value according to a high level value corresponding to the high level signal; or

The signal inspection module (314) is electrically connected with the upper computer (200); the detection apparatus further comprises a signal pattern selection module (315),

the signal checking module (314) comprises a first signal checking submodule (3141) and a second signal checking submodule (3142), wherein the first signal checking submodule (3141) is used for determining whether a high-level value is a preset value or not according to the high-level value corresponding to the high-level signal when the EVCC (100) is detected to send the high-level signal; the second signal checking submodule (3142) is used for sending a high-level signal to the upper computer (200) when the EVCC (100) is detected to send the high-level signal, so that the upper computer (200) determines whether the high-level value is a preset value or not according to the high-level value corresponding to the high-level signal;

the signal mode selection module (315) is configured to trigger the first signal checking submodule (3141) if the first signal checking mode is selected to operate, and to trigger the second signal checking submodule (3142) if the second signal checking mode is selected to operate.

9. The detection apparatus according to claim 1, wherein the labeling module (302) comprises a part number labeling submodule (3021);

the part number labeling submodule (3021) is configured to send part number information issued by an upper computer (200) to the EVCC (100), so that the EVCC (100) writes the part number carried in the part number information;

the information verification module (303) is specifically configured to read the part number written by the EVCC (100) to verify whether the read part number is correct; or/and

the labeling module (302) further comprises a barcode labeling submodule (3022),

the barcode labeling submodule (3022) is configured to send barcode information issued by an upper computer (200) to the EVCC (100), so that the EVCC (100) edits and writes a barcode according to a preset barcode format carried by the barcode information;

the information verification module (303) is specifically configured to read the barcode written by the EVCC (100) to verify whether the read barcode is correct.

10. The detection device according to claim 9, further comprising: a part number mode selection module (316),

the information verification module (303) comprises a first part number verification submodule (3031) and a second part number verification submodule (3032),

the first part number verification submodule (3031) is used for reading the part number written in the EVCC (100) and verifying whether the read part number is correct or not; the second part number verification submodule (3032) is used for reading the part number written in the EVCC (100) and sending the part number to the upper computer (200) so that the upper computer (200) can verify whether the read part number is correct or not;

the part number mode selection module (316) is used for triggering the first part number verification submodule (3031) under the condition of selecting to work in a first labeling mode, and triggering the second part number verification submodule (3032) under the condition of selecting to work in a second labeling mode; or/and

the detection device further comprises a bar code mode selection module (317),

the information verification module (303) comprises a first bar code verification sub-module (3033) and a second bar code verification sub-module (3034),

the first barcode verification submodule (3033) is used for reading the barcode written in the EVCC (100) and verifying whether the read barcode is correct; the second bar code verification sub-module (3034) is used for reading the bar code written in by the EVCC (100) and sending the read bar code to the upper computer (200) so that the upper computer (200) can verify whether the bar code is correct or not;

the barcode mode selection module (317) is used for triggering the first barcode verification submodule (3033) under the condition that the barcode mode selection module works in a first marking mode, and triggering the second barcode verification submodule (3034) under the condition that the barcode mode selection module works in a second marking mode.

11. An electric vehicle comprising an EVCC (100) and an upper computer (200), characterized in that it further comprises a detection device (300) according to any one of claims 1 to 10.