CN220629359U - Vehicle remote diagnosis system - Google Patents

Abstract

The utility model provides a vehicle remote diagnosis system which comprises diagnosis equipment, a first mobile phone, a server and a second mobile phone. Wherein the diagnostic device is used for connecting the vehicle to diagnose the vehicle; the first mobile phone is directly connected with the diagnosis equipment; the server is remotely connected with the first mobile phone through a mobile network; the second mobile phone is remotely connected with the server through a mobile network. The utility model does not need to upgrade and reform the hardware of the diagnosis equipment, saves the development time of the hardware and conveniently realizes the remote diagnosis of the vehicle.

Description

Vehicle remote diagnosis system

Technical Field

The utility model relates to the field of vehicle diagnosis, in particular to a vehicle remote diagnosis system.

Background

At present, the remote diagnosis of the vehicle maintenance equipment is realized by configuring a mobile communication module on the diagnosis equipment, connecting the mobile communication module of the diagnosis equipment to a server, and connecting the mobile communication module of the diagnosis equipment to a terminal equipment through the server. Therefore, the need to make hardware modifications to existing diagnostic equipment can greatly increase equipment costs, resulting in low price competitiveness. In addition, at present, a real name system is required for handling the SIM card in China, and after the diagnosis equipment is delivered to a customer, the customer needs to handle the SIM card first and cannot use the SIM card immediately.

Disclosure of Invention

In view of the above, it is necessary to provide a vehicle remote diagnosis system that does not need to upgrade and modify hardware of a diagnosis device, saves development time of hardware, and conveniently realizes remote diagnosis of a vehicle.

A first embodiment of the present utility model provides a vehicle remote diagnosis system, the system comprising:

a diagnostic device for connecting the vehicle to diagnose the vehicle;

the first mobile phone is directly connected with the diagnosis equipment;

the server is remotely connected with the first mobile phone through a mobile network;

the second mobile phone is remotely connected with the server through a mobile network.

Further, the first mobile phone is directly connected with the diagnostic equipment through USB, bluetooth or WIFI.

Further, the first mobile phone is remotely connected with the server through a 5G network.

Further, the second mobile phone is remotely connected with the server through a 5G network.

A second embodiment of the present utility model provides a vehicle remote diagnosis system, the system comprising:

a diagnostic device for connecting the vehicle to diagnose the vehicle;

the first mobile phone is directly connected with the diagnosis equipment;

and the second mobile phone is remotely connected with the first mobile phone through network punching.

Further, the first mobile phone is directly connected with the diagnostic equipment through USB, bluetooth or WIFI.

Compared with the prior art, the utility model has the beneficial effects that: according to the utility model, upgrading and reconstruction of hardware of the diagnosis equipment are not needed, the development time of the hardware can be greatly saved, the diagnosis data can be sent to the first mobile phone, the mobile phone is used as data transfer, the mobile phone is popular at present, and the remote diagnosis of the vehicle is conveniently realized by almost one person.

Drawings

Fig. 1 is a schematic diagram of a vehicle remote diagnosis system according to a first embodiment of the present utility model.

Fig. 2 is a schematic structural diagram of a vehicle remote diagnosis system according to a second embodiment of the present utility model.

Fig. 3 is a flowchart of a vehicle remote diagnosis method according to a first embodiment of the present utility model.

Fig. 4 is a flowchart of a vehicle remote diagnosis method according to a second embodiment of the present utility model.

Fig. 5 is a flowchart of a vehicle remote diagnosis method according to a third embodiment of the present utility model.

The utility model will be further described in the following detailed description in conjunction with the above-described figures.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to fall within the scope of the utility model. It is to be understood that the drawings are designed solely for the purposes of illustration and not as a definition of the limits of the utility model.

As shown in fig. 1, the embodiment of the utility model provides a vehicle remote diagnosis system, which comprises diagnosis equipment, a server, a first mobile phone and a second mobile phone.

The diagnosis device is used for being connected with a vehicle to diagnose the vehicle. The first mobile phone is directly connected with the diagnosis equipment, and the server is remotely connected with the first mobile phone through a mobile network. The second mobile phone is used for being remotely connected with the server through a mobile network. More specifically, the first mobile phone is directly connected with the diagnostic equipment through USB, bluetooth or WIFI. More specifically, the first mobile phone 20 is remotely connected to the server 30 via a 5G network. More specifically, the second mobile phone 40 is remotely connected to the server 30 through a 5G network.

In other embodiments, as shown in FIG. 2, the vehicle remote diagnostic system may include a diagnostic device 10, a first mobile phone 20, and a second mobile phone 40. Wherein the diagnostic device 10 is used for connecting a vehicle for diagnosing the vehicle. The first mobile phone 20 is directly connected to the diagnostic device 10. The second mobile phone 40 is remotely connected to the first mobile phone 20 through a network via hole. More specifically, the first mobile phone 20 is directly connected to the diagnostic device 10 through USB, bluetooth, or WIFI.

In the vehicle remote diagnosis system provided in the above two embodiments, the development time of hardware is greatly saved without upgrading and modifying the hardware of the diagnosis device 10, the diagnosis data can be sent to the first mobile phone 20, the first mobile phone 20 is used as data transfer, and the mobile phone is popular at present, almost one by one, so that the remote diagnosis of the vehicle is conveniently realized.

The vehicle remote diagnosis method provided by the utility model is applied to the first mobile phone 10, as shown in fig. 3, and comprises the following steps:

s11: and receiving diagnosis data sent by the diagnosis equipment for diagnosing the vehicle and judging whether the vehicle has a fault and a fault type result according to the diagnosis data by the diagnosis equipment.

S12: and determining that the fault type is a first type of fault or a second type of fault or a third type of fault, if the fault type is the first type of fault, executing the step S13, if the fault type is the second type of fault, executing the step S14, and if the fault type is the third type of fault, executing the step S15.

S13: and sending a video acquisition request to the diagnosis equipment, and after the request is successful, receiving and playing the video belonging to the first type of video corresponding to the fault stored by the diagnosis equipment.

S14: and sending a video acquisition request to a server, and after the request is successful, receiving and playing the video belonging to the second type of video, which corresponds to the fault and is sent by the server.

The video belonging to the second type of video of the server is shot by the second mobile phone periodically or aperiodically during amateur hours and is sent to the server to be stored.

S15: and sending an online connection request to a second mobile phone, and sending the diagnosis data to the second mobile phone after the request is successful.

S16: and carrying out real-time video communication with the second mobile phone.

More specifically, the first type of faults includes decorative non-system faults, the second type of faults includes non-dynamic system faults, and the third type of faults includes dynamic system faults. The technical content required for diagnosis and the demands on driving safety are increasing from decorative non-system faults to non-dynamic system faults to dynamic system faults.

According to the utility model, the video corresponding to the first type of faults is stored in the diagnosis equipment, the video corresponding to the second type of faults is stored in the server, the storage pressure of the diagnosis equipment is reduced, the corresponding video can be obtained according to the fault type to carry out watching diagnosis, and diagnosis is more visual.

Aiming at the first type of faults, videos can be obtained from diagnostic equipment under the condition of no network, the diagnosis speed of the first type of faults is improved, aiming at the second type of faults, videos can be obtained from a server without communication with a second mobile phone, the diagnosis speed of the second type of faults is improved, and aiming at the third type of faults, the third type of faults need to be communicated with the second mobile phone so as to solve the complex diagnosis problem.

More specifically, in step S14, the performing real-time video communication with the second mobile phone includes:

s141: and acquiring a sound stream sent by the second mobile phone in the process of carrying out real-time communication with the second mobile phone.

S142: keywords included in the sound stream are analyzed, the keywords including names of vehicle components.

S143: and judging whether the name of the vehicle component is associated with the fault according to the diagnosis data.

S144: and if the fault is associated with the fault, displaying a vehicle position schematic diagram of the vehicle part in a video interface so as to conduct operation guidance on a user of the first mobile phone.

In the specific embodiment, the user of the first mobile phone can conveniently find the position of the fault point of the vehicle quickly when in video communication of the user of the second mobile phone, so that the time is saved, and the diagnosis efficiency is improved.

Further, as shown in fig. 4, the vehicle remote diagnosis method provided by the utility model further includes:

s17: and sending the received video affiliated to the second type of video to the diagnosis equipment so that the diagnosis equipment can store the video as the first type of video and modify the type corresponding to the fault into the first type of fault.

S18: and transmitting the video obtained in the process of carrying out real-time video communication with the second mobile phone to the diagnosis equipment so that the diagnosis equipment can store the video as a first type of video and modify the type corresponding to the fault into the first type of fault.

Because of the reason of the vehicle, the possibility that the vehicle encounters the same fault again is relatively high, the received second-class video or the video obtained in the communication process of the second-class video and the second-handset video is stored through the diagnosis equipment, when the user of the first-handset encounters the same fault problem again, the corresponding video can be directly obtained from the diagnosis equipment, the diagnosis speed when the user encounters the same fault problem again is improved, and because the user has relevant diagnosis experience, the corresponding video can be directly obtained from the diagnosis equipment through experience.

In step S18, the sending, to the diagnostic device, the video obtained in the process of performing real-time video communication with the second mobile phone specifically includes:

s181: and acquiring the video acquired in the process of carrying out real-time video communication with the second mobile phone.

S182: and acquiring the video stream and the sound stream of the video.

S183: and setting the parts, which are included in the video stream and the sound stream and are associated with the faults, as normal play and deleting the parts which are not associated with the faults.

S184: and sending the processed video to the diagnosis equipment.

During real-time video communication with the second handset, video chat may occur that is not related to the diagnostic process, resulting in excessive video content. In this embodiment, the parts associated with the fault included in the video stream and the audio stream are set to be normally played, the parts not associated with the fault are deleted, and then the reserved parts are spliced and fused, so that the video content after final processing is smaller, and the storage pressure of the diagnostic device can be reduced.

Further, as shown in fig. 5, the vehicle remote diagnosis method provided by the utility model further includes:

s19: and receiving the diagnosis information of the second mobile phone and displaying the diagnosis information on a display interface.

Wherein the diagnostic information is obtained based on the following method:

s1, after receiving the diagnosis data sent by the first mobile phone, the second mobile phone sends the diagnosis data to other local diagnosis equipment for re-diagnosis so as to determine the fault point and the fault type of the fault.

S2, if the fault type is a non-third type fault, the determined fault point and the determined fault type are sent to the second mobile phone.

And if the fault type is a third type of fault, continuing to step S16 to perform normal video communication with the first mobile phone.

S20: and determining that the fault type included in the diagnosis information is a first type of fault or a second type of fault, if the fault type is the first type of fault, executing the step S21, and if the fault type is the second type of fault, executing the step S22.

S21: and sending a video acquisition request to the diagnosis equipment, and after the request is successful, receiving and playing the video belonging to the first type of video, which corresponds to the determined fault point and is stored by the diagnosis equipment.

S22: and sending a video acquisition request to the service, and after the request is successful, receiving and playing the video belonging to the second type of video, which corresponds to the determined fault point and is sent by the server.

In the specific embodiment of the utility model, the local other diagnosis equipment connected with the second mobile phone is used for performing re-diagnosis according to the diagnosis data, so that the fault point and the fault type of the fault are further determined, and the accuracy of the diagnosis result can be ensured.

And if the finally determined fault type is a first type of fault, the first mobile phone is instructed to acquire videos which are affiliated to the first type of video and correspond to the determined fault point from the connected diagnosis equipment, if the finally determined fault type is a second type of fault, the first mobile phone is instructed to acquire videos which are affiliated to the second type of video and correspond to the determined fault point from the server, and if the finally determined fault type is a third type of fault, the step S16 is continued, and normal video communication is carried out with the first mobile phone.

A third aspect of the present utility model provides a computer storage medium having stored therein a computer software program which when executed by a processor implements the vehicle remote diagnosis method.

The foregoing description of the preferred embodiment of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (6)

1. A vehicle remote diagnostic system, the system comprising:

a diagnostic device for connecting the vehicle to diagnose the vehicle;

the first mobile phone is directly connected with the diagnosis equipment;

the server is remotely connected with the first mobile phone through a mobile network;

the second mobile phone is remotely connected with the server through a mobile network.

2. The vehicle remote diagnostic system of claim 1, wherein the first mobile phone is directly connected to the diagnostic device via USB or bluetooth or WIFI.

3. The vehicle remote diagnostic system of claim 1, wherein the first mobile phone is remotely connected to the server via a 5G network.

4. The vehicle remote diagnostic system of claim 1, wherein the second mobile phone is remotely connected to the server via a 5G network.

5. A vehicle remote diagnostic system, the system comprising:

a diagnostic device for connecting the vehicle to diagnose the vehicle;

the first mobile phone is directly connected with the diagnosis equipment;

and the second mobile phone is remotely connected with the first mobile phone through network punching.

6. The vehicle remote diagnostic system of claim 5, wherein the first mobile phone is directly connected to the diagnostic device via USB or bluetooth or WIFI.