CN115370453B

CN115370453B - Control method of auxiliary regeneration system of particle trapping device based on solar power supply

Info

Publication number: CN115370453B
Application number: CN202211033461.XA
Authority: CN
Inventors: 吴同; 杨航; 刘泽华; 张亮; 董立冬; 宋庆文; 刁旭; 徐宁宁; 闫涛
Original assignee: FAW Group Corp
Current assignee: FAW Group Corp
Priority date: 2022-08-26
Filing date: 2022-08-26
Publication date: 2023-11-14
Anticipated expiration: 2042-08-26
Also published as: CN115370453A

Abstract

The invention discloses a control method of an auxiliary regeneration system of a particle trapping device based on solar power supply. Wherein the method comprises the following steps: judging whether the solar charging device meets working conditions or not; judging whether the electronic control unit of the engine is in a power-on state or not under the condition that the solar charging device meets the working condition; under the condition that the electronic control unit of the engine is in a power-on state, controlling the auxiliary regeneration system of the particle trapping device to execute a standby mode, wherein the execution of the standby mode comprises the steps of acquiring working condition information of the auxiliary regeneration system of the particle trapping device; and under the condition that the engine and the working condition information meet the preset conditions and an auxiliary regeneration demand instruction is received, the standby mode is exited, and a first control instruction set is generated and used for opening the first electric valve and the air supply device. The invention solves the technical problem of lower regeneration efficiency of the particle trapping device in the related technology.

Description

Control method of auxiliary regeneration system of particle trapping device based on solar power supply

Technical Field

The invention relates to the technical field of regeneration of a vehicle engine particle capture device, in particular to a control method of an auxiliary regeneration system of a particle capture device based on solar power supply.

Background

Currently, in order to further reduce the emission of particulate matter generated during the running of passenger vehicles, various automobile manufacturers begin to adopt a technology of adding a particulate trap device to an exhaust system of an engine for vehicles. However, in the daily use process of users, especially in a part of low-temperature areas, the particle trapping device often cannot possess enough time to clean accumulated carbon in the particle trapping device by virtue of passive regeneration, and in the use process of most passenger vehicles, the problem of insufficient effective regeneration time and low regeneration efficiency of the particle trapping device (GPF or DPF) caused by too low temperature of the engine exhaust gas exists.

The prior art discloses a regeneration method, a controller and a regeneration system of a particle catcher, and the implementation scheme is that a wind source and a heat source are arranged on the basis of the particle catcher, and air flow provided by the wind source is heated by the heat source and is sent into an inlet of the particle catcher, so that the regeneration time of the particle catcher is shortened, and the regeneration efficiency of the particle catcher is improved. The technical scheme has the following defects: when the engine works under the working condition of high load, namely the exhaust back pressure of the engine (or the gas pressure in an exhaust system at the upstream inlet of the particle trapping device) is high, the power of the wind source is required to be correspondingly increased to increase the pressure of the supplied gas, otherwise, the technical purpose of the system cannot be achieved, and therefore the application working condition and the application scene of the system are limited.

Aiming at the technical problems of insufficient regeneration time and low regeneration efficiency of a particle trapping device (GPF or DPF) in the use process of most passenger vehicles in the prior art, no effective solution is proposed at present.

Disclosure of Invention

The embodiment of the invention provides a control method of an auxiliary regeneration system of a particle trapping device based on solar power supply, which at least solves the technical problem of low regeneration efficiency of the particle trapping device in the related art.

According to one embodiment of the present invention, there is provided a control method of an auxiliary regeneration system of a particle trap device based on solar power supply, the method including the steps of: judging whether the solar charging device meets working conditions or not; judging whether the electronic control unit of the engine is in a power-on state or not under the condition that the solar charging device meets the working condition; under the condition that the electronic control unit of the engine is in a power-on state, controlling the auxiliary regeneration system of the particle trapping device to execute a standby mode, wherein the execution of the standby mode comprises the steps of obtaining working condition information of the auxiliary regeneration system of the particle trapping device, closing an air supply device of the auxiliary regeneration system of the particle trapping device, closing a first electric valve, closing a second heating device and closing the first heating device; and under the condition that the engine and the working condition information meet the preset conditions and an auxiliary regeneration demand instruction is received, the standby mode is exited, and a first control instruction set is generated and used for opening the first electric valve and the air supply device.

Optionally, the operating condition information includes at least a first preset temperature value, a second preset temperature value, a first preset pressure value, a first gas pressure in a gas supplementing branch of an auxiliary regeneration system of the particle capturing device, and a gas temperature at an inlet of an upstream pipeline of the particle capturing device, and when it is determined that the engine and the operating condition information meet preset conditions, and when an auxiliary regeneration demand instruction is received, the standby mode is exited, and a first control instruction set is generated, including: judging whether an auxiliary regeneration demand instruction is received or not under the condition that the engine is in an ignition running state and the gas temperature is greater than or equal to a first preset temperature value; and under the condition that the auxiliary regeneration demand instruction is determined to be received, the first gas pressure is smaller than a first preset pressure value, and the gas temperature is smaller than a second preset temperature value, the standby mode is exited, and a first control instruction set is generated.

Optionally, the method further comprises: and generating a second control instruction set under the condition that the first gas pressure is smaller than a first preset pressure value and the gas temperature is not smaller than a second preset temperature value, wherein the second control instruction set is used for controlling the air supply device, the first electric valve, the second heating device and the first heating device to be in a closed state.

Optionally, the operating condition information includes at least a third preset temperature value, the first control instruction set includes a first control instruction and a second control instruction, and the method further includes: generating a first control instruction when the first gas pressure is smaller than a first preset pressure value, the gas temperature is smaller than a second preset temperature value and the gas temperature is smaller than a third preset temperature value, wherein the first control instruction is used for starting the second heating device; and generating a second control instruction under the condition that the first gas pressure is smaller than a first preset pressure value, the gas temperature is smaller than a second preset temperature value and the gas temperature is larger than or equal to a third preset temperature value, wherein the second control instruction is used for controlling the second heating device to be in a closed state.

Optionally, the working condition information at least includes a second preset pressure value and a second gas pressure in a pressure release branch of the auxiliary regeneration system of the particle capturing device, and the method further includes: judging whether the particle trapping device has completed regeneration; judging whether the vehicle-mounted information control display system receives an auxiliary regeneration termination instruction under the condition that the particle trapping device does not complete regeneration; determining whether the second gas pressure is greater than or equal to a second preset pressure value under the condition that the vehicle-mounted information control display system does not receive an auxiliary regeneration termination instruction; and under the condition that the second gas pressure is larger than or equal to a second preset pressure value, generating a third control instruction set, wherein the third control instruction set is used for controlling the auxiliary regeneration system of the particle trapping device to stop working and execute a standby mode, and after the standby mode is completed, exiting the standby mode and opening the second electric valve.

Optionally, the working condition information at least includes a third preset pressure value, and after the second electric valve is opened, the method further includes: judging whether the second gas pressure is smaller than a third preset pressure value or not; and under the condition that the second gas pressure is smaller than a third preset pressure value, generating a fourth control instruction set, wherein the fourth control instruction set is used for controlling the auxiliary regeneration system of the particle trapping device to stop working and executing a standby mode.

Optionally, the method further comprises: and generating a fourth control instruction set under the condition that the solar charging device does not meet the working condition, or the engine is not in an ignition running state, or the first gas pressure is not smaller than a first preset pressure value, or the particle capturing device has completed regeneration, or the vehicle-mounted information control display system receives an auxiliary regeneration termination instruction.

According to an embodiment of the present invention, there is also provided a control device for an auxiliary regeneration system of a particle capturing device based on solar power supply, including: the first judging module is used for judging whether the solar charging device meets working conditions or not; the second judging module is used for judging whether the electronic control unit of the engine is in a power-on state or not under the condition that the solar charging device meets the working condition; the control module is used for controlling the particle trapping device auxiliary regeneration system to execute a standby mode under the condition that the electronic control unit of the engine is in a power-on state, wherein the execution standby mode comprises the steps of acquiring working condition information of the particle trapping device auxiliary regeneration system, closing an air supply device of the particle trapping device auxiliary regeneration system, closing a first electric valve, closing a second heating device and closing the first heating device; the generating module is used for generating a first control instruction set when the engine and working condition information are determined to meet preset conditions and the standby mode is exited under the condition that an auxiliary regeneration demand instruction is received, wherein the first control instruction set is used for opening the first electric valve and the air supply device.

According to an embodiment of the present invention, there is further provided a processor for running a program, wherein the program is configured to execute the control method of the auxiliary regeneration system of the particle catch device based on solar power supply.

According to one embodiment of the present invention, there is also provided a vehicle having a particle trap device-assisted regeneration system controlled by any one of the methods described above.

In the embodiment of the invention, whether the solar charging device meets the working condition is judged; judging whether the electronic control unit of the engine is in a power-on state or not under the condition that the solar charging device meets the working condition; under the condition that the electronic control unit of the engine is in a power-on state, controlling the auxiliary regeneration system of the particle trapping device to execute a standby mode, wherein the execution of the standby mode comprises the steps of obtaining working condition information of the auxiliary regeneration system of the particle trapping device, closing an air supply device of the auxiliary regeneration system of the particle trapping device, closing a first electric valve, closing a second heating device and closing the first heating device; and under the condition that the engine and the working condition information meet the preset conditions and an auxiliary regeneration demand instruction is received, the standby mode is exited, and a first control instruction set is generated and used for opening the first electric valve and the air supply device. According to the method, the first electric valve and the air supply device are started under the condition that the engine and the auxiliary regeneration system of the particle trapping device meet preset conditions, so that gas introduced into the air inlet end of the particle trapping device not only comprises engine exhaust, but also comprises filtered air, the oxygen content of the gas entering the particle trapping device is improved, the regeneration efficiency of the particle trapping device is higher, the first electric valve and the air supply device are started under the condition that an auxiliary regeneration demand instruction is received for auxiliary regeneration, the auxiliary regeneration function of a vehicle is more intelligent, the corresponding auxiliary regeneration function of the particle trapping device can be selectively started according to the actual use demands of users and the comprehensive judgment result of the acquired working condition information of the auxiliary regeneration system of the particle trapping device, the technical problem that the regeneration efficiency of the particle trapping device in the related technology is lower is solved, and the regeneration efficiency of the particle trapping device is effectively improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute a limitation on the application. In the drawings:

FIG. 1 is a block diagram of the hardware architecture of an electronic device of a vehicle according to one embodiment of the application;

FIG. 2 is a flow chart of a method of controlling a solar powered particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present application;

FIG. 3 is a block diagram of a control device for a solar powered particle capture device assisted regeneration system in accordance with an alternative embodiment of the present application;

FIG. 4 is a schematic diagram of an engine particulate trap device assisted regeneration system based on solar charging energy in accordance with an alternative embodiment of the present application;

FIG. 5 is a control signal logic diagram of an engine particulate trap device assisted regeneration system based on solar charging energy in accordance with an alternative embodiment of the present application;

FIG. 6 is a logic diagram of energy transfer for an engine particulate trap assisted regeneration system based on solar charging energy in accordance with an alternative embodiment of the present application;

FIG. 7 is a general flow chart of a method of controlling a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 8 is a flow chart of a sleep mode of a control method of a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 9 is a flow chart of a standby mode of a control method of a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 10 is a flow chart of a solar charging device powered mode of operation of a method for controlling an auxiliary regeneration system of an engine particulate trap device based on solar charging power in accordance with an alternative embodiment of the present invention;

FIG. 11 is a flow chart of an engine run-particulate trap assisted regeneration mode of operation based on a solar charge powered engine particulate trap assisted regeneration system control method according to an alternative embodiment of the present invention;

FIG. 12 is a flow chart of an engine run-particulate trap auxiliary first heating mode of operation based on a solar charge powered engine particulate trap auxiliary regeneration system control method according to an alternative embodiment of the present invention;

FIG. 13 is a flow chart of a ride-on, misfired park-particulate trap device assisted regeneration mode of operation of a method of controlling a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 14 is a flow chart of a ride-on, non-fired park-particulate trap device assisted first heating mode of operation of a control method of a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 15 is a flow chart of a non-solar charging device powered mode of operation of a method of controlling a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 16 is a flow chart of an on-board power supply alone-engine on-particulate trap auxiliary regeneration mode of operation of a method of controlling a solar charge powered engine particulate trap auxiliary regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 17 is a flow chart of an on-board power supply alone-engine on-particulate trap device assisted first heating mode of operation for a control method of a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 18 is a flow chart of an on-board power supply alone-ride-on-unfired park-particulate-trap-assisted regeneration mode of operation of a method of controlling a solar-charge-based engine particulate-trap-assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 19 is a flow chart of an on-board power supply alone-ride-on-unfired park-particulate-trap-assisted first heating mode of operation of a method of controlling a solar-charge-based engine particulate-trap-assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 20 is a flow chart of a park remote pre-control mode of operation of a control method for a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 21 is a flow chart of a park remote pre-control-particulate trap device assisted regeneration mode of operation of a control method of a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention;

FIG. 22 is a flow chart of a park remote pre-control-particulate trap device assisted first heating mode of operation of a control method for a solar charge powered engine particulate trap device assisted regeneration system in accordance with an alternative embodiment of the present invention.

Wherein the above figures include the following reference numerals:

1. an energy supply controller; 2. an air cleaner; 3. an air supply device; 300. an air supply line; 301. a gas supplementing branch; 302. a pressure relief branch;

4. a first electrically operated valve; 5. a one-way valve; 6. a first pressure sensor; 7. a second heating device;

8. a first oxygen sensor; 9. a three-way catalyst; 10. a second oxygen sensor;

11. a temperature sensor; 12. a gas pressure difference sensor; 13. a first heating device; 14. a particle catcher; 141. a first pipeline; 142. a second pipeline;

15. a second pressure sensor; 16. a second electrically operated valve;

17. an engine electronic control unit; 18. a solar charging device; 19. a vehicle-mounted power supply; 20. the vehicle-mounted information control display system; 21. a remote interactive communication system; 22. a central server; 23. and a portable communication control terminal.

Detailed Description

In order that those skilled in the art will better understand the present invention, a technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present invention without making any inventive effort, shall fall within the scope of the present invention.

It should be noted that the terms "first," "second," and the like in the description and the claims of the present invention and the above figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the invention described herein may be implemented in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

According to one embodiment of the present invention, there is provided an embodiment of a method of controlling a solar powered particulate trap device assisted regeneration system, it being noted that the steps illustrated in the flowchart of the figures may be performed in a computer system, such as a set of computer executable instructions, and, although a logical sequence is illustrated in the flowchart, in some cases, the steps illustrated or described may be performed in a different order than that illustrated herein.

The method embodiments may be performed in an electronic device or similar computing device in a vehicle that includes a memory and a processor. Taking an example of operation on an electronic device of a vehicle, as shown in fig. 1, the electronic device of the vehicle may include one or more processors 102 (the processors may include, but are not limited to, a Central Processing Unit (CPU), a Graphics Processor (GPU), a Digital Signal Processing (DSP) chip, a Microprocessor (MCU), a programmable logic device (FPGA), a neural Network Processor (NPU), a Tensor Processor (TPU), an Artificial Intelligence (AI) type processor, etc., and a memory 104 for storing data. Optionally, the electronic apparatus of the automobile may further include a transmission device 106, an input/output device 108, and a display 110 for communication functions. It will be appreciated by those skilled in the art that the configuration shown in fig. 1 is merely illustrative and is not intended to limit the configuration of the electronic device of the vehicle described above. For example, the electronic device of the vehicle may also include more or fewer components than the above structural description, or have a different configuration than the above structural description.

The memory 104 may be used to store a computer program, for example, a software program of application software and a module, such as a computer program corresponding to an information processing method in an embodiment of the present invention, and the processor 102 executes the computer program stored in the memory 104 to perform various functional applications and data processing, that is, implement the information processing method described above. Memory 104 may include high-speed random access memory, and may also include non-volatile memory, such as one or more magnetic storage devices, flash memory, or other non-volatile solid-state memory. In some examples, the memory 104 may further include memory remotely located relative to the processor 102, which may be connected to the mobile terminal via a network. Examples of such networks include, but are not limited to, the internet, intranets, local area networks, mobile communication networks, and combinations thereof.

The transmission device 106 is used to receive or transmit data via a network. Specific examples of the network described above may include a wireless network provided by a communication provider of the mobile terminal. In one example, the transmission device 106 includes a network interface controller (Network Interface Controller, simply referred to as NIC) that can communicate with other network devices via a base station to communicate with the internet. In one example, the transmission device 106 may be a Radio Frequency (RF) module, which is configured to communicate with the internet wirelessly.

The display 110 may be, for example, a touch screen type Liquid Crystal Display (LCD). The liquid crystal display may enable a user to interact with a user interface of the mobile terminal. In some embodiments, the mobile terminal has a Graphical User Interface (GUI), and the user may interact with the GUI by touching finger contacts and/or gestures on the touch-sensitive surface, where the man-machine interaction functions optionally include the following interactions: executable instructions for performing the above-described human-machine interaction functions, such as creating web pages, drawing, word processing, making electronic documents, games, video conferencing, instant messaging, sending and receiving electronic mail, talking interfaces, playing digital video, playing digital music, and/or web browsing, are configured/stored in a computer program product or readable storage medium executable by one or more processors.

In this embodiment, a control method of an auxiliary regeneration system of a particle capturing device based on solar power supply of an electronic device operating on the vehicle is provided, fig. 2 is a flowchart of a control method of an auxiliary regeneration system of a particle capturing device based on solar power supply according to one embodiment of the present invention, as shown in fig. 2, the flowchart includes the following steps:

step S20, judging whether the solar charging device 18 meets the working condition;

specifically, in step S20, when it is determined whether the solar charging device 18 meets the working condition, whether the voltage value output by the solar charging device 18 (or the power value of the electric energy output by the solar charging device 18, etc.) exceeds the threshold preset by the system may be used as the basis for determining the step of the determining flow, for example, when the voltage value output by the solar charging device 18 (or the power value of the electric energy output by the solar charging device 18, etc.) reaches or exceeds the set lower threshold (where the lower threshold may be the lowest voltage value, the lowest power value, etc. required when the electric equipment is working normally), it is determined that the solar charging device 18 meets the working condition.

Step S22 of judging whether the engine electronic control unit 17 is in a power-on state or not in the case where it is determined that the solar charging device 18 satisfies the operation condition;

In one exemplary embodiment of the present application, when it is determined that the engine electronic control unit 17 is not in the power-on state, the telematics control display system 20 issues a prompt "system-related functions have stopped because the user's riding state has changed".

Specifically, in step S22, when determining whether the engine electronic control unit 17 is in the power-on state, the value (or the value of the flag bit) of the control variable of the engine electronic control unit 17 indicating that the vehicle-mounted power supply 19 is the power supply signal of the engine electronic control unit 17 may be used as a basis for determining the step of the determination flow, for example, when the value (or the value of the flag bit) of the control variable indicating that the vehicle-mounted power supply 19 is the power supply signal of the engine electronic control unit 17 is a certain preset value, it is determined that the engine electronic control unit 17 is in the power-on state.

Step S24, in the case that it is determined that the electronic control unit 17 of the engine is in the power-on state, controlling the auxiliary regeneration system of the particle capturing device to execute a standby mode, where the execution of the standby mode includes obtaining the working condition information of the auxiliary regeneration system of the particle capturing device, closing the air supply device 3 of the auxiliary regeneration system of the particle capturing device, closing the first electrically operated valve 4, closing the second electrically operated valve 16, closing the second heating device 7, and closing the first heating device 13;

In step S24, when the standby mode is executed, the air supply device 3 is turned off, the first electric valve 4 is turned off, the second electric valve 16 is turned off, the second heating device 7 is turned off, and the first heating device 13 is turned off, so that the purpose of resetting the on-off or running state of the related devices can be achieved, and certain devices can be selectively turned on as required to achieve corresponding functions, so that the subsequent operation is more convenient, the influence of the on-state of the unrelated devices on the realization of the subsequent functions is avoided, and the purpose of saving energy consumption can be achieved.

In step S26, when it is determined that the engine and the working condition information meet the preset conditions, and when an auxiliary regeneration demand command is received, the standby mode is exited, and a first control command set is generated, where the first control command set is used to open the first electrically operated valve 4 and the air supply device 3.

The auxiliary regeneration demand instruction is an auxiliary regeneration demand instruction issued by a user, and the user may transmit the auxiliary regeneration demand instruction by operating a user terminal matched with the vehicle, operating an interactive interface provided in the vehicle, or performing voice control.

Through the above steps, it is determined whether the solar charging device 18 satisfies the operation condition; in the case where it is determined that the solar charging device 18 satisfies the operation condition, it is determined whether the engine electronic control unit 17 is in the power-on state; in the case that the electronic control unit 17 of the engine is determined to be in a power-on state, controlling the auxiliary regeneration system of the particle capturing device to execute a standby mode, wherein the execution of the standby mode comprises the steps of acquiring working condition information of the auxiliary regeneration system of the particle capturing device, closing the air supply device 3 of the auxiliary regeneration system of the particle capturing device, closing the first electric valve 4, closing the second electric valve 16, closing the second heating device 7 and closing the first heating device 13; and when the engine and the working condition information are determined to meet the preset conditions, and when an auxiliary regeneration demand instruction is received, the standby mode is exited, and a first control instruction set is generated, wherein the first control instruction set is used for opening the first electric valve 4 and the air supply device 3. In the embodiment, solar charging is adopted to supply energy, the first electric valve 4 and the air supply device 3 are opened under the condition that the engine and the auxiliary regeneration system of the particle trapping device meet preset conditions, so that the gas introduced into the air inlet end of the particle trapping device 14 not only comprises engine exhaust, but also comprises filtered air, the oxygen content of the gas entering the particle trapping device 14 is improved, the regeneration efficiency of the particle trapping device 14 is higher, the first electric valve 4 and the air supply device 3 perform auxiliary regeneration under the condition that an auxiliary regeneration demand instruction is received, the auxiliary regeneration function of a vehicle is more intelligent, the corresponding auxiliary regeneration function of the particle trapping device can be selectively opened according to the actual use demand of a user and the acquired comprehensive judgment result of the working condition information of the auxiliary regeneration system of the particle trapping device, the technical problem that the regeneration efficiency of the particle trapping device in the related technology is lower is solved, and the regeneration efficiency of the particle trapping device is effectively improved.

Optionally, the operating condition information includes at least a first preset temperature value, a second preset temperature value, a first preset pressure value, a first gas pressure in a gas supplementing branch 301 of the auxiliary regeneration system of the particle capturing device, and a gas temperature at an inlet of an upstream pipeline of the particle capturing device 14, and in step S26, when it is determined that the engine and the operating condition information meet preset conditions, and when an auxiliary regeneration demand instruction is received, the standby mode is exited, and a first control instruction set is generated, including the following execution steps:

step S260, judging whether an auxiliary regeneration demand instruction is received or not under the condition that the engine is determined to be in an ignition operation state and the gas temperature is greater than or equal to a first preset temperature value;

the first preset temperature value is a second stage threshold value indicating a lower limit of a temperature range of the exhaust system of the engine, in which the particle catch device 14 is suitable for performing a regeneration process, and is used for judging whether the particle catch device 14 has been warmed up before performing the regeneration process, and when the gas temperature is determined to be greater than or equal to the first preset temperature value, it is determined that the particle catch device 14 has been warmed up. Through step S260, the regeneration function of the particle catch device 14 can be performed only after the preheating is completed, so that the operating temperature of the particle catch device 14 is ensured to be suitable, and the regeneration efficiency of the particle catch device 14 is higher.

In step S261, when it is determined that the auxiliary regeneration demand command is received, and the first gas pressure is less than the first preset pressure value, and the gas temperature is less than the second preset temperature value, the standby mode is exited, and a first control command set is generated.

The first preset pressure value is the maximum value of the gas pressure that can be delivered when the air supply device 3 works normally, and is used for judging whether the first gas pressure in the gas supplementing branch 301 of the auxiliary regeneration system of the particle capturing device is higher than the gas supply capacity of the air supply device 3, and when the first gas pressure is determined to be lower than the first preset pressure value, the air supply device 3 can supply gas. The second preset temperature value is a temperature upper limit threshold value for determining whether the air supply device 3 should enter and remain in a stopped state when the engine is in an ignition operation state and the particulate trap device 14 is in a regeneration process, and when it is determined that the gas temperature is less than the second preset temperature value, it is determined that the particulate trap device auxiliary regeneration system does not need to prohibit the auxiliary regeneration function, and the air supply device 3 does not need to be stopped accordingly. When it is determined that the first gas pressure is smaller than the first preset pressure value and the gas temperature is smaller than the second preset temperature value, it is determined that the air supply device 3 can operate, so that gas supply to the particle trapping device 14 is realized. The arrangement of the first preset pressure value and the second preset temperature value can effectively protect the system and components thereof, and avoid the damage to the corresponding components in the system caused by the fact that the particle capture device auxiliary regeneration system and the components thereof work under the condition that the actual temperature or pressure value is not suitable for starting the corresponding function of the system.

It should be noted that, the gas temperature at the inlet of the upstream pipeline of the particle capturing device 14 is measured by the temperature sensor 11, the first gas pressure in the air supplementing branch 301 of the auxiliary regeneration system of the particle capturing device is measured by the first pressure sensor 6, and the first preset temperature value, the second preset temperature value and the first preset pressure value may be stored in advance in the relevant controller (e.g. the energy supply controller 1) of the vehicle.

In an exemplary embodiment of the present application, when it is determined that the auxiliary regeneration request command is received and the first gas pressure is smaller than the first preset pressure value, the engine electronic control unit 17 sends a first prompt message to the vehicle information control display system 20, where the first prompt message is used to prompt the user that the engine operation-particle capturing device auxiliary regeneration function is being performed, where it should be understood that the first prompt message may be represented by various manners such as voice (for example, voice broadcasting through a speaker of the vehicle), text (for example, text message prompt of a display interface), a pattern (for example, lighting an associated icon on the display), and when applied to the intelligent vehicle, the first prompt message may also be sent to the user side by a wireless network, bluetooth, etc., where the user side may be an electronic device matched with the vehicle, such as a mobile phone, a tablet, a bluetooth headset, etc.

Through steps S260 to S261, it is possible to ensure that the particulate trap device 14 performs a regeneration function in the case of the completion of warm-up and that the air supply device 3 performs gas supply within the gas supply capability range. While effectively improving the regeneration efficiency of the particulate trap device 14, the relevant components in the system are protected.

Optionally, in step S261, the following steps are further performed:

in step S2610, when the first gas pressure is less than the first preset pressure value and the gas temperature is not less than the second preset temperature value, a second control instruction set is generated, where the second control instruction set is used to control the air supply device 3, the first electrically operated valve 4, the second electrically operated valve 16, the second heating device 7 and the first heating device 13 to be in a closed state.

Through step S2610, under the condition that the gas temperature is not less than the second preset temperature value, the air supply device 3, the first electric valve 4, the second electric valve 16, the second heating device 7 and the first heating device 13 are kept in the closed state, so that potential safety hazards caused by starting related devices under the condition that the corresponding functions of the system are not suitable to be started are avoided, and the system is effectively protected.

Optionally, the operating mode information includes at least a third preset temperature value, the first control instruction set includes a first control instruction and a second control instruction, and in step S261, the method further includes:

Step S2611, when the first gas pressure is less than the first preset pressure value, the gas temperature is less than the second preset temperature value, and the gas temperature is less than the third preset temperature value, generating a first control command for turning on the second heating device 7;

the third preset temperature value indicates a first stage threshold of a lower limit of a temperature range of the particle capturing device 14 suitable for performing a regeneration process, the third preset temperature value is greater than the first preset temperature value, and the third preset temperature value is used for judging whether the working temperature of the particle capturing device 14 in the regeneration process is lower than the lower limit of the temperature suitable for performing the regeneration process, so as to determine whether the second heating device 7 enters and keeps a running working state, when the gas temperature is determined to be lower than the third preset temperature value, namely, the working temperature of the particle capturing device 14 is determined to be too low, the second heating device 7 is started at the moment, the second heating device 7 can heat the gas flowing through the second heating device 7 in the gas supplementing branch 301, and the temperature of the gas in the gas supplementing branch 301 is raised, so that the working temperature of the particle capturing device 14 is in a suitable temperature value range.

In step S2612, when the first gas pressure is less than the first preset pressure value, the gas temperature is less than the second preset temperature value, and the gas temperature is greater than or equal to the third preset temperature value, a second control command is generated, and the second control command is used to control the second heating device 7 to be in the off state.

Through step S2611 and step S2612, it is determined whether the second heating device 7 needs to be turned on to raise the gas temperature at the air inlet end of the particle capturing device 14 according to the temperature numerical range where the gas temperature at the inlet of the upstream pipeline of the particle capturing device 14 is located, so that it is possible to ensure that the operating temperature of the particle capturing device 14 is appropriate, and to raise the regeneration efficiency of the particle capturing device 14.

Optionally, the operating condition information includes at least a second preset pressure value and a second gas pressure in the pressure relief branch 302 of the particle capture device auxiliary regeneration system, and after step S26, the method further includes:

step S280, judging whether the particulate trap 14 has completed regeneration;

specifically, the basis for determining whether the particulate trap 14 has completed regeneration may be: 1) Sensor signal values installed in respective systems of the engine, and data and programs such as a carbon accumulation model and a regeneration model stored in the engine electronic control unit 17; 2) The engine particle trapping device assists the gas flow output by the regeneration system air supply device 3; 3) A temperature signal measured by the temperature sensor 11, a thermodynamic model of the power of the first heating means 13 (based on the corresponding power line operating current, the operating voltage signal of the first heating means 13) and the power and time of the second heating means 7 (the accumulated time in the corresponding controller in the system), etc.

Step S282, when it is determined that the particle trap device 14 does not complete the regeneration, it is determined whether the in-vehicle information control display system 20 receives an auxiliary regeneration termination instruction;

the auxiliary regeneration termination instruction can be an auxiliary regeneration termination instruction from a user, and the user can send the auxiliary regeneration termination instruction in various modes such as operation of a remote controller, display interface interaction control, voice control and the like.

Step S284, determining whether the second gas pressure is greater than or equal to a second preset pressure value if the vehicle-mounted information control display system 20 does not receive the command to terminate the auxiliary regeneration;

the second preset pressure value represents a maximum gas pressure value that can be safely borne by the pipeline of the auxiliary regeneration system of the particle capturing device, and is used for judging whether the second electric valve 16 needs to be controlled to be opened for pressure relief. The second preset pressure value may be pre-stored in an associated controller of the vehicle (e.g., the energy supply controller 1).

In step S286, when the second gas pressure is determined to be greater than or equal to the second preset pressure value, a third control instruction set is generated, where the third control instruction set is used to control the auxiliary regeneration system of the particle capturing device to stop working and execute the standby mode, exit the standby mode after completing the standby mode, and open the second electrically operated valve 16.

In step S286, the particle capturing device is controlled to assist the regeneration system to stop working and execute a standby mode, so that each device in the system can be restored to a closed state, that is, each device in the previous working state is stopped working in time, the system damage caused by further increasing the pressure in the pipeline is avoided, after the standby mode is completed, each device is stopped working, at the moment, the second electric valve 16 is opened to release pressure, and the pressure in the pipeline can be quickly reduced.

Through step S280-step S286, under the condition that the second gas pressure is determined to be greater than or equal to the second preset pressure value, the particle capturing device auxiliary regeneration system is controlled to execute the standby mode, and the second electric valve 16 is opened after the execution of the standby mode is completed, that is, when the second gas pressure is greater than or equal to the second preset pressure value, the air supply device 3, the first electric valve 4, the second electric valve 16, the second heating device 7 and the first heating device 13 are closed first, the opening and closing or operating states of related devices are reset, and then the second electric valve 16 is opened to release pressure, so that new air is not introduced into the particle capturing device auxiliary regeneration system any more, and the air supplementing branch 301 stops supplementing the air to the particle capturing device 14, the related devices are controlled to stop working in time, so that potential safety hazards or system damage caused by further increasing the second gas pressure and working in time can be avoided, and interference to a pressure release process due to untimely stopping working of the related devices can be avoided after confirming that all devices stop working can be avoided, so that the pressure release efficiency is higher, and the second gas pressure is reduced to a reasonable range.

Optionally, the operating condition information includes at least a third preset pressure value, and after step S286, the method further includes:

step S288, judging whether the second gas pressure is smaller than a third preset pressure value;

the third preset pressure value indicates a gas pressure threshold for judging whether the pressure release process is stopped or not in the process of opening the second electrically operated valve 16 to release the pressure of the system pipeline, and when the second gas pressure is smaller than the third preset pressure value, it is determined that the pressure release is completed, and the second electrically operated valve 16 for releasing the pressure can be closed.

In step S289, when the second gas pressure is determined to be less than the third preset pressure value, a fourth control instruction set is generated, where the fourth control instruction set is used to control the auxiliary regeneration system of the particle capturing device to stop working and execute the standby mode.

Through step S288-step S289, when the second gas pressure falls to a suitable value range, the second electrically operated valve 16 is closed in time, so that the condition that the second electrically operated valve 16 is continuously opened under the condition that the pressure release process in the pressure release branch 302 is completed can be avoided, the pressure release branch 302 of the auxiliary regeneration system of the particle capturing device is kept unnecessarily communicated with the external environment, and meanwhile, the energy consumption is effectively saved, and the use cost is reduced.

In an exemplary embodiment of the present application, in the case where it is determined that the second gas pressure is less than the third preset pressure value, the generated fourth control instruction set is further used to control the engine electronic control unit 17 to send second prompting information to the vehicle information control display system 20, the second prompting information being used to prompt "the engine operation-particulate trap auxiliary regeneration function has stopped due to abnormal gas pressure in the engine particulate trap auxiliary regeneration system line".

Optionally, the method further comprises: the fourth control instruction set is generated in the case where it is determined that the solar charging device 18 does not satisfy the operation condition, or in the case where the engine is not in the ignition operation state, or in the case where the first gas pressure is not less than the first preset pressure value, or in the case where the particulate trap device 14 has completed regeneration, or in the case where the in-vehicle information control display system 20 receives the instruction to terminate the auxiliary regeneration. Through the step, the auxiliary regeneration system of the particle trapping device can be ensured to close each device in time under the corresponding condition, so that the damage of the system is avoided, and the energy consumption is saved.

In an exemplary embodiment of the present application, in the case where it is determined that the solar charging apparatus 18 does not meet the operation condition, the generated fourth control instruction set is further used to control the engine electronic control unit 17 to send third prompting information to the vehicle information control display system 20, where the third prompting information is used to prompt "the engine running-particulate capturing apparatus auxiliary regeneration function has stopped because the solar charging apparatus is not currently operating normally".

In an exemplary embodiment of the present application, in the case where it is determined that the engine is not in the ignition-on state, the generated fourth control instruction set is further used to control the engine electronic control unit 17 to send fourth prompt information to the in-vehicle information control display system 20, the fourth prompt information being used to prompt "the engine running-particulate trapping device auxiliary regeneration function has stopped because the engine has stopped running".

In an exemplary embodiment of the present application, in the case where it is determined that the first gas pressure is not less than the first preset pressure value, the generated fourth control instruction set is further used to control the engine electronic control unit 17 to send fifth prompting information to the in-vehicle information control display system 20, the fifth prompting information being used to prompt "the engine exhaust system gas pressure is greater than the regeneration system gas supply capability, the engine operation-particulate trap auxiliary regeneration function has stopped".

In one exemplary embodiment of the present application, in the event that it is determined that the particulate trap device 14 has completed regeneration, the generated fourth control instruction set is further used to control the engine electronic control unit 17 to send a sixth prompt message to the on-vehicle information control display system 20, the sixth prompt message being used to prompt that the "engine on-particulate trap device auxiliary regeneration function has been successfully executed".

In an exemplary embodiment of the present application, in the case where it is determined that the in-vehicle information control display system 20 receives the termination of the auxiliary regeneration instruction, the generated fourth control instruction set is further used to control the engine electronic control unit 17 to send seventh prompt information to the in-vehicle information control display system 20, the seventh prompt information being used to prompt "the engine on-particulate matter trapping device auxiliary regeneration function has been terminated".

The embodiment also provides a control device of the auxiliary regeneration system of the particle capturing device based on solar power supply, which is used for realizing the embodiment and the preferred implementation mode, and the description is omitted. As used below, the term "module" may be a combination of software and/or hardware that implements a predetermined function. While the means described in the following embodiments are preferably implemented in software, implementation in hardware, or a combination of software and hardware, is also possible and contemplated.

Fig. 3 is a block diagram of a control device of an auxiliary regeneration system of a particle trap device based on solar power supply according to an embodiment of the present application, as shown in fig. 3, the device includes: the first determining module 30, the first determining module 30 is configured to determine whether the solar charging device 18 meets a working condition; the second judging module 32, the second judging module 32 is configured to judge whether the electronic engine control unit 17 is in a power-on state if it is determined that the solar charging device 18 meets the working condition; the control module 34 is configured to control the auxiliary regeneration system of the particle capturing device to execute a standby mode when it is determined that the electronic control unit 17 of the engine is in a power-on state, where the execution standby mode includes acquiring working condition information of the auxiliary regeneration system of the particle capturing device, closing the air supply device 3 of the auxiliary regeneration system of the particle capturing device, closing the first electrically operated valve 4, closing the second electrically operated valve 16, closing the second heating device 7, and closing the first heating device 13; the generating module 36, the generating module 36 is configured to, when determining that the engine and the working condition information meet the preset conditions, and when receiving the auxiliary regeneration requirement instruction, exit the standby mode, and generate a first control instruction set, where the first control instruction set is used to open the first electrically operated valve 4 and the air supply device 3.

By the above means, whether the solar charging device 18 satisfies the operation condition is judged; in the case where it is determined that the solar charging device 18 satisfies the operation condition, it is determined whether the engine electronic control unit 17 is in the power-on state; in the case that the electronic control unit 17 of the engine is determined to be in a power-on state, controlling the auxiliary regeneration system of the particle capturing device to execute a standby mode, wherein the execution of the standby mode comprises the steps of acquiring working condition information of the auxiliary regeneration system of the particle capturing device, closing the air supply device 3 of the auxiliary regeneration system of the particle capturing device, closing the first electric valve 4, closing the second electric valve 16, closing the second heating device 7 and closing the first heating device 13; and when the engine and the working condition information are determined to meet the preset conditions, and when an auxiliary regeneration demand instruction is received, the standby mode is exited, and a first control instruction set is generated, wherein the first control instruction set is used for opening the first electric valve 4 and the air supply device 3. In the embodiment, solar charging is adopted to supply energy, the first electric valve 4 and the air supply device 3 are opened under the condition that the engine and the auxiliary regeneration system of the particle trapping device meet preset conditions, so that the gas introduced into the air inlet end of the particle trapping device 14 not only comprises engine exhaust, but also comprises filtered air, the oxygen content of the gas entering the particle trapping device 14 is improved, the regeneration efficiency of the particle trapping device 14 is higher, the first electric valve 4 and the air supply device 3 perform auxiliary regeneration under the condition that an auxiliary regeneration demand instruction is received, the auxiliary regeneration function of a vehicle is more intelligent, the corresponding auxiliary regeneration function of the particle trapping device can be selectively opened according to the actual use demand of a user and the acquired comprehensive judgment result of the working condition information of the auxiliary regeneration system of the particle trapping device, the technical problem that the regeneration efficiency of the particle trapping device in the related technology is lower is solved, and the regeneration efficiency of the particle trapping device is effectively improved.

It should be noted that each of the above modules may be implemented by software or hardware, and for the latter, it may be implemented by, but not limited to: the modules are all located in the same processor; alternatively, the above modules may be located in different processors in any combination.

From the description of the above embodiments, it will be clear to a person skilled in the art that the method according to the above embodiments may be implemented by means of software and a necessary general hardware platform, but of course also by means of hardware, but in many cases the former is a preferred embodiment. Based on such understanding, the technical solution of the present invention may be embodied essentially or in a part contributing to the prior art in the form of a software product stored in a storage medium (e.g. ROM/RAM, magnetic disk, optical disk) comprising instructions for causing a terminal device (which may be a mobile phone, a computer, a server, or a network device, etc.) to perform the method according to the embodiments of the present invention.

Embodiments of the present invention also provide a computer readable storage medium having a computer program stored therein, wherein the computer program is arranged to perform the steps of any of the method embodiments described above when run.

Alternatively, in the present embodiment, the above-described storage medium may be configured to store a computer program for performing the steps of:

Alternatively, in the present embodiment, the storage medium may include, but is not limited to: a usb disk, a Read-Only Memory (ROM), a random access Memory (Random Access Memory, RAM), a removable hard disk, a magnetic disk, or an optical disk, or other various media capable of storing a computer program.

Embodiments of the invention also provide a processor arranged to run a computer program to perform the steps of any of the method embodiments described above.

Alternatively, in the present embodiment, the above-described processor may be configured to execute the following steps by a computer program:

FIG. 4 is a schematic structural view of an auxiliary regeneration system (the sizes of the shapes of the components shown in the drawings are not to scale) for an engine particulate trap device based on solar charging energy supply according to an alternative embodiment of the present invention, and as shown in FIG. 4, the auxiliary regeneration system for an engine particulate trap device includes: the energy supply controller 1, the air filter 2, the air supply device 3, the air supply line 300, the air supplement line 301, the pressure relief line 302, the first electric valve 4, the one-way valve 5, the first pressure sensor 6 (i.e., the pressure sensor provided on the line from the one-way valve 5 to the second heating device 7), the second heating device 7, the first oxygen sensor 8 (i.e., the oxygen sensor provided on the line from the three-way catalyst 9), the three-way catalyst 9, the second oxygen sensor 10 (i.e., the oxygen sensor provided downstream of the three-way catalyst 9), the temperature sensor 11 (the temperature sensor 11 is provided upstream of the particle capturing device 14), the gas pressure difference sensor 12 (the gas pressure difference sensor 12 is used for detecting the gas pressure difference upstream and downstream of the particle capturing device 14), the first heating device 13, the particle capturing device 14, the first line 141, the second line 142, the second pressure sensor 15 (i.e., the pressure sensor provided on the line from the air supply device 3 to the second electric valve 16), the second electric valve 16, the engine electronic control unit 17, the solar charging device 18, the vehicle-mounted information system 21, the vehicle-mounted information communication system 20, the portable communication system, and the portable communication system. Fig. 5 is a logic relationship diagram of control signals of an auxiliary regeneration system of an engine particulate trap device based on solar charging energy (the sizes of the shapes of the components shown in the figure do not represent true proportions), and fig. 6 is a logic relationship diagram of energy transfer of the auxiliary regeneration system of the engine particulate trap device based on solar charging energy (the sizes of the shapes of the components shown in the figure do not represent true proportions).

Referring to fig. 4 to 6, the connection relationship and the working principle between the auxiliary regeneration system of the engine particle capturing device based on solar charging energy supply and other relevant components of the vehicle in the embodiment are as follows:

the energy supply controller 1 is connected with the air supply device 3, the first electric valve 4, the first pressure sensor 6, the second heating device 7, the first heating device 13, the second pressure sensor 15, the second electric valve 16 and the solar charging device 18 through signal lines and power lines; the energy supply controller 1 is connected with an engine electronic control unit 17 through a signal line. The energy supply controller 1 is used for receiving, processing and analyzing the measured parameter value signals transmitted by the sensors (such as the first pressure sensor 6 and the second pressure sensor 15) in the auxiliary regeneration system of the particle trapping device of the engine and the control parameter signals transmitted by the electronic control unit 17 of the engine, and meanwhile, the energy supply controller 1 controls the actuators in the auxiliary regeneration system of the particle trapping device to execute various instruction actions under different judging conditions according to different working modes and control methods.

The air cleaner 2 is connected to the air supply device 3 through a relevant air pipe, and the air cleaner 2 functions to filter air entering the air pipe (i.e., the air supply pipe 300) of the auxiliary regeneration system of the engine particle catch device, so as to prevent particles or impurities in the air from entering the pipe system to damage the particle catch device 14 and other relevant functional components.

The air supply device 3 is connected with the air cleaner 2, the first electrically operated valve 4 and the second electrically operated valve 16 through relevant gas pipelines, wherein a downstream gas pipeline connected with the air supply device 3 is divided into two branches: one branch (i.e. the air supplementing branch 301) is connected with the first electric valve 4, and the other branch (i.e. the pressure releasing branch 302) is connected with the second electric valve 16; the air supply device 3 is connected to the energy supply controller 1 via a signal line and an electric power line. The air supply device 3 is used for receiving the control signal of the energy supply controller 1, and providing air flow with specific pressure for the air pipeline and the particle capturing device 14 in the system under specific judging conditions according to different working modes and control methods, so that the particle capturing device 14 can efficiently and safely perform the regeneration process when the specific judging conditions are met.

The first electric valve 4 is connected with the air supply device 3 and the second electric valve 16 through related gas pipelines; the first electrically operated valve 4 is connected with the energy supply controller 1 through a signal line and an electric power line. The first electrically operated valve 4 is used for receiving a control signal of the energy supply controller 1, executing a switching instruction action under specific judging conditions according to different working modes and control methods, and allowing or preventing the gas flow in the related gas pipeline connected with the first electrically operated valve.

The one-way valve 5 is connected with the first electric valve 4 and the second heating device 7 through relevant gas pipelines, and the one-way valve 5 is used for allowing air to flow through the one-way valve under the condition that the gas pressure in the upstream gas pipeline (the gas pipeline between the one-way valve 5 and the first electric valve 4 and the same shall apply hereinafter) is higher than that in the downstream gas pipeline (the gas pipeline between the one-way valve 5 and the second heating device 7 and the same shall apply hereinafter); air flow is prevented from flowing through its upstream gas line under conditions where the gas pressure in its downstream line is greater than its upstream gas line.

The first pressure sensor 6 is arranged on the gas pipeline between the one-way valve 5 and the second heating device 7, and a measuring probe of the first pressure sensor 6 is inserted into the section of the gas pipeline (the tightness of the gas pipeline is ensured during installation); the first pressure sensor 6 is connected to the energy supply controller 1 via a signal line and a power line. The first pressure sensor 6 serves to measure the real-time gas pressure in its probe position-dependent gas line and to transmit this gas pressure value to the power supply controller 1.

The upstream of the second heating device 7 is connected with the one-way valve 5 through a relevant gas pipeline, and the downstream of the second heating device 7 is led into a gas pipeline in an engine exhaust system (namely a first pipeline 141 between the engine exhaust system three-way catalyst 9 and the engine exhaust system particle trapping device 14) through a relevant gas pipeline; the second heating device 7 is connected with the energy supply controller 1 through a signal line and an electric power line. The second heating device 7 is used for receiving the control signal of the energy supply controller 1, and heating the air flow from the air supply device 3 under specific judging conditions according to different working modes and control methods, so that the temperature value of the air flow is more approximate to the proper temperature value range required by the regeneration of the particle capturing device 14, the normal and safe regeneration process of the particle capturing device 14 is further promoted, and the regeneration efficiency of the particle capturing device 14 is improved.

The first oxygen sensor 8 is arranged on the gas pipeline at the upstream of the three-way catalyst 9, and a measuring probe of the first oxygen sensor 8 is inserted into the section of the gas pipeline (the tightness of the gas pipeline is ensured during the installation); the first oxygen sensor 8 is connected to the engine electronic control unit 17 via a signal line and a power line. The first oxygen sensor 8 is used for monitoring the oxygen concentration of exhaust gas in a gas pipeline at the upstream of the three-way catalyst 9 during the working process of the engine, and feeding back an oxygen concentration signal to the engine electronic control unit 17, so as to provide a reference basis for the engine electronic control unit 17 to control the air-fuel ratio of the mixture gas in the engine combustion chamber.

The three-way catalyst 9 is connected with an outlet of an engine exhaust manifold (or an engine exhaust turbine) and a particle trapping device 14 through relevant gas pipelines; the gas line between the three-way catalyst 9 and the particle catch arrangement 14 (i.e. the first line 141 described above) is connected to the gas line downstream of the second heating device 7 (i.e. downstream of the gas make-up line 301 described above). The three-way catalyst 9 functions to convert carbon monoxide (CO), hydrocarbons (HC), nitrogen Oxides (NO) generated during engine operation _X ) Conversion to carbon dioxide (CO) by oxidation and reduction reactions ₂ ) Water (H) ₂ O) and nitrogen (N) ₂ )。

The second oxygen sensor 10 is installed on the gas pipeline downstream of the three-way catalyst 9, and a measuring probe of the second oxygen sensor is inserted into the pipeline (the sealing performance of the pipeline should be ensured during installation); the second oxygen sensor 10 is connected to the engine electronic control unit 17 via a signal line and an electric power line. The second oxygen sensor 10 is used for monitoring the oxygen concentration of exhaust gas in a gas pipeline at the downstream of the three-way catalyst 9 in the working process of the engine, feeding back an oxygen concentration signal to the engine electronic control unit 17, comparing the oxygen concentration signal monitored by the first oxygen sensor 8, and providing a judging basis for the engine electronic control unit 17 to judge whether the three-way catalyst 9 works normally.

The temperature sensor 11 is installed on the gas pipeline at the upstream of the particle trapping device 14, and a measuring probe of the temperature sensor 11 is inserted into the section of the gas pipeline (the tightness of the pipeline should be ensured during installation); the temperature sensor 11 is connected to the engine electronic control unit 17 via a signal line and a power line. The temperature sensor 11 is used for monitoring the temperature of the gas in the gas pipeline upstream of the particle trapping device 14 during the working process of the engine, and transmitting the temperature signal to the engine electronic control unit 17, so as to provide a reference basis for the engine electronic control unit 17 to calculate the current accumulated carbon quantity and regeneration efficiency of the particle trapping device 14, judge whether the particle trapping device 14 has the condition for carrying out the corresponding regeneration process, and the like.

The gas pressure difference sensor 12 is installed on the gas pipelines at the upper and lower stream of the particle trapping device 14, and two measuring pipelines (or measuring probes) of the gas pressure difference sensor 12 are respectively inserted into the gas pipelines at the upper and lower stream of the particle trapping device 14 (the tightness of the pipelines should be ensured during installation); the gas pressure difference sensor 12 is connected to the engine electronic control unit 17 via a signal line and an electric power line. The gas pressure difference sensor 12 is used for monitoring the pressure difference of the gas in the gas pipelines at the upper and the lower stream of the particle trapping device 14 in the working process of the engine, and transmitting a gas pressure difference signal to the electronic engine control unit 17, so as to provide a reference for the electronic engine control unit 17 to judge whether the particle trapping device 14 is in a normal working state.

The first heating device 13 is wrapped outside the particle catch device 14. In order to prevent deformation of the particle catch device 14 during operation, a certain gap should be reserved between the inner side shell of the first heating device 13 and the outer shell of the particle catch device 14; to ensure safe operation of the system, the outer housing of the first heating device 13 should have good tightness and ensure insulation between its interior and the outside. The first heating device 13 is connected to the energy supply controller 1 via a signal line and an electrical line. The first heating device 13 is used for receiving the control signal of the energy supply controller 1, and heating the particle capturing device 14 under specific judging conditions according to different working modes and control methods, so that the internal temperature of the particle capturing device 14 is more approximate to a proper temperature range required by regeneration, and further the normal and safe regeneration process of the particle capturing device 14 is promoted, and the regeneration efficiency of the particle capturing device 14 is improved.

The particle trapping device 14 is connected with the three-way catalyst 9 and the second heating device 7 through relevant gas pipelines; the outer shell of the particle catch arrangement 14 is surrounded by the first heating device 13 with a certain play from the inner shell of the first heating device 13. The particulate trap 14 is used to trap and collect particulate emissions generated during operation of the engine by utilizing its internal special structure (and materials, etc.), thereby preventing the particulate emissions from being discharged into the atmosphere.

The second pressure sensor 15 is installed on the gas pipeline upstream of the second electric valve 16, and a measuring probe of the second pressure sensor 15 is inserted into the gas pipeline (the tightness of the gas pipeline should be ensured during installation); the second pressure sensor 15 is connected to the energy supply controller 1 via a signal line and a power line. The function of the second pressure sensor 15 is to measure the real-time gas pressure in the relevant gas line (the gas line downstream of the air supply 3 to upstream of the second electrically operated valve 16) of its probe position and to transmit this gas pressure value to the power supply controller 1.

The second electric valve 16 is connected with the air supply device 3 and the first electric valve 4 through related gas pipelines; the second electrically operated valve 16 is connected to the energy supply controller 1 via a signal line and an electrical line. The second electrically operated valve 16 is used for receiving the control signal of the energy supply controller 1, and opening the pressure release when the gas pressure in the gas pipeline (i.e. the pressure release branch 302) downstream of the air supply device 3 exceeds the maximum gas pressure that can be born by the gas pipeline, so as to ensure the safe operation of the system and reduce the gas pressure value in the gas pipeline to be within a reasonable range.

The engine electronic control unit 17 is connected with the energy supply controller 1, the first oxygen sensor 8, the second oxygen sensor 10, the temperature sensor 11, the gas pressure difference sensor 12 and the remote interactive communication system 21 through signal lines; the engine electronic control unit 17 is connected to the first oxygen sensor 8, the second oxygen sensor 10, the temperature sensor 11, the gas pressure difference sensor 12, and the in-vehicle power supply 19 via electric power lines. The electronic engine control unit 17 is used for receiving, processing and analyzing the measured parameter value signals from the sensors of the engine and the vehicle and the control parameter signals from the energy supply controller 1, and transmitting the control signals to the actuators of the engine and the vehicle, so that the engine and the vehicle can work safely, reliably and efficiently according to preset operation parameters, and good power performance and emission performance of the engine and the vehicle are ensured.

In the present embodiment, only the logical connection relationship between the components and systems related to the operation of the solar energy charging and energy supply is mentioned, and the logical connection relationship between the engine electronic control unit 17 and the components and systems of the engine and other sensors and actuators of the vehicle is omitted here, but the logical connection relationship between these components and systems is also indispensable for the normal operation of the engine and the vehicle.

The solar charging device 18 is connected to the energy supply controller 1 via a signal line and a power line. The solar charging device 18 is used for receiving the control signal of the energy supply controller 1, and converting solar radiation energy into electric energy through a photoelectric effect or a photochemical effect and providing electric energy for the engine particle capturing device auxiliary regeneration system or the vehicle-mounted power supply 19 under the condition that the solar charging device 18 can receive enough solar radiation energy and the engine particle capturing device auxiliary regeneration system or the vehicle-mounted power supply 19 needs the solar charging device 18 to provide electric energy.

The vehicle-mounted power supply 19 is connected with the energy supply controller 1, the engine electronic control unit 17, the vehicle-mounted information control display system 20 and the remote interactive communication system 21 through power lines. The vehicle-mounted power supply 19 is used for providing sufficient electric energy meeting the normal operating voltage for the auxiliary regeneration system of the engine particle capturing device, the engine and electric equipment of the vehicle.

The vehicle-mounted information control display system 20 is connected with the engine electronic control unit 17 through a signal line; the in-vehicle information control display system 20 is connected to the in-vehicle power supply 19 via an electric power line. The on-vehicle information control display system 20 is used for maintaining communication and data information exchange with the engine electronic control unit 17 and other vehicle control devices, displaying the working states of the whole vehicle and the systems and main components thereof for users and reporting corresponding faults.

The remote interactive communication system 21 is connected with the engine electronic control unit 17 through a signal line; the remote interactive communication system 21 is connected to the in-vehicle power supply 19 through a power line. The remote interactive communication system 21 is used for receiving control signals from the central server 22 and the portable communication control terminal 23, transmitting the control signals to the engine electronic control unit 17 and other vehicle control equipment through signal lines to execute corresponding instruction actions; at the same time, feedback signals of the status or results (ongoing, successful, failed, etc.) of the execution of the respective instruction functions are transmitted to the central server 22 via wireless communication technology.

The central server 22 performs wireless communication with the remote interactive communication system 21, the portable communication control terminal 23 by a wireless communication technology; the central server 22 may be maintained by the vehicle manufacturer or other operator-qualified enterprises or groups. The central server 22 is used for receiving the effective control signals from the portable communication control terminals 23 of the users of the products (in a certain area) in real time, evaluating the effectiveness and safety thereof, and transmitting the effective control signals to the remote interactive communication system 21 in the vehicle corresponding to the portable communication control terminals 23 after the evaluation is completed; meanwhile, feedback signals from the respective vehicle telematics systems 21 (within a certain area) are received, their effectiveness, safety are evaluated, and after the evaluation is completed, they are transmitted to the portable communication control terminals 23 of the respective product users corresponding to the telematics systems 21.

The portable communication control terminal 23 performs wireless communication with the center server 22 and the remote interactive communication system 21 in the vehicle corresponding to the portable communication control terminal 23 by wireless communication technology. The portable communication control terminal 23 serves as a remote control function carrier for providing the user with his vehicle products, and transmits instructions and control signals to the central server 22 and the remote interactive communication system 21 of the corresponding vehicle according to the user's wishes and corresponding operations. The portable communication control terminal 23 may be implemented by installing corresponding software on the mobile communication device of the user, or may be a separate mobile communication device and software.

As shown in fig. 4, in the engine particulate capturing device auxiliary regeneration system powered by solar energy charging, the airflow flows as follows:

the exhaust gas flow F1 flowing into the engine exhaust system enters the engine exhaust system from the engine combustion chamber during engine operation, flows to the gas line downstream of the three-way catalyst 9 via the engine exhaust manifold (or engine exhaust turbine), the three-way catalyst 9 and the relevant gas line, and is mixed with the gas flow F4 flowing in by the auxiliary regeneration system of the engine particulate trap device in this section of gas line (at this time, the air supply device 3 is in a normal operation state and the first electrically operated valve 4 is in an open state), forming the exhaust gas flow F2 flowing from the engine exhaust system to the atmosphere and flowing into the particulate trap device 14 and the gas line downstream thereof.

The exhaust gas flow F2 flowing from the engine exhaust system to the atmosphere flows into the atmosphere through the relevant gas line upstream of the particulate trap device 14, via the particulate trap device 14 and the gas line downstream thereof.

The air flow F3 flowing into the engine particulate matter trapping device auxiliary regeneration system flows into the downstream gas line of the air supply device 3 via the air cleaner 2, the air supply device 3 and the associated gas line under the condition that the air supply device 3 is in a normal operation state.

The gas flow F4 flowing into the engine exhaust system from the engine particle catch system auxiliary regeneration system flows into the engine exhaust system through the upstream gas pipeline of the first electric valve 4 under the condition that the air supply device 3 is in a normal working state and the first electric valve 4 is in an open state, flows into the engine exhaust system through the first electric valve 4, the one-way valve 5, the second heating device 7 and related gas pipelines, and is mixed with the exhaust gas flow F1 flowing into the engine exhaust system to form an exhaust gas flow F2 flowing into the atmosphere from the engine exhaust system and flows into the particle catch device 14 and the downstream gas pipelines thereof.

The pressure-released air flow F5 flows into the atmosphere through the upstream air pipeline of the second electrically operated valve 16 and through the second electrically operated valve 16 and related air pipelines under the condition that the first electrically operated valve 4 is in a closed state and the second electrically operated valve 16 is in an open state, when the air pressure in the downstream air pipeline of the air supply device 3 exceeds the maximum air pressure which can be borne by the air pipeline of the auxiliary regeneration system of the engine particle capturing device.

Fig. 7-22 are schematic diagrams of a control method of an auxiliary regeneration system of an engine particulate capturing device based on solar charging energy according to an alternative embodiment of the present invention, and the variables and variable names referred to in fig. 7-22 are as follows:

the real-time gas temperature value t_gpf_i_a at the inlet of the pipeline upstream of the engine particulate trap (GPF) is measured by the temperature sensor 11 and represents the real-time gas temperature value at the inlet of the pipeline upstream of the particulate trap 14.

It should be noted that the real-time gas temperature value t_gpf_i_a at the inlet of the upstream pipeline of the engine particulate trap (GPF) is the gas temperature.

The third-stage threshold t_gpfr_v_lll of the lower temperature range for which the engine particulate trap device (GPF) is suitable for regeneration is a preset control reference value stored in the energy supply controller 1, and represents the third-stage threshold of the lower temperature range for which the engine exhaust system particulate trap device 14 is suitable for regeneration (there is a numerical relationship that t_gpfr_v_lll < t_gpfr_v_ll < t_gpfr_v_l, i.e., t_gpfr_v_lll is the lower threshold with the lowest temperature value). The threshold is used to determine whether the particulate trap device 14 has been warmed up before the regeneration process is performed when the power supply controller 1 performs the vehicle power supply alone-engine operation-particulate trap device auxiliary regeneration operation mode flow steps S0100-040100.

The engine exhaust system particulate trap device (GPF) suitable regeneration temperature lower limit second stage threshold T_GPFR_V_LL is a preset control reference value stored in the power supply controller 1, representing a temperature range lower limit second stage threshold (there is a numerical relationship: T_GPFR_V_LLL < T_GPFR_V_LL < T_GPFR_V_L) at which the engine exhaust system particulate trap device 14 is suitable for performing a regeneration process. This threshold is used for two cases: in the first case, when the energy supply controller 1 executes the engine operation-particulate trap device auxiliary regeneration operation mode flow steps S0100-030100, it is determined whether the particulate trap device 14 has been warmed up before the regeneration process is performed; in the second case, when the energy supply controller 1 performs the vehicle power supply independent energy supply-engine operation-auxiliary regeneration operation mode of the particle capturing device step S0100-040100 or the vehicle power supply independent energy supply-driving non-ignition parking-auxiliary regeneration operation mode of the particle capturing device step S0100-040300, it is used to determine whether the operating temperature of the particle capturing device 14 is lower than the appropriate temperature range during the regeneration process, so as to determine whether the second heating device 7 enters and maintains the operation state.

It should be noted that the second stage threshold t_gpfr_v_ll of the suitable regeneration temperature lower limit of the engine particulate filter (GPF) is the aforementioned first preset temperature value.

The first-stage threshold t_gpfr_v_l of the lower limit of the temperature of the regeneration-suitable engine particle catch device (GPF) is a preset control reference value stored in the energy supply controller 1, and represents the first-stage threshold of the lower limit of the temperature range of the regeneration-suitable engine particle catch device 14 (there is a numerical relationship that t_gpfr_v_lll < t_gpfr_v_ll < t_gpfr_v_l, i.e., t_gpfr_v_lll is the lower threshold with the highest temperature value). The threshold value is used for judging whether the operating temperature of the particle catch device 14 is lower than a proper temperature range during the regeneration process when the energy supply controller 1 executes the steps S0100-030100 of the engine operation-particle catch device auxiliary regeneration operation mode, or executes the steps S0100-030300 of the driving non-ignition parking-particle catch device auxiliary regeneration operation mode, or executes the steps S0100-050100 of the parking remote pre-control-particle catch device auxiliary regeneration operation mode, so as to determine whether the second heating device 7 enters and maintains the operation state.

It should be noted that the first stage threshold t_gpfr_v_l of the suitable regeneration temperature lower limit of the engine particulate filter (GPF) is the aforementioned third preset temperature value.

The upper limit first-stage threshold t_gpfr_v_h of the suitable regeneration temperature of the engine particulate trap (GPF) is a preset control reference value stored in the energy supply controller 1, and represents the upper limit first-stage threshold of the temperature that determines whether the air supply device 3 should enter and keep in a stop operation state when the engine is in an ignition operation state and the particulate trap 14 performs a regeneration process, and if t_gpf_i_a is greater than or equal to t_gpfr_v_h, the air supply device 3 is controlled to enter and keep in the stop operation state.

It should be noted that the first stage threshold t_gpfr_v_h of the suitable regeneration temperature upper limit of the engine particulate filter (GPF) is the aforementioned second preset temperature value.

The upper temperature limit second stage threshold t_gpfr_v_hh of the suitable regeneration temperature of the engine particulate trap (GPF) is a preset control reference value stored in the energy supply controller 1, and indicates that when the engine is in a stop ignition operation state and the particulate trap 14 is performing a regeneration process, it is determined whether the air supply device 3 should enter and maintain the upper temperature limit second stage threshold in the stop operation state, and if t_gpf_i_a is greater than or equal to t_gpfr_v_hh, the air supply device 3 is controlled to enter and maintain the stop operation state.

The real-time gas pressure value p_gpf_i_a in the pipeline upstream of the engine particulate trap (GPF) is measured by the first pressure sensor 6 and represents the real-time gas pressure value at the inlet of the pipeline upstream of the particulate trap 14 (or at the outlet of the pipeline downstream of the one-way valve 5).

It should be noted that the real-time gas pressure value p_gpf_i_a in the pipeline upstream of the engine particulate trap (GPF) is the aforementioned first gas pressure.

The engine particulate trap auxiliary regeneration system line real-time gas pressure value p_gpfassp_o_a is measured by the second pressure sensor 15 and represents the real-time gas pressure value in the line between the downstream line outlet of the air supply device 3 and the upstream line inlet of the second electrically operated valve 16 (or from the downstream line outlet of the air supply device 3 to the upstream line inlet of the first electrically operated valve 4).

It should be noted that the real-time gas pressure value p_gpfarsp_o_a of the auxiliary regeneration system pipeline of the engine particulate trap device is the aforementioned second gas pressure.

The upper limit threshold p_gpfarsp_v_s_h of the gas pressure in the pipeline when the pressure release of the auxiliary regeneration system of the engine particle capturing device is completed is a preset control reference value stored in the energy supply controller 1, and represents the gas pressure threshold for judging whether the pressure release process is stopped or not in the process of opening the second electric valve 16 to release the pressure of the system pipeline, and if p_gpfarsp_o_a is smaller than p_gpfarsp_v_s_h, the second electric valve 16 is controlled to close to stop the pressure release process.

It should be noted that, when the pressure release of the auxiliary regeneration system of the particulate matter trapping device of the engine is completed, the upper limit threshold p_gpfarsp_v_s_h of the gas pressure in the pipeline is the third preset pressure value.

The maximum gas supply capacity of the air supply device 3 is set in such a way that the upper limit threshold value p_gpfassp_max of the gas pressure at the outlet of the downstream pipeline is a preset control reference value stored in the energy supply controller 1, and represents the maximum value of the gas pressure that can be delivered when the air supply device 3 is operating normally. The threshold value is used to determine whether the value of the gas pressure at the inlet of the upstream line of the particulate trap 14 in real time is higher than the gas supply capacity of the air supply device 3 when the system assisted regeneration related function is on.

It should be noted that the upper limit value p_gpfarsp_max of the gas pressure at the outlet of the downstream pipeline when the maximum gas supply capacity of the air supply device 3 is in operation is the aforementioned first preset pressure value.

The upper limit threshold value P_GPFARSP_V_H of the gas pressure in the pipeline when the auxiliary regeneration system of the engine particle capturing device works normally is a preset control reference value stored in the energy supply controller 1 of the solar charging and auxiliary regeneration system of the engine particle capturing device, and the preset control reference value represents the maximum gas pressure value which can be safely born by the pipeline of the auxiliary regeneration system of the engine particle capturing device. The threshold is used to determine if the system needs to control the opening of the second electrically operated valve 16 to perform the pressure relief process.

It should be noted that, when the auxiliary regeneration system of the engine particulate filter device works normally, the upper limit threshold p_gpfassp_v_h of the gas pressure in the pipeline is the aforementioned second preset pressure value.

The upper limit threshold value p_gpfarp_v_h of the gas pressure in the upstream pipeline when the engine particulate trap (GPF) is suitable for regeneration is a preset control reference value stored in the energy supply controller 1, and indicates that the particulate trap 14 has the upper limit threshold value of the gas pressure in the upstream pipeline when the particulate trap is capable of performing a regeneration process (or has normal operation). The threshold is used for judging whether the system can execute the auxiliary heating related function, and if the P_GPF_I_a is more than or equal to the P_GPFARP_V_H, the auxiliary heating related function is turned off. For most engine particulate traps and exhaust systems, there is generally a numerical relationship in design to reduce the energy consumption level of the air supply device 3: P_GPFARP_V_H is equal to or greater than P_GPFARSP_MAX.

The system cumulative waiting time upper limit threshold t_Sys_Wait_H is a preset control reference value stored in the energy supply controller 1 and represents the longest waiting time when the system waits for a certain function. If t_Sys_Wait_a is greater than or equal to t_Sys_Wait_H, the system stops waiting.

The system cumulative latency real-time value t_sys_wait_a is the cumulative latency value stored in the power supply controller 1.

The user-to-vehicle real-time distance value dist_u-c_a is calculated by the central server 22 through a positioning technique (e.g., a real-time position signal of a target object fed back by a timing ranging navigation satellite) and the user (or portable communication control terminal 23).

The upper threshold value dist_u-c_v_l of the distance between the user and the vehicle when the function related to the parking remote pre-control of the auxiliary regeneration system of the engine particulate matter trapping device is activated is a preset control reference value stored in the energy supply controller 1. The threshold is used for judging whether the system stops executing the auxiliary regeneration function when the energy supply controller 1 executes the parking remote pre-control working mode flow step S0100-050000, and if the dist_u-c_a is not less than the dist_u-c_v_l, the auxiliary regeneration function of the particle capturing device is prohibited from being started (if the auxiliary regeneration function is in progress, the function is stopped).

For the electronic engine control unit 17, the engine and the vehicle are in different running and working states, the control method of the auxiliary regeneration system of the engine particle capturing device based on solar charging energy supply of the embodiment has 5 control working modes, and comprises the following steps: the parking remote pre-control system comprises a dormant mode, a standby mode, a solar charging device energy supply working mode, a non-solar charging device energy supply working mode and a parking remote pre-control working mode. For different control working modes, the auxiliary regeneration system of the engine particle capturing device based on solar charging energy supply executes different control method flow steps, comprising the following steps: sleep mode flow steps S0100-010100, standby mode flow steps S0100-020100, solar charging device energy supply working mode flow steps S0100-030000, non-solar charging device energy supply working mode flow steps S0100-040000, and parking remote pre-control working mode flow steps S0100-050000.

When executing the solar charging device energy supply operation mode, the control method of the engine particle capturing device auxiliary regeneration system based on solar charging energy supply of the embodiment has 4 control sub-modes, including: the engine operation-particle trapping device auxiliary regeneration operation mode, the engine operation-particle trapping device auxiliary first heating operation mode, the driving non-ignition parking-particle trapping device auxiliary regeneration operation mode and the driving non-ignition parking-particle trapping device auxiliary first heating operation mode. For different control modes, the system executes different control method flow steps, including: the method comprises the steps of steps S0100-030100 of an auxiliary regeneration working mode of an engine operation-particle trapping device, steps S0100-030200 of an auxiliary first heating working mode of the engine operation-particle trapping device, steps S0100-030300 of an auxiliary regeneration working mode of a driving non-ignition parking-particle trapping device and steps S0100-030400 of an auxiliary first heating working mode of the driving non-ignition parking-particle trapping device.

When executing the non-solar charging device energy supply operation mode, the control method of the engine particle capturing device auxiliary regeneration system based on solar charging energy supply of the embodiment has 4 control sub-modes, including: the vehicle-mounted power supply independently supplies energy to the engine, the particle trapping device is assisted to regenerate the working mode, the vehicle-mounted power supply independently supplies energy to the engine, the particle trapping device is assisted to the first heating working mode, the vehicle-mounted power supply independently supplies energy to the driving non-ignition parking, the particle trapping device is assisted to regenerate the working mode, and the vehicle-mounted power supply independently supplies energy to the driving non-ignition parking, the particle trapping device is assisted to the first heating working mode. Accordingly, for different control modes, the system will execute different control method flow steps, including: the vehicle-mounted power supply independent energy supply-engine operation-particle trapping device auxiliary regeneration working mode flow steps S0100-040100, the vehicle-mounted power supply independent energy supply-engine operation-particle trapping device auxiliary first heating working mode flow steps S0100-040200, the vehicle-mounted power supply independent energy supply-driving unfired parking-particle trapping device auxiliary regeneration working mode flow steps S0100-040300, and the vehicle-mounted power supply independent energy supply-driving unfired parking-particle trapping device auxiliary first heating working mode flow steps S0100-040400.

When executing the parking remote pre-control operation mode, the control method of the engine particle capturing device auxiliary regeneration system based on solar charging energy supply of the embodiment has 2 control sub-modes, including: the parking remote pre-control-particle capturing device assists the regeneration working mode, and the parking remote pre-control-particle capturing device assists the first heating working mode. Accordingly, for different control modes, the system will execute different control method flow steps, including: the parking remote pre-control-particle capturing device assists the regeneration working mode flow steps S0100-050100, and the parking remote pre-control-particle capturing device assists the first heating working mode flow steps S0100-050200.

Specifically, fig. 7 shows a general flow chart of a control method of an auxiliary regeneration system of an engine particulate trap device powered based on solar charging, as shown in fig. 7, comprising the steps of:

after the process starts, executing the process steps S0100-000001 (the solar charging and engine particulate capturing device auxiliary regeneration system energy supply controller 1 executes the sleep mode process steps S0100-010100); executing the judging step SJ0100-000001 (whether the solar charging device 18 satisfies the working condition; and returning to and executing the judging steps SJ0100-000001 and the subsequent flow steps according to the step sequence of the control method flow.

After the process starts, executing the process steps S0100-000001 (the solar charging and engine particulate capturing device auxiliary regeneration system energy supply controller 1 executes the sleep mode process steps S0100-010100); executing the judging step SJ0100-000001 (whether the solar charging device 18 satisfies the working condition; returning to and executing the flow steps S0100-000001 and the subsequent flow steps according to the step sequence of the control method flow.

After the process starts, executing the process steps S0100-000001 (the solar charging and engine particulate capturing device auxiliary regeneration system energy supply controller 1 executes the sleep mode process steps S0100-010100); executing the judging step SJ0100-000001 (whether the solar charging device 18 meets the working condition; executing the flow steps S0100-000005 (the solar charging and engine particle capturing device auxiliary regeneration system energy supply controller 1 executes the non-solar charging device energy supply working mode flow steps S0100-040000); returning to and executing the flow steps S0100-000001 and the subsequent flow steps according to the step sequence of the control method flow.

Specifically, fig. 8 shows a flowchart of a sleep mode of a control method of an auxiliary regeneration system of an engine particulate trap device powered based on solar charging, as shown in fig. 8, the steps include:

after the flow starts, the flow steps S0100-010101 are executed (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the stopped operating state); executing the steps S0100-010102 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-010103 (the engine particle trap device assists the second heating device 7 of the regeneration system to enter and maintain the stop operation state); executing the steps S0100-010104 (the engine particle trap apparatus assists the first heating apparatus 13 of the regeneration system to enter and maintain the stopped state); executing the steps S0100-010105 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-010106 (setting and reading the value of the system accumulated waiting time upper limit variable t_Sys_Wait_H according to the system working mode); executing the steps S0100-010107 (accumulated waiting time is stored in the system accumulated waiting time variable t_Sys_Wait_a); executing the flow steps S0100-010108 (stopping the real-time data communication with the engine electronic control unit 17, leaving only the wake-up required signal communication); executing the steps S0100-010109 (stopping the supply of electrical power to all sensors in the auxiliary regeneration system); executing the steps S0100-010110 (stopping data communication with all sensors in the auxiliary regeneration system); executing the steps S0100-010111 (resetting all control parameters and control state flag parameter values of the auxiliary regeneration system); ending the flow steps S0100-010100.

Specifically, fig. 9 shows a flowchart of a standby mode of a control method of an auxiliary regeneration system of an engine particulate trap device powered based on solar charging, as shown in fig. 9, the steps include:

after the start of the flow, the flow steps S0100-020101 (maintaining real-time data communication with the engine electronic control unit 17) are performed; executing the steps S0100-020102 (maintaining power supply to all sensors in the auxiliary regeneration system); executing the flow steps S0100-020103 (maintaining data communication with all sensors in the auxiliary regeneration system and receiving the measured data signals thereof in real time); executing the flow steps S0100-020104 (reloading target values and limit values of all control parameters of the auxiliary regeneration system according to the current working mode selected by the user); executing the flow steps S0100-020105 (the engine particulate matter trapping device assists the regeneration system air supply device 3 to enter and maintain the stopped operating state); executing the steps S0100-020106 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-020107 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working state; executing the steps S0100-020108 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and keep the stop working state); executing the flow steps S0100-020109 (closing and holding the engine particulate trap auxiliary regeneration system second electrically operated valve 16); ending the flow steps S0100-020100.

Specifically, fig. 10 shows a flowchart of a solar charging device energy supply operation mode of an engine particle capturing device auxiliary regeneration system control method based on solar energy charge energy supply, and as shown in fig. 10, the steps include:

after the flow starts, the judgment flow steps SJ0100-030001 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030003 (whether the engine is in the "ignition operation" state; ending the flow steps S0100-030000.

After the flow starts, the judgment flow steps SJ0100-030001 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030003 (whether the engine is in the "ignition operation" state.

After the flow starts, the judgment flow steps SJ0100-030001 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030003 (whether the engine is in the 'ignition operation' state; ending the flow steps S0100-030000.

After the flow starts, the judgment flow steps SJ0100-030001 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judgment flow steps SJ0100-030003 (whether the engine is in the "ignition operation" state.

After the flow starts, the judgment flow steps SJ0100-030001 are executed (whether the solar charging device 18 satisfies the operation condition; ending the flow steps S0100-030000.

In fig. 10, the "parking particulate trap auxiliary regeneration" instruction refers to a particulate trap auxiliary regeneration instruction transmitted to the system on the premise that the system confirms that the vehicle driver or user is physically located inside the vehicle cabin, that is, in the "riding vehicle" use state. The "auxiliary heating instruction of the parking particle trapping device" refers to an auxiliary heating instruction of the particle trapping device sent to the system on the premise that the system confirms that a vehicle driver or a user is located in a carriage in physical space, namely, in a using state of the "driving vehicle".

Specifically, fig. 11 shows a flowchart of an engine operation-particulate trap auxiliary regeneration operation mode of an engine particulate trap auxiliary regeneration system control method based on solar charging energy, and as shown in fig. 11, the steps include:

After the flow starts, the judgment flow steps SJ0100-030101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030105 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-030103 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the steps S0100-030105 (the engine particle trap device assists the first heating device 13 of the regeneration system to enter and keep the stop working state); executing the steps S0100-030106 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judging process steps SJ0100-030107 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-030108 (feeding back to the central server 22 the information "the engine on-particulate trap auxiliary regeneration function has been successfully executed"); ending the flow steps S0100-030100.

After the flow starts, the judgment flow steps SJ0100-030101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030105 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-030103 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the steps S0100-030105 (the engine particle trap device assists the first heating device 13 of the regeneration system to enter and keep the stop working state); executing the steps S0100-030106 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judgment flow steps SJ0100-030107 (whether the engine exhaust system particulate trap device 14 has completed regeneration; flow steps S0100-030110 (feedback of information "engine on-particulate trap auxiliary regeneration function has been terminated" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-030100.

After the flow starts, the judgment flow steps SJ0100-030101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030105 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-030103 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the steps S0100-030105 (the engine particle trap device assists the first heating device 13 of the regeneration system to enter and keep the stop working state); executing the steps S0100-030106 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judgment flow steps SJ0100-030107 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-030112 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030110 (P_GPFARSP_O_a < P_GPFARSP_V_S_H; executing the steps S0100-030114 (feedback of information "engine particulate trap auxiliary regeneration system line gas pressure is abnormal, engine operation-particulate trap auxiliary regeneration function has stopped" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-030100.

After the flow starts, the judgment flow steps SJ0100-030101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030105 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-030103 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the steps S0100-030105 (the engine particle trap device assists the first heating device 13 of the regeneration system to enter and keep the stop working state); executing the steps S0100-030106 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judgment flow steps SJ0100-030107 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-030112 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030110 (P_GPFARSP_O_a < P_GPFARSP_V_S_H.

After the flow starts, the judgment flow steps SJ0100-030101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030105 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-030103 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the steps S0100-030105 (the engine particle trap device assists the first heating device 13 of the regeneration system to enter and keep the stop working state); executing the steps S0100-030106 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); the judgment flow steps SJ0100-030107 (whether the engine exhaust system particulate trap device 14 has completed regeneration.

After the flow starts, the judgment flow steps SJ0100-030101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030105 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-030103 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; after this, the flow steps S0100-030105 and subsequent flow steps thereof are performed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-030101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030105 (t_gpf_i_a < t_gpfr_v_h; executing the steps S0100-030117 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); flow steps S0100-030118 (closing and holding the engine particulate trap auxiliary regeneration system first electrically operated valve 4); flow steps S0100-030119 (engine particulate trap device assisted regeneration system second heating device 7 enters and remains inactive); flow steps S0100-030120 (engine particulate trap device assisted regeneration system first heating device 13 enters and remains inactive); after that, the judgment flow steps SJ0100-030107 and the subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-030101 (whether the solar charging device 18 satisfies the operation condition; flow steps S0100-030122 (feedback to the in-vehicle information control display system 20 and the user that "engine exhaust system gas pressure is greater than regeneration system air supply capability, engine operation-particulate trap device assisted regeneration function has stopped)"; ending the flow steps S0100-030100.

After the flow starts, the judgment flow steps SJ0100-030101 are executed (whether the solar charging device 18 satisfies the operation condition; executing flow steps S0100-030124 (executing flow steps S0100-030200); ending the flow steps S0100-030100.

After the flow starts, executing the judgment flow steps SJ0100-030101 (whether the solar charging device 18 satisfies the operation condition; flow steps S0100-030126 (feedback of information "because the engine has stopped, engine operation-particulate trap auxiliary regeneration function has stopped" to the in-vehicle information control display system 20 and the user); ending the flow steps S0100-030100.

After the flow starts, the judgment flow steps SJ0100-030101 (whether or not the solar charging device 18 satisfies the operation condition; executing the steps S0100-030128 (feedback of information "because the solar charging device is currently not operating properly, engine operation-particulate trap auxiliary regeneration function has stopped") to the in-vehicle information control display system 20 and the user; ending the flow steps S0100-030100.

Specifically, fig. 12 shows a flowchart of an engine operation-particle trap apparatus assisted first heating operation mode of an engine particle trap apparatus assisted regeneration system control method based on solar charging energy, and as shown in fig. 12, the steps include:

after the flow starts, the judgment flow steps SJ0100-030201 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030202 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030203 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030204 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030205 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030206 (the engine particle capture device assists the first heating device 13 of the regeneration system to enter and maintain the operational state); decision flow steps SJ0100-030204 are performed (whether engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; if the determination result is "yes", executing the flow steps S0100-030207 (the engine particulate trap device assists the regeneration system to stop working, and executing the standby mode flow steps S0100-020100); flow steps S0100-030208 (feedback to the telematics control display system 20 of the information "engine on-particulate trap device assisted first heating function has been successfully executed"); ending the flow steps S0100-030200.

After the flow starts, the judgment flow steps SJ0100-030201 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030202 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030203 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030204 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030205 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030206 (the engine particle capture device assists the first heating device 13 of the regeneration system to enter and maintain the operational state); decision flow steps SJ0100-030204 are performed (whether engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; if the determination result is "no", then executing the determination flow steps SJ0100-030205 (whether the in-vehicle information control display system 20 receives the "stop assist first heating" instruction from the user; flow steps S0100-030210 (feedback of information "engine on-particulate trap device assisted first heating function has been terminated" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-030200.

After the flow starts, the judgment flow steps SJ0100-030201 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030202 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030203 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030204 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030205 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030206 (the engine particle capture device assists the first heating device 13 of the regeneration system to enter and maintain the operational state); decision flow steps SJ0100-030204 are performed (whether engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; if the determination result is "no", the determination flow steps SJ0100-030205 (whether the in-vehicle information control display system 20 receives the "stop assist first heating" instruction from the user; executing the steps S0100-030212 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030207 (P_GPFARSP_O_a < P_GPFARSP_V_S_H; flow steps S0100-030214 (feedback of information "engine particulate trap assist regeneration system line gas pressure abnormality, engine run-particulate trap assist first heating function has stopped" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-030200.

After the flow starts, the judgment flow steps SJ0100-030201 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030202 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030203 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030204 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030205 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030206 (the engine particle capture device assists the first heating device 13 of the regeneration system to enter and maintain the operational state); decision flow steps SJ0100-030204 are performed (whether engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; if the determination result is "no", the determination flow steps SJ0100-030205 (whether the in-vehicle information control display system 20 receives the "stop assist first heating" instruction from the user; executing the steps S0100-030212 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030207 (P_GPFARSP_O_a < P_GPFARSP_V_S_H.

After the flow starts, the judgment flow steps SJ0100-030201 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030202 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030203 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030204 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030205 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030206 (the engine particle capture device assists the first heating device 13 of the regeneration system to enter and maintain the operational state); decision flow steps SJ0100-030204 are performed (whether engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; if the determination result is "no", the determination flow steps SJ0100-030205 (whether the in-vehicle information control display system 20 receives the "stop assist first heating" instruction from the user.

After the flow starts, the judgment flow steps SJ0100-030201 (whether the solar charging device 18 satisfies the operation condition; flow steps S0100-030216 (feedback of information "engine exhaust system line gas pressure overrun, engine run-particulate trap assist first heating function has stopped" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-030200.

After the flow starts, the judgment flow steps SJ0100-030201 (whether the solar charging device 18 satisfies the operation condition; flow steps S0100-030218 (feedback of information "because the engine has stopped, the engine operation-particulate trap device assisted first heating function has stopped" to the in-vehicle information control display system 20 and the user); ending the flow steps S0100-030200.

After the flow starts, the judgment flow steps SJ0100-030201 (whether or not the solar charging device 18 satisfies the operation condition; executing the steps S0100-030120 (feedback of information "the engine run-particle trap assists the first heating function has stopped because the solar charging device is currently not operating properly" to the in-vehicle information control display system 20 and the user); ending the flow steps S0100-030200.

Specifically, fig. 13 shows a flowchart of a driving non-ignition parking-particulate-trapping device assisted regeneration operation mode of a control method of a solar-charge-powered engine particulate-trapping device assisted regeneration system, as shown in fig. 13, including the steps of:

after the flow starts, the judgment flow steps SJ0100-030301 (whether the solar charging device 18 satisfies the operation condition; flow steps S0100-030302 (feedback of information "because engine operating state is changed, driver-by-vehicle misfire parking-particulate trap auxiliary regeneration function has stopped" to the in-vehicle information control display system 20 and the user); ending the flow steps S0100-030300.

After the flow starts, the judgment flow steps SJ0100-030301 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030305 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-030305 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030306 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-030307 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-030308 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judging process steps SJ0100-030308 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-030310 (feedback of information "driving unfired parking-particulate trap auxiliary regeneration function has been successfully executed" to the central server 22 and user); ending the flow steps S0100-030300.

After the flow starts, the judgment flow steps SJ0100-030301 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030305 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-030305 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030306 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-030307 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-030308 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judgment flow steps SJ0100-030308 (whether the engine exhaust system particulate trap device 14 has completed regeneration; flow steps S0100-030312 (information "driving un-ignited parking-particulate trap assisted regeneration function has been terminated" to the in-vehicle information control display system 20 and user feedback); ending the flow steps S0100-030300.

After the flow starts, the judgment flow steps SJ0100-030301 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030305 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-030305 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030306 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-030307 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-030308 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judgment flow steps SJ0100-030308 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-030314 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030311 (P_GPFARSP_O_a < P_GPFARSP_V_S_H; executing the steps S0100-030316 (feedback of information "engine particulate trap assisted regeneration system line gas pressure is abnormal, ride-on non-ignition park-particulate trap assisted regeneration function has stopped" to the in-vehicle information control display system 20 and the user); ending the flow steps S0100-030300.

After the flow starts, the judgment flow steps SJ0100-030301 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030305 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-030305 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030306 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-030307 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-030308 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judgment flow steps SJ0100-030308 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-030314 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030311 (P_GPFARSP_O_a < P_GPFARSP_V_S_H.

After the flow starts, the judgment flow steps SJ0100-030301 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030305 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-030305 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030306 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-030307 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-030308 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the running operation state); the determination flow steps SJ0100-030308 are executed (whether the engine exhaust system particulate trap device 14 has completed regeneration.

After the flow starts, the judgment flow steps SJ0100-030301 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030305 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-030305 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030306 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-030307 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; after this, the flow steps S0100-030308 and subsequent flow steps thereof are performed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-030301 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030305 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-030305 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-030306 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; after that, the judgment flow steps SJ0100-030307 and subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-030301 are executed (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-030305 (t_gpf_i_a < t_gpfr_v_hh; executing the steps S0100-030320 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030321 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030322 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030323 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and keep a stop working state); after that, the judgment flow steps SJ0100-030308 and subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-030301 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030325 (the feedback information "the engine exhaust system gas pressure is greater than the regeneration system air supply capability, the ride-on non-ignition parking-particulate trap auxiliary regeneration function has been stopped") to the in-vehicle information control display system 20 and the user; ending the flow steps S0100-030300.

After the flow starts, the judgment flow steps SJ0100-030301 are executed (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-030327 (to the central server 22 and the user feedback information "because the user' S riding status has changed, riding the non-ignition parking-particulate trap auxiliary regeneration function has stopped"); ending the flow steps S0100-030300.

After the flow starts, the judgment flow steps SJ0100-030301 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030329 (the control display system 20 for vehicle-mounted information and the feedback information of the user "because the solar charging device cannot work normally at present, the auxiliary regeneration function of the driving non-ignition parking-particle capturing device is stopped)"; ending the flow steps S0100-030300.

Specifically, fig. 14 shows a flowchart of a driving non-ignition parking-particulate-trapping device assist first heating operation mode of a control method of a solar-charge-powered engine particulate-trapping device assist regeneration system, as shown in fig. 14, including the steps of:

after the flow starts, the judgment flow steps SJ0100-030401 are executed (whether the solar charging device 18 satisfies the operation condition; flow steps S0100-030402 (feedback of information "because engine operating state is changed, driving of the non-ignition parking-particulate trap device to assist the first heating function has stopped" to the in-vehicle information control display system 20 and the user); ending the flow steps S0100-030400.

After the flow starts, the judgment flow steps SJ0100-030401 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030404 (engine particulate trap device assists regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030405 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030406 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030407 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030408 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and maintain the running working state); executing the judging process steps SJ0100-030405 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; flow steps S0100-030410 are performed (feedback of information "ride-on-ignition-not-on-ignition park-particulate-trapping device-assist first heating function has been successfully performed" to the in-vehicle information control display system 20; ending the flow steps S0100-030400.

After the flow starts, the judgment flow steps SJ0100-030401 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030404 (engine particulate trap device assists regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030405 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030406 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030407 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030408 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and maintain the running working state); executing the judgment flow steps SJ0100-030405 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; flow steps S0100-030412 (feedback of information "ride-on-ignition-not-ignition-park-particulate-trapping-device-assist first heating function has been terminated" to the in-vehicle information control display system 20; ending the flow steps S0100-030400.

After the flow starts, the judgment flow steps SJ0100-030401 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030404 (engine particulate trap device assists regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030405 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030406 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030407 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030408 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and maintain the running working state); executing the judgment flow steps SJ0100-030405 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-030414 (opening the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap device and maintaining); executing the judging process steps SJ0100-030408 (P_GPFARSP_O_a < P_GPFARSP_V_S_H; executing the steps S0100-030416 (feedback of information "engine particulate trap assist regeneration system line gas pressure abnormality, ride non-ignited park-particulate trap assist first heating function has stopped" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-030400.

After the flow starts, the judgment flow steps SJ0100-030401 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030404 (engine particulate trap device assists regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030405 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030406 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030407 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030408 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and maintain the running working state); executing the judgment flow steps SJ0100-030405 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-030414 (opening the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap device and maintaining); executing the judging process steps SJ0100-030408 (P_GPFARSP_O_a < P_GPFARSP_V_S_H.

After the flow starts, the judgment flow steps SJ0100-030401 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030404 (engine particulate trap device assists regeneration system air supply device 3 to enter and maintain a stopped state); executing the steps S0100-030405 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030406 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-030407 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep the working stop state); executing the steps S0100-030408 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and maintain the running working state); the judgment flow steps SJ0100-030405 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function.

After the flow starts, the judgment flow steps SJ0100-030401 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-030418 (feedback of information "engine exhaust system line gas pressure overrun, ride-on non-ignition park-particulate trap assist first heating function stopped" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-030400.

After the flow starts, the judgment flow steps SJ0100-030401 are executed (whether the solar charging device 18 satisfies the operation condition; flow steps S0100-030420 (in-vehicle information control display system 20 and user feedback information "because the user' S riding status has changed, riding the non-ignition parking-particulate trap device assisted first heating function has stopped."); ending the flow steps S0100-030400.

After the flow starts, the judgment flow steps SJ0100-030401 (whether or not the solar charging device 18 satisfies the operation condition; executing the steps S0100-030422 (feedback of information "because the solar charging device is currently not operating properly, the riding non-ignition parking-particle trap assists the first heating function has stopped") to the in-vehicle information control display system 20 and the user; ending the flow steps S0100-030400.

Specifically, fig. 15 shows a flowchart of a non-solar charging device power supply operation mode of a control method of an engine particulate capturing device auxiliary regeneration system based on solar charging power supply, and as shown in fig. 15, the steps include:

after the flow starts, the determination flow steps SJ0100-040001 are executed (whether the engine electronic control unit 17 is in the "power-on" state; executing the judging process steps SJ0100-040003 (whether the engine is in the "ignition operation" state; ending the flow steps S0100-040000.

After the flow starts, the determination flow steps SJ0100-040001 are executed (whether the engine electronic control unit 17 is in the "power-on" state; executing the judging process steps SJ0100-040003 (whether the engine is in the "ignition operation" state.

After the flow starts, the determination flow steps SJ0100-040001 are executed (whether the engine electronic control unit 17 is in the "power-on" state; executing the judging process steps SJ0100-040003 (whether the engine is in an ignition operation state; ending the flow steps S0100-040000.

After the flow starts, the determination flow steps SJ0100-040001 are executed (whether the engine electronic control unit 17 is in the "power-on" state; executing the judgment flow steps SJ0100-040003 (whether the engine is in the "ignition operation" state.

After the flow starts, the determination flow steps SJ0100-040001 are executed (whether the engine electronic control unit 17 is in the "power-on" state; ending the flow steps S0100-040000.

After the flow starts, the determination flow steps SJ0100-040001 (whether the engine electronic control unit 17 is in the "power-on" state; ending the flow steps S0100-040000.

Specifically, fig. 16 shows a flowchart of an on-vehicle power supply individual power supply-engine operation-particle trapping device auxiliary regeneration operation mode of a control method of an engine particle trapping device auxiliary regeneration system based on solar charging power supply, and as shown in fig. 16, the steps include:

after the flow starts, executing the judging flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040102 (feedback of information "because the solar charging device currently has normal operation capability, auxiliary regeneration system is attempting to switch operation mode … …" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-040100.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040106 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-040105 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040107 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the steps S0100-040107 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040108 (the engine particle capturing device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judging process steps SJ0100-040108 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-040110 (feeding back information "vehicle-mounted power supply alone-engine running-auxiliary regeneration function of the particulate trap device has been successfully executed" to the central server 22 and the user); ending the flow steps S0100-040100.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040106 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-040105 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040107 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the steps S0100-040107 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040108 (the engine particle capturing device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judgment flow steps SJ0100-040108 (whether the engine exhaust system particulate matter trapping device 14 has completed regeneration; executing the steps S0100-040112 (the information "the vehicle-mounted power supply alone-the engine running-the auxiliary regeneration function of the particulate trap has been terminated" is fed back to the vehicle-mounted information control display system 20 and the user); ending the flow steps S0100-040100.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040106 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-040105 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040107 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the steps S0100-040107 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040108 (the engine particle capturing device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judgment process steps SJ0100-040108 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-040114 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040111 (P_GPFARSP_O_a < P_GPFARSP_V_S_H; executing the steps S0100-040116 (feedback of information "engine particulate trap auxiliary regeneration system line gas pressure abnormality to the in-vehicle power supply alone-engine operation-particulate trap auxiliary regeneration function has stopped") to the in-vehicle information control display system 20 and the user; ending the flow steps S0100-040100.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040106 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-040105 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040107 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the steps S0100-040107 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040108 (the engine particle capturing device assists the regeneration system air supply device 3 to enter and maintain the running operation state); executing the judgment process steps SJ0100-040108 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-040114 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040111 (P_GPFARSP_O_a < P_GPFARSP_V_S_H.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040106 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-040105 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040107 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the steps S0100-040107 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040108 (the engine particle capturing device assists the regeneration system air supply device 3 to enter and maintain the running operation state); the judgment process steps SJ0100-040108 (whether the engine exhaust system particulate trap device 14 has completed regeneration.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040106 (T_GPF_I_a < T_GPFR_V_H; executing the steps S0100-040105 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040107 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; after that, the flow steps S0100 to 040107 and the subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040106 (t_gpf_i_a < t_gpfr_v_h; executing the steps S0100-040119 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040120 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040121 (the second heating device 7 of the auxiliary regeneration system of the engine particle capturing device enters and keeps a stop working state); executing the steps S0100-040122 (the first heating device 13 of the auxiliary regeneration system of the engine particulate matter trapping device enters and keeps a stop working state); after that, the judgment flow steps SJ0100-040108 and the subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040124 (feedback information "engine exhaust system gas pressure is greater than regeneration system air supply capability" to the in-vehicle information control display system 20 and user), vehicle power supply alone-engine operation-particle trap auxiliary regeneration function has stopped "; ending the flow steps S0100-040100.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging device 18 satisfies the operation condition; executing the process steps S0100-040126 (executing the process steps S0100-040200); ending the flow steps S0100-040100.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging apparatus 18 satisfies the operation condition; executing the steps S0100-040128 (feedback of information "because the engine has stopped operating, vehicle power supply alone-engine operating-auxiliary regeneration function of the particulate trap has stopped" to the vehicle information control display system 20 and the user); ending the flow steps S0100-040100.

After the flow starts, the judgment flow steps SJ0100-040101 (whether the solar charging apparatus 18 satisfies the operation condition; executing the steps S0100-040130 (the information "the vehicle-mounted power supply does not have a condition for supplying power to the auxiliary regeneration system, cannot execute the relevant function" is fed back to the vehicle-mounted information control display system 20 and the user); ending the flow steps S0100-040100.

Specifically, fig. 17 shows a flowchart of an on-vehicle power supply alone-engine running-particle trapping device assisting first heating operation mode of a control method of an engine particle trapping device assisting regeneration system based on solar charging, and as shown in fig. 17, the steps include:

after the flow starts, executing the judgment flow steps SJ0100-040201 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040202 (feedback of information "because the solar charging device currently has normal operation capability, auxiliary regeneration system is attempting to switch operation mode … …" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-040200.

After the flow starts, the judgment flow steps SJ0100-040201 (whether the solar charging apparatus 18 satisfies the operation condition; executing the steps S0100-040204 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop working state); executing the steps S0100-040205 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040206 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040207 (the second heating device 7 of the auxiliary regeneration system of the engine particle capturing device enters and keeps a stop working state); executing the steps S0100-040208 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judging process steps SJ0100-040205 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-040210 (the information "the vehicle-mounted power supply alone-the engine running-the particle catch device assisting the first heating function has been successfully executed" is fed back to the vehicle-mounted information control display system 20 and the user); ending the flow steps S0100-040200.

After the flow starts, the judgment flow steps SJ0100-040201 (whether the solar charging apparatus 18 satisfies the operation condition; executing the steps S0100-040204 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop working state); executing the steps S0100-040205 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040206 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040207 (the second heating device 7 of the auxiliary regeneration system of the engine particle capturing device enters and keeps a stop working state); executing the steps S0100-040208 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judging process steps SJ0100-040205 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-040212 (the information "the vehicle-mounted power supply alone-the engine running-the particle trap apparatus assisting the first heating function has been terminated" is fed back to the vehicle-mounted information control display system 20 and the user); ending the flow steps S0100-040200.

After the flow starts, the judgment flow steps SJ0100-040201 (whether the solar charging apparatus 18 satisfies the operation condition; executing the steps S0100-040204 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop working state); executing the steps S0100-040205 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040206 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040207 (the second heating device 7 of the auxiliary regeneration system of the engine particle capturing device enters and keeps a stop working state); executing the steps S0100-040208 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judging process steps SJ0100-040205 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-040214 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040208 (P_GPFARSP_O_a < P_GPFARSP_V_S_H; executing the steps S0100-040216 (feedback of information "engine particle trap auxiliary regeneration system line gas pressure abnormality to vehicle-mounted power supply alone-engine operation-particle trap auxiliary first heating function has stopped") to the vehicle-mounted information control display system 20 and the user; ending the flow steps S0100-040200.

After the flow starts, the judgment flow steps SJ0100-040201 (whether the solar charging apparatus 18 satisfies the operation condition; executing the steps S0100-040204 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop working state); executing the steps S0100-040205 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040206 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040207 (the second heating device 7 of the auxiliary regeneration system of the engine particle capturing device enters and keeps a stop working state); executing the steps S0100-040208 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judging process steps SJ0100-040205 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-040214 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040208 (P_GPFARSP_O_a < P_GPFARSP_V_S_H.

After the flow starts, the judgment flow steps SJ0100-040201 (whether the solar charging apparatus 18 satisfies the operation condition; executing the steps S0100-040204 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop working state); executing the steps S0100-040205 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040206 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040207 (the second heating device 7 of the auxiliary regeneration system of the engine particle capturing device enters and keeps a stop working state); executing the steps S0100-040208 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judgment flow steps SJ0100-040205 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function.

After the flow starts, the judgment flow steps SJ0100-040201 (whether the solar charging apparatus 18 satisfies the operation condition; executing the steps S0100-040218 (feedback of information "engine exhaust system line gas pressure overrun, vehicle power supply alone-engine running-particle trap apparatus assisted first heating function has stopped" to the vehicle information control display system 20 and user); ending the flow steps S0100-040200.

After the flow starts, the judgment flow steps SJ0100-040201 (whether the solar charging apparatus 18 satisfies the operation condition; flow steps S0100-040220 (feedback of information "because the engine has stopped running, vehicle power supply alone-engine running-particle trap apparatus assisted first heating function has stopped" to the vehicle information control display system 20 and user); ending the flow steps S0100-040200.

After the flow starts, executing the judgment flow steps SJ0100-040201 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040222 (the information "the vehicle-mounted power supply does not have a condition for supplying power to the auxiliary regeneration system, cannot execute the related function" is fed back to the vehicle-mounted information control display system 20 and the user); ending the flow steps S0100-040200.

Specifically, fig. 18 shows a flowchart of an in-vehicle power supply alone-driving non-ignition parking-particulate trap auxiliary regeneration operation mode of a control method of an engine particulate trap auxiliary regeneration system based on solar charging, and as shown in fig. 18, the steps include:

after the flow starts, executing the judging flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040302 (feedback of information "because the solar charging device currently has normal operation capability, auxiliary regeneration system is attempting to switch operation mode … …" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-040300.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040304 (the vehicle-mounted power supply is independently supplied-the driving non-ignition parking-the auxiliary regeneration function of the particle trap device has been stopped "due to the change of the engine operation state to the vehicle-mounted information control display system 20 and the user feedback information); ending the flow steps S0100-040300.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040306 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-040307 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040307 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the judgment flow steps SJ0100-040308 (is the engine exhaust system particulate trap device 14 already completed the auxiliary first heating function; if the determination result is yes, executing the steps S0100-040309 (the first heating device 13 of the auxiliary regeneration system of the engine particulate matter trapping device enters and keeps the stopped state); executing the steps S0100-040310 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the operation state); executing the judging process steps SJ0100-040309 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-040312 (providing the information "the vehicle-mounted power supply supplies power alone-the driving non-ignition parking-the auxiliary regeneration function of the particle trapping device has been successfully executed" to the central server 22 and the user feedback); ending the flow steps S0100-040300.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040306 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-040307 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040307 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the judgment flow steps SJ0100-040308 (is the engine exhaust system particulate trap device 14 already completed the auxiliary first heating function; if the determination result is yes, executing the steps S0100-040309 (the first heating device 13 of the auxiliary regeneration system of the engine particulate matter trapping device enters and keeps the stopped state); executing the steps S0100-040310 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the operation state); executing the judgment flow steps SJ0100-040309 (whether the engine exhaust system particulate matter trapping device 14 has completed regeneration; executing the steps S0100-040314 (the vehicle-mounted power supply alone-driving non-ignition parking-particle trap auxiliary regeneration function is terminated "to the vehicle-mounted information control display system 20 and the user feedback information); ending the flow steps S0100-040300.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040306 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-040307 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040307 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the judgment flow steps SJ0100-040308 (is the engine exhaust system particulate trap device 14 already completed the auxiliary first heating function; if the determination result is yes, executing the steps S0100-040309 (the first heating device 13 of the auxiliary regeneration system of the engine particulate matter trapping device enters and keeps the stopped state); executing the steps S0100-040310 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the operation state); executing the judgment process steps SJ0100-040309 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-040316 (opening the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap device and maintaining); executing the judging process steps SJ0100-040312 (P_GPFARSP_O_a < P_GPFARSP_V_S_H; executing the steps S0100-040318 (feedback of information "engine particle trap auxiliary regeneration system line gas pressure abnormality to vehicle-mounted power supply alone-driving non-ignition parking-particle trap auxiliary regeneration function has stopped") to the vehicle-mounted information control display system 20 and the user; ending the flow steps S0100-040300.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040306 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-040307 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040307 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the judgment flow steps SJ0100-040308 (is the engine exhaust system particulate trap device 14 already completed the auxiliary first heating function; if the determination result is yes, executing the steps S0100-040309 (the first heating device 13 of the auxiliary regeneration system of the engine particulate matter trapping device enters and keeps the stopped state); executing the steps S0100-040310 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the operation state); executing the judgment process steps SJ0100-040309 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-040316 (opening the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap device and maintaining); executing the judging process steps SJ0100-040312 (P_GPFARSP_O_a < P_GPFARSP_V_S_H.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040306 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-040307 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040307 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the judgment flow steps SJ0100-040308 (is the engine exhaust system particulate trap device 14 already completed the auxiliary first heating function; if the determination result is yes, executing the steps S0100-040309 (the first heating device 13 of the auxiliary regeneration system of the engine particulate matter trapping device enters and keeps the stopped state); executing the steps S0100-040310 (the engine particle trap device assists the regeneration system air supply device 3 to enter and maintain the operation state); the determination process steps SJ0100-040309 (whether the engine exhaust system particulate trap device 14 has completed regeneration.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040306 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-040307 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040307 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; executing the judgment flow steps SJ0100-040308 (is the engine exhaust system particulate trap device 14 already completed the auxiliary first heating function; if the determination result is "no", executing the flow steps S0100-040319 (the engine particulate trap device auxiliary regeneration system first heating device 13 enters and maintains the operation state); after that, the flow steps S0100 to 040310 and the subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040306 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-040307 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-040307 (T_GPF_I_a is greater than or equal to T_GPFR_V_LL; after that, the judgment flow steps SJ0100-040308 and the subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the judging process steps SJ0100-040306 (t_gpf_i_a < t_gpfr_v_hh; executing the steps S0100-040322 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040323 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040324 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040325 (the engine particle capturing device assists the first heating device 13 of the regeneration system to enter and keep the stop working state); after that, the judgment flow steps SJ0100-040309 and the subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040327 (feedback information "engine exhaust system gas pressure is greater than regeneration system air supply capability to vehicle-mounted power supply alone-driving non-ignition parking-particle trap auxiliary regeneration function has stopped") to the vehicle-mounted information control display system 20 and user; ending the flow steps S0100-040300.

After the flow starts, the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-040329 (feedback of information to the central server 22 and user "because the user' S driving state has changed, vehicle-mounted power supply is independently powered-driving non-ignition parking-particle trap auxiliary regeneration function has stopped"); ending the flow steps S0100-040300.

After the flow starts, executing the judgment flow steps SJ0100-040301 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040331 (the information "the vehicle-mounted power supply does not have a condition for supplying power to the auxiliary regeneration system, and cannot execute the related function" is fed back to the vehicle-mounted information control display system 20 and the user); ending the flow steps S0100-040300.

Specifically, fig. 19 shows a flowchart of a vehicle power supply alone-driving an unfired parking-particulate trap device-assisted first heating operation mode of a control method of an engine particulate trap device-assisted regeneration system based on solar charging, and as shown in fig. 19, the steps include:

after the flow starts, determining the flow steps SJ0100-040401 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040402 (feedback of information "because the solar charging device currently has normal operation capability, auxiliary regeneration system is attempting to switch operation mode … …" to the in-vehicle information control display system 20 and user); ending the flow steps S0100-040400.

After the flow starts, the judgment flow steps SJ0100-040401 (whether the solar charging device 18 satisfies the operation condition; flow steps S0100-040404 (feedback of information "due to engine operating state change to in-vehicle information control display system 20 and user" in-vehicle power supply alone-driving non-ignition parking-particulate trap device assisted first heating function has stopped "); ending the flow steps S0100-040400.

After the flow starts, the judgment flow steps SJ0100-040401 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040406 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop operation state); executing the steps S0100-040407 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040408 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate matter trapping device); executing the steps S0100-040409 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040410 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judging process steps SJ0100-040406 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-040412 (providing the vehicle-mounted information control display system 20 with the vehicle-mounted power supply alone-driving non-ignition parking-particle trapping device assisting the first heating function to have been successfully executed "with the user feedback information); ending the flow steps S0100-040400.

After the flow starts, the judgment flow steps SJ0100-040401 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040406 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop operation state); executing the steps S0100-040407 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040408 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate matter trapping device); executing the steps S0100-040409 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040410 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judgment flow steps SJ0100-040406 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-040414 (to the in-vehicle information control display system 20 and user feedback information "in-vehicle power supply alone-driving non-ignition parking-particle trapping device assisted first heating function has terminated"); ending the flow steps S0100-040400.

After the flow starts, the judgment flow steps SJ0100-040401 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040406 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop operation state); executing the steps S0100-040407 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040408 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate matter trapping device); executing the steps S0100-040409 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040410 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judgment flow steps SJ0100-040406 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-040416 (opening the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap device and maintaining); executing the judging process steps SJ0100-040409 (P_GPFARSP_O_a < P_GPFARSP_V_S_H; executing the steps S0100-040418 (feedback of information "engine particle trap auxiliary regeneration system line gas pressure is abnormal, vehicle power supply alone-driving non-ignition parking-particle trap auxiliary first heating function has stopped") to the vehicle information control display system 20 and the user; ending the flow steps S0100-040400.

After the flow starts, the judgment flow steps SJ0100-040401 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040406 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop operation state); executing the steps S0100-040407 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040408 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate matter trapping device); executing the steps S0100-040409 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040410 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judgment flow steps SJ0100-040406 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the steps S0100-040416 (opening the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap device and maintaining); executing the judging process steps SJ0100-040409 (P_GPFARSP_O_a < P_GPFARSP_V_S_H.

After the flow starts, the judgment flow steps SJ0100-040401 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040406 (the engine particle trap device assists the regeneration system air supply device 3 to enter and keep the stop operation state); executing the steps S0100-040407 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-040408 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate matter trapping device); executing the steps S0100-040409 (the engine particle capturing device assists the second heating device 7 of the regeneration system to enter and keep a stop working state); executing the steps S0100-040410 (the first heating device 13 of the auxiliary regeneration system of the engine particle capturing device enters and keeps running working state); executing the judgment flow steps SJ0100-040406 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function.

After the flow starts, the judgment flow steps SJ0100-040401 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040420 (the vehicle-mounted power supply independently supplies power-driving the non-ignition parking-particle trapping device to assist the first heating function is stopped "" the vehicle-mounted information control display system 20 and the user feedback information "the engine exhaust system line gas pressure is overrun); ending the flow steps S0100-040400.

After the flow starts, the judgment flow steps SJ0100-040401 (whether the solar charging device 18 satisfies the operation condition; flow steps S0100-040422 (in-vehicle information control display system 20 and user feedback information "because the user' S driving state has changed, in-vehicle power supply alone-driving non-ignition parking-particle trap apparatus auxiliary first heating function has stopped"); ending the flow steps S0100-040400.

After the flow starts, the judgment flow steps SJ0100-040401 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-040424 (the information "the vehicle-mounted power supply does not have a condition for supplying power to the auxiliary regeneration system, cannot execute the related function" is fed back to the vehicle-mounted information control display system 20 and the user); ending the flow steps S0100-040400.

Specifically, fig. 20 shows a flowchart of a parking remote pre-control operation mode of a control method of an engine particulate capturing device auxiliary regeneration system based on solar charging energy, and as shown in fig. 20, the steps include:

after the flow starts, the judgment flow steps SJ0100-050001 are executed (whether the solar charging device 18 satisfies the operation condition; ending the flow steps S0100-050000.

After the flow starts, the judgment flow step SJ0100-050001 is executed (whether the solar charging device 18 satisfies the operation condition; ending the flow steps S0100-050000.

After the flow starts, the judgment flow step SJ0100-050001 is executed (whether the solar charging device 18 satisfies the operation condition.

After the process starts, the step SJ0100-050001 of determining the process (whether the solar charging device 18 satisfies the operation condition; ending the flow steps S0100-050000.

Specifically, fig. 21 shows a flowchart of a parking remote pre-control-particle capturing device auxiliary regeneration operation mode of a control method of an engine particle capturing device auxiliary regeneration system based on solar charging energy, and as shown in fig. 21, the steps include:

after the flow starts, the judgment flow steps SJ0100-050101 (whether or not the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050102 (feedback information "because the user driving state has changed, parking remote pre-control-particle trap auxiliary regeneration function has stopped" to the central server 22 and the user); ending the flow steps S0100-050100.

After the flow starts, executing the judgment flow step SJ0100-050101 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050104 (feeding back information "parking remote pre-control-particle trap auxiliary regeneration function is being executed … …" to the central server 22 and the user); executing the judging process steps SJ0100-050105 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-050106 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-050106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-050107 (whether or not the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-050109 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the operational state); executing the judging process steps SJ0100-050108 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the steps S0100-050111 (feeding back information "parking remote pre-control-particle trap apparatus auxiliary regeneration function has been successfully executed" to the central server 22 and user); ending the flow steps S0100-050100.

After the flow starts, executing the judgment flow step SJ0100-050101 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050104 (feeding back information "parking remote pre-control-particle trap auxiliary regeneration function is being executed … …" to the central server 22 and the user); executing the judging process steps SJ0100-050105 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-050106 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-050106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-050107 (whether or not the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-050109 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the operational state); executing the judgment flow steps SJ0100-050108 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the flow steps S0100-050113 (feedback information "parking remote pre-control-particulate trap auxiliary regeneration function has been terminated" to the central server 22 and user); ending the flow steps S0100-050100.

After the flow starts, executing the judgment flow step SJ0100-050101 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050104 (feeding back information "parking remote pre-control-particle trap auxiliary regeneration function is being executed … …" to the central server 22 and the user); executing the judging process steps SJ0100-050105 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-050106 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-050106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-050107 (whether or not the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-050109 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the operational state); executing the judging process steps SJ0100-050108 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the flow steps S0100-050115 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judgment flow steps SJ0100-050111 (p_gpfarsp_o_a < p_gpfarsp_v_s_h; if the determination result is yes, executing the flow steps S0100-050116 (the engine particulate trap device assists the regeneration system to stop working, and executing the standby mode flow steps S0100-020100); executing the flow steps S0100-050117 (feedback of information "engine particle trap auxiliary regeneration system line gas pressure is abnormal, park remote pre-control-particle trap auxiliary regeneration function has stopped" to the central server 22 and user); ending the flow steps S0100-050100.

After the flow starts, executing the judgment flow step SJ0100-050101 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050104 (feeding back information "parking remote pre-control-particle trap auxiliary regeneration function is being executed … …" to the central server 22 and the user); executing the judging process steps SJ0100-050105 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-050106 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-050106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-050107 (whether or not the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-050109 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the operational state); executing the judging process steps SJ0100-050108 (whether the engine exhaust system particulate trap device 14 has completed regeneration; executing the flow steps S0100-050115 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judgment flow steps SJ0100-050111 (p_gpfarsp_o_a < p_gpfarsp_v_s_h; if the judgment result is "no", returning and executing the flow steps S0100-050115 and subsequent flow steps according to the step sequence of the control method flow.

After the flow starts, executing the judgment flow step SJ0100-050101 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050104 (feeding back information "parking remote pre-control-particle trap auxiliary regeneration function is being executed … …" to the central server 22 and the user); executing the judging process steps SJ0100-050105 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-050106 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-050106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-050107 (whether or not the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-050109 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the operational state); the judgment process steps SJ0100-050108 (whether the engine exhaust system particulate trap device 14 has completed regeneration.

After the flow starts, executing the judgment flow step SJ0100-050101 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050104 (feeding back information "parking remote pre-control-particle trap auxiliary regeneration function is being executed … …" to the central server 22 and the user); executing the judging process steps SJ0100-050105 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-050106 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-050106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; executing the judging process steps SJ0100-050107 (whether or not the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; after that, the flow steps S0100 to 050109 and subsequent flow steps thereof are performed in the step order of the control method flow.

After the flow starts, executing the judgment flow step SJ0100-050101 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050104 (feeding back information "parking remote pre-control-particle trap auxiliary regeneration function is being executed … …" to the central server 22 and the user); executing the judging process steps SJ0100-050105 (T_GPF_I_a < T_GPFR_V_HH; executing the steps S0100-050106 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-050106 (T_GPF_I_a is greater than or equal to T_GPFR_V_L; after that, the judgment flow steps SJ0100-050107 and the subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, executing the judgment flow step SJ0100-050101 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050104 (feeding back information "parking remote pre-control-particle trap auxiliary regeneration function is being executed … …" to the central server 22 and the user); executing the judging process steps SJ0100-050105 (t_gpf_i_a < t_gpfr_v_hh; executing the flow steps S0100-050121 (closing and holding the engine particulate trap auxiliary regeneration system second electrically operated valve 16); executing the steps S0100-050122 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050123 (the engine particle trapping device assists the second heating device 7 of the regeneration system to enter and keep the stop working state); executing the steps S0100-050124 (the engine particle trapping device assists the first heating device 13 of the regeneration system to enter and keep the stop working state); after that, the judgment flow steps SJ0100-050108 and the subsequent flow steps thereof are executed in the step order of the control method flow.

After the flow starts, the judgment flow steps SJ0100-050101 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050126 (feedback information "engine exhaust system gas pressure is greater than regeneration system air supply capability, park remote pre-control-particle trap device assisted regeneration function has stopped" to the central server 22 and user); ending the flow steps S0100-050100.

After the flow starts, the judgment flow steps SJ0100-050101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-050128 (accumulated waiting time is stored in the system accumulated waiting time variable t_Sys_Wait_a); executing the steps S0100-050129 (feedback of information to the central server 22 and the user "the current user is far from the vehicle, for safety, park remote pre-control-particulate trap auxiliary regeneration function is prohibited from being activated; executing the judging process steps SJ0100-050112 (whether the remote interactive communication system 21 receives the "parking remote pre-control particle capturing device auxiliary heating" instruction from the user; ending the flow steps S0100-050100.

After the flow starts, the judgment flow steps SJ0100-050101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-050128 (accumulated waiting time is stored in the system accumulated waiting time variable t_Sys_Wait_a); executing the steps S0100-050129 (feedback of information to the central server 22 and the user "the current user is far from the vehicle, for safety, park remote pre-control-particulate trap auxiliary regeneration function is prohibited from being activated; executing the judging process steps SJ0100-050112 (whether the remote interactive communication system 21 receives the "parking remote pre-control particulate trap auxiliary heating" instruction from the user; executing the flow steps S0100-050132 (feedback of information "system waiting time overrun, engine particulate matter trapping device assisted regeneration system stop working to enter sleep mode" to the central server 22 and user); ending the flow steps S0100-050100.

After the flow starts, the judgment flow steps SJ0100-050101 are executed (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-050128 (accumulated waiting time is stored in the system accumulated waiting time variable t_Sys_Wait_a); executing the steps S0100-050129 (feedback of information to the central server 22 and the user "the current user is far from the vehicle, for safety, park remote pre-control-particulate trap auxiliary regeneration function is prohibited from being activated; the judgment flow steps SJ0100-050112 (whether the remote interactive communication system 21 receives the "parking remote pre-control particle trap auxiliary heating" instruction from the user.

After the flow starts, executing the judging flow steps SJ0100-050101 (whether or not the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050134 (feedback of information to the central server 22 "because the solar charging device is currently not operating properly, the parking remote pre-control-particle capture device auxiliary regeneration function has stopped"); ending the flow steps S0100-050100.

Specifically, fig. 22 shows a flowchart of a parking remote pre-control-particle capturing device auxiliary first heating operation mode of a control method of an engine particle capturing device auxiliary regeneration system based on solar charging energy, and as shown in fig. 22, the steps include:

after the flow starts, the judgment flow steps SJ0100-050201 (whether or not the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050202 (feedback information "because the user' S driving state has changed, parking remote pre-control-particle trap apparatus assisted first heating function has stopped") to the central server 22 and the user; ending the flow steps S0100-050200.

After the flow starts, the judgment flow steps SJ0100-050201 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-050204 (feeding back information "parking remote pre-control-particle trap device assist first heating function is executing … …" to the central server 22 and user); executing the flow steps S0100-050205 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the stopped operating state); executing the flow steps S0100-050206 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050207 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050208 (the engine particle trapping device assists the second heating device 7 of the regeneration system to enter and keep the stop working state); executing the steps S0100-050209 (the engine particle trapping device assists the first heating device 13 of the regeneration system to enter and maintain the operation state); executing the judging process steps SJ0100-050204 (whether or not the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-050211 (feeding back information "parking remote pre-control-particle trap device assisted first heating function has been successfully executed" to the central server 22 and user); ending the flow steps S0100-050200.

After the flow starts, the judgment flow steps SJ0100-050201 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-050204 (feeding back information "parking remote pre-control-particle trap device assist first heating function is executing … …" to the central server 22 and user); executing the flow steps S0100-050205 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the stopped operating state); executing the flow steps S0100-050206 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050207 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050208 (the engine particle trapping device assists the second heating device 7 of the regeneration system to enter and keep the stop working state); executing the steps S0100-050209 (the engine particle trapping device assists the first heating device 13 of the regeneration system to enter and maintain the operation state); executing the judging process steps SJ0100-050204 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-050213 (feedback of information "park remote pre-control-particle trap device assisted first heating function has terminated" to the central server 22 and user); ending the flow steps S0100-050200.

After the flow starts, the judgment flow steps SJ0100-050201 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-050204 (feeding back information "parking remote pre-control-particle trap device assist first heating function is executing … …" to the central server 22 and user); executing the flow steps S0100-050205 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the stopped operating state); executing the flow steps S0100-050206 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050207 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050208 (the engine particle trapping device assists the second heating device 7 of the regeneration system to enter and keep the stop working state); executing the steps S0100-050209 (the engine particle trapping device assists the first heating device 13 of the regeneration system to enter and maintain the operation state); executing the judging process steps SJ0100-050204 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-050215 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-050207 (P_GPFARSP_O_a < P_GPFARSP_V_S_H; executing the flow steps S0100-050217 (feedback of information "engine particle trap device assisted regeneration system line gas pressure is abnormal, park remote pre-control-particle trap device assisted first heating function has terminated" to the central server 22 and user); ending the flow steps S0100-050200.

After the flow starts, the judgment flow steps SJ0100-050201 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-050204 (feeding back information "parking remote pre-control-particle trap device assist first heating function is executing … …" to the central server 22 and user); executing the flow steps S0100-050205 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the stopped operating state); executing the flow steps S0100-050206 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050207 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050208 (the engine particle trapping device assists the second heating device 7 of the regeneration system to enter and keep the stop working state); executing the steps S0100-050209 (the engine particle trapping device assists the first heating device 13 of the regeneration system to enter and maintain the operation state); executing the judging process steps SJ0100-050204 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function; executing the flow steps S0100-050215 (opening and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the judging process steps SJ0100-050207 (p_gpfarsp_o_a < p_gpfarsp_v_s_h.

After the flow starts, the judgment flow steps SJ0100-050201 (whether the solar charging device 18 satisfies the operation condition; executing the steps S0100-050204 (feeding back information "parking remote pre-control-particle trap device assist first heating function is executing … …" to the central server 22 and user); executing the flow steps S0100-050205 (the engine particulate trap device assists the regeneration system air supply device 3 to enter and maintain the stopped operating state); executing the flow steps S0100-050206 (closing and maintaining the first electrically operated valve 4 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050207 (closing and maintaining the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap); executing the steps S0100-050208 (the engine particle trapping device assists the second heating device 7 of the regeneration system to enter and keep the stop working state); executing the steps S0100-050209 (the engine particle trapping device assists the first heating device 13 of the regeneration system to enter and maintain the operation state); executing the judgment flow steps SJ0100-050204 (whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function.

After the flow starts, the judgment flow steps SJ0100-050201 (whether the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050219 (feedback of information "engine exhaust system line gas pressure overrun, park remote pre-control-particle trap assist first heating function has terminated" to the central server 22 and user); ending the flow steps S0100-050200.

After the flow starts, executing the judging flow steps SJ0100-050201 (whether or not the solar charging device 18 satisfies the operation condition; executing the flow steps S0100-050221 (feedback of information to the central server 22 and the user that "the first heating function has been stopped due to the solar charging device being unable to work normally at present, parking remote pre-control-particle capture device); ending the flow steps S0100-050200.

As an alternative embodiment, the manner of supplying energy based on solar charging may be replaced by other energy supplying solutions, for example: 1. means for braking the energy recovery power system to supply energy (including energy supply and conversion systems of pure electric vehicles, fuel cell vehicles and hybrid vehicles applying electric energy through other types); 2. the way in which the vehicle-mounted power battery supplies energy (for a pure electric vehicle); 3. the manner in which the vehicle-mounted fuel cell stack or fuel cell engine is powered (for a fuel cell car); 4. based on the wind power generation and energy supply mode; 5. based on the manner in which nuclear power is generated and supplied (including energy conversion systems based on micro thermonuclear fusion devices or micro nuclear fission reactor devices).

As an alternative embodiment, the control method of the auxiliary regeneration system of the engine particulate capturing device designed and manufactured according to the above alternative energy supply technical scheme capable of utilizing other renewable energy sources (such as wind energy and the like) is basically the same as the control method of the auxiliary regeneration system of the engine particulate capturing device based on solar charging energy supply provided by the embodiment. Only the energy supply controller 1, the engine electronic control unit 17, the solar charging device 18, the vehicle-mounted power supply 19 and other relevant components and control signal lines and system control method logic between the energy supply controller 1 and the engine particle capturing device auxiliary regeneration system are required to be changed, and besides, the control method (working mode) of the engine particle capturing device auxiliary regeneration system is not required to be changed.

As an alternative embodiment, the control method of the auxiliary regeneration system of the engine particulate capturing device based on solar charging energy provided in this embodiment is basically the same for the above energy supply alternative technical scheme that may utilize other forms of non-renewable energy sources (such as nuclear energy, natural gas, etc.) or secondary energy sources (such as electric energy, hydrogen energy, gasoline, etc.). Only the following two technical schemes need to be changed: 1. the solar charging and engine particle trapping device auxiliary regeneration system energy supply controller 1, the engine electronic control unit 17, the solar charging device 18, the vehicle-mounted power supply 19 and other relevant components, and control signal lines and system control method logic between the components; 2. the judgment condition of selecting to supply the system with alternative energy sources or to supply the system with vehicle-mounted power sources alone (when the non-renewable energy source or secondary energy equivalent stored in the vehicle is lower than a certain threshold value, the energy supply of the engine particle capturing device auxiliary regeneration system is stopped). In addition, no other control method (operation mode) of the engine particulate trap auxiliary regeneration system is required to be changed.

As an alternative embodiment, the technical solution of completing the regeneration process or the auxiliary heating process of the particulate trapping device 14 of the engine exhaust system in a remote communication manner based on the control signal line connection relationship and/or the data transmission relationship among the energy supply controller 1 of the auxiliary regeneration system of the particulate trapping device of the engine, the engine electronic control unit 17, the remote interactive communication system 21, the central server 22 and the portable communication control terminal 23 of the solar energy charging and engine may be accomplished by the following alternative technical solution: the regeneration process or the auxiliary heating process of the particulate trap device 14 of the engine exhaust system is completed by remote control of a user by using application software (or an application program, etc.) installed in (or stored in) a mobile phone (or other type of portable communication control terminal capable of completing a remote communication function) in place of the portable communication control terminal 23 in the technical scheme provided by the patent of the invention.

As an alternative embodiment, the technical solution of the auxiliary heating process of the second heating device 7 based on the auxiliary regeneration system of the engine particulate capturing device may be replaced by the technical solution of the heat exchanging device. The heat exchange device can exchange heat with gas in a gas pipeline of an auxiliary regeneration system of the engine particle capturing device by using a heat exchange working medium (such as engine cooling liquid) and a corresponding pipeline (such as a liquid pipeline connected with an engine cooling system) so as to complete a corresponding auxiliary heating process.

As an alternative embodiment, the second electrically operated valve 16 of the auxiliary regeneration system of the engine particulate trap may be replaced by a pressure relief valve having a pressure relief equal to the upper threshold p_gpfassp_v_h of the gas pressure in the pipeline when the auxiliary regeneration system of the engine particulate trap is operating normally.

As an alternative embodiment, the content is "is the solar charging device 18 satisfying the operating conditions? In all the "judging steps, whether the voltage value output by the solar charging device 18 (or the power value of the electric energy output by the solar charging device 18) exceeds a certain threshold preset by the system may be used as the judging basis of the judging steps.

As an alternative embodiment, the content is "is the engine in the 'ignition on' state? All the steps of the determination flow "(or" whether the engine ecu 17 is in the 'power-on' state.

As an alternative embodiment, the content is "is the user's ride status changed? All the judging flow steps of the' can be comprehensively used as the judging basis of the judging flow steps of the following information data: 1. the connection state or communication state between the automobile remote control key (or any other type of wireless automobile remote control device) and the vehicle currently (including state information for judging whether the automobile remote control key is inserted into a corresponding lock hole and acts or positions in the lock hole, physical position relation between the automobile remote control key and the vehicle, distance state information and the like) is judged whether the automobile remote control key is in a carriage of the vehicle or not; 2. the engine electronic control unit 17 indicates the values of the control variables (or the values of the flag bits) of the engine ignition signal, the start vehicle signal, and the power supply signal supplied from the in-vehicle power supply 19 to the engine electronic control unit 17.

As an alternative embodiment, the context is "whether the engine exhaust system particulate trap device 14 has completed the auxiliary first heating function? "all the steps of the judging process, the system can calculate to obtain the result as the judging basis of the step of the judging process by constructing a thermodynamic model based on the initial temperature value of the particle trapping device 14 of the engine exhaust system (taking the temperature signal detected by the temperature sensor 11 at the upstream of the particle trapping device of the engine as the reference basis), the power of the first heating device 13 of the auxiliary regeneration system of the particle trapping device of the engine (taking the working current of the corresponding electric line and the working voltage signal of the first heating device 13 of the auxiliary regeneration system of the particle trapping device of the engine as the reference basis) and time (the accumulated time in the corresponding controller in the system).

As an alternative embodiment, the content is "is the engine exhaust system particulate trap device 14 has completed regeneration? All the judging flow steps of the' can be comprehensively used as the judging basis of the judging flow steps of the following information data: 1. sensor signal values installed in respective systems of the engine, and data and programs such as a carbon accumulation model and a regeneration model stored in the engine electronic control unit 17; 2. the engine particle trapping device assists the gas flow output by the regeneration system air supply device 3; 3. thermodynamic models based on the temperature signal detected by the temperature sensor 11 upstream of the engine particle catch system, the power of the first heating device 13 of the auxiliary regeneration system of the engine particle catch system (based on the corresponding power line operating current and the operating voltage signal of the first heating device 13 of the auxiliary regeneration system of the engine particle catch system), the power of the second heating device 7 of the auxiliary regeneration system of the engine particle catch system, and time (accumulated time in the corresponding controller of the system), etc.

As an alternative embodiment, the engine particle catch arrangement auxiliary regeneration system second heating device 7 and the engine particle catch arrangement auxiliary regeneration system first heating device 13 may be designed as PTC (Positive Temperature Coefficient) heaters as auxiliary heating devices for electric energy-thermal energy conversion.

The technical scheme of the auxiliary regeneration system and the control method of the engine particle capturing device based on solar charging energy provided in the embodiment is that, on the basis of the existing technical scheme of the engine particle capturing device, a vehicle-mounted solar charging device 18, an auxiliary regeneration system air supply device 3, an auxiliary regeneration system heating device (an auxiliary regeneration system first heating device 13 and an auxiliary regeneration system second heating device 7) and a corresponding control method are added: providing electric energy for an auxiliary regeneration system of the engine particle capturing device and other electric equipment of the vehicle under the condition that the solar radiation energy is sufficient by utilizing the vehicle-mounted solar charging device 18; controlling the auxiliary regeneration system air supply device 3 to provide sufficient air (oxygen) flow for the engine particulate capturing device when the engine particulate capturing device meets the regeneration condition under a specific judgment condition; the first heating device 13 of the auxiliary regeneration system is used for controlling the first heating device to provide a heat source for the engine particle trapping device 14 under a specific judging condition, so that the working temperature of the first heating device can reach a reasonable temperature range required by regeneration more quickly; the secondary heating device 7 of the auxiliary regeneration system is used for controlling the secondary heating device to provide a heat source for the air flow generated by the air supply device 3 of the auxiliary regeneration system under a specific judging condition, so that the temperature of the air flow is more approximate to the temperature required for regeneration of the engine particle capturing device 14, and the normal and safe regeneration process of the engine particle capturing device 14 is further promoted. In addition, the scheme utilizes the wireless communication technology means, under the specific judging condition, a user can utilize the portable communication control terminal to wirelessly communicate with the central server, command signals such as 'engine particle trapping device pre-control auxiliary heating' are transmitted to the remote interactive communication system, and the user wakes up related systems in the vehicle and executes corresponding action commands, so that the engine particle trapping device 14 can reach a proper working temperature range more quickly when the user uses the vehicle, and finally the purposes of energy conservation and emission reduction are achieved.

The embodiment of the application also provides a vehicle, which comprises a particle trapping device auxiliary regeneration system and a control method thereof, wherein the particle trapping device auxiliary regeneration system is the particle trapping device auxiliary regeneration system in the embodiment.

Alternatively, specific examples in this embodiment may refer to examples described in the foregoing embodiments and optional implementations, and this embodiment is not described herein.

The foregoing embodiment numbers of the present application are merely for the purpose of description, and do not represent the advantages or disadvantages of the embodiments.

In the foregoing embodiments of the present application, the descriptions of the embodiments are emphasized, and for a portion of this disclosure that is not described in detail in this embodiment, reference is made to the related descriptions of other embodiments.

In the several embodiments provided in the present application, it should be understood that the disclosed technology may be implemented in other manners. The above-described embodiments of the apparatus are merely exemplary, and the division of the units, for example, may be a logic function division, and may be implemented in another manner, for example, a plurality of units or components may be combined or may be integrated into another system, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be through some interfaces, units or modules, or may be in electrical or other forms.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

In addition, each functional unit in the embodiments of the present invention may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit. The integrated units may be implemented in hardware or in software functional units.

The integrated units, if implemented in the form of software functional units and sold or used as stand-alone products, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention may be embodied essentially or in part or all of the technical solution or in part in the form of a software product stored in a storage medium, including instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to perform all or part of the steps of the method according to the embodiments of the present invention. And the aforementioned storage medium includes: a U-disk, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a removable hard disk, a magnetic disk, or an optical disk, or other various media capable of storing program codes.

The foregoing is merely a preferred embodiment of the present invention and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present invention, which are intended to be comprehended within the scope of the present invention.

Claims

1. The control method of the auxiliary regeneration system of the particle trapping device based on solar power supply is characterized in that the auxiliary regeneration system of the particle trapping device comprises the following steps: the system comprises an energy supply controller (1), an air filter (2), an air supply device (3), an air supply pipeline (300), an air supplementing branch (301), a pressure releasing branch (302), a first electric valve (4), a one-way valve (5), a first pressure sensor (6), a second heating device (7), a first oxygen sensor (8), a three-way catalyst (9), a second oxygen sensor (10), a temperature sensor (11), a gas pressure difference sensor (12), a first heating device (13), a particle capturing device (14), a first pipeline (141), a second pipeline (142), a second pressure sensor (15), a second electric valve (16), an engine electronic control unit (17), a solar charging device (18), a vehicle-mounted power supply (19), a vehicle-mounted information control display system (20), a remote interactive communication system (21), a central server (22) and a portable communication control terminal (23); the first pressure sensor (6) is arranged on a pipeline from the one-way valve (5) to the second heating device (7), the first oxygen sensor (8) is arranged on the upstream of the three-way catalyst (9), the second oxygen sensor (10) is arranged on the downstream of the three-way catalyst (9), the temperature sensor (11) is arranged on the upstream of the particle trapping device (14), the gas pressure difference sensor (12) is used for detecting the gas pressure difference between the upstream and the downstream of the particle trapping device (14), the second pressure sensor (15) is arranged on a pipeline from the air supply device (3) to the second electric valve (16), the air supply device (3) is arranged on the air supply pipeline (300), the downstream gas pipeline connected with the air supply device (3) is divided into two branches, the two branches are respectively a gas supplementing branch (301) and a pressure releasing branch (302), the first electric valve (4) is arranged on the gas supplementing branch (301), the second electric valve (16) is arranged on the pressure releasing branch (302), the particle trapping device (14) is arranged on the first pipeline (141) and is arranged on the downstream of the three-way catalyst (9) and is arranged on the second electric branch (14) and is arranged on the outer part of the air trapping device (7); the air supply device (3), the first electric valve (4), the second electric valve (16), the first heating device (13), the second heating device (7) and the solar charging device (18) are all connected with the energy supply controller (1) through signal lines and power lines; the solar charging device (18) is used for receiving a control signal of the energy supply controller (1), converting solar radiation energy into electric energy through a photoelectric effect or a photochemical effect and providing electric energy for the particle capture device auxiliary regeneration system under the condition that the solar charging device (18) can receive enough solar radiation energy and the particle capture device auxiliary regeneration system needs the solar charging device (18) to provide electric energy; the control method comprises the following steps:

Judging whether the solar charging device (18) meets the working condition or not;

judging whether an engine electronic control unit (17) is in a power-on state or not under the condition that the solar charging device (18) meets working conditions;

under the condition that the electronic control unit (17) of the engine is in a power-on state, controlling the auxiliary regeneration system of the particle trapping device to execute a standby mode, wherein the execution of the standby mode comprises the steps of acquiring working condition information of the auxiliary regeneration system of the particle trapping device, closing an air supply device (3) of the auxiliary regeneration system of the particle trapping device, closing a first electric valve (4), closing a second electric valve (16), closing a second heating device (7) and closing a first heating device (13);

when the engine and the working condition information are determined to meet preset conditions, and an auxiliary regeneration demand instruction is received, the standby mode is exited, and a first control instruction set is generated and used for opening the first electric valve (4) and the air supply device (3);

the working condition information at least comprises a first preset temperature value, a second preset temperature value, a first preset pressure value, a first gas pressure in a gas supplementing branch (301) of the auxiliary regeneration system of the particle trapping device, and a gas temperature at an inlet of an upstream pipeline of the particle trapping device (14), and the working condition information is determined to meet preset conditions, and the standby mode is exited under the condition that the auxiliary regeneration demand instruction is received, so that a first control instruction set is generated, and the working condition information comprises:

Judging whether the auxiliary regeneration demand instruction is received or not under the condition that the engine is in an ignition running state and the gas temperature is greater than or equal to the first preset temperature value;

and under the condition that the auxiliary regeneration demand instruction is received, the first gas pressure is smaller than the first preset pressure value, and the gas temperature is smaller than the second preset temperature value, the standby mode is exited, and the first control instruction set is generated.

2. The method according to claim 1, wherein the method further comprises:

and under the condition that the first gas pressure is smaller than the first preset pressure value and the gas temperature is not smaller than the second preset temperature value, generating a second control instruction set, wherein the second control instruction set is used for controlling the air supply device (3), the first electric valve (4), the second electric valve (16), the second heating device (7) and the first heating device (13) to be in a closed state.

3. The method of claim 1, wherein the operating condition information includes at least a third preset temperature value, the first set of control instructions includes a first control instruction and a second control instruction, the method further comprising:

Generating the first control command for turning on the second heating device (7) when the first gas pressure is smaller than the first preset pressure value, the gas temperature is smaller than the second preset temperature value, and the gas temperature is smaller than the third preset temperature value;

and generating the second control instruction under the condition that the first gas pressure is smaller than the first preset pressure value, the gas temperature is smaller than the second preset temperature value and the gas temperature is larger than or equal to the third preset temperature value, wherein the second control instruction is used for controlling the second heating device (7) to be in a closed state.

4. The method of claim 1 or 2, the operating condition information comprising at least a second preset pressure value and a second gas pressure within a pressure relief branch (302) of the particle trap auxiliary regeneration system, the method further comprising:

judging whether the particle catch device (14) has completed regeneration;

under the condition that the particle trapping device (14) is not complete in regeneration, judging whether a vehicle-mounted information control display system (20) receives an auxiliary regeneration termination instruction or not;

Determining whether the second gas pressure is greater than or equal to the second preset pressure value under the condition that the vehicle-mounted information control display system (20) does not receive the auxiliary regeneration termination instruction;

and under the condition that the second gas pressure is larger than or equal to the second preset pressure value, generating a third control instruction set, wherein the third control instruction set is used for controlling the auxiliary regeneration system of the particle trapping device to stop working and execute the standby mode, exiting the standby mode after the standby mode is completed and opening the second electric valve (16).

5. The method according to claim 4, wherein the operating condition information includes at least a third preset pressure value, and wherein after opening the second electrically operated valve (16), the method further comprises:

judging whether the second gas pressure is smaller than the third preset pressure value or not;

and under the condition that the second gas pressure is smaller than the third preset pressure value, generating a fourth control instruction set, wherein the fourth control instruction set is used for controlling the auxiliary regeneration system of the particle trapping device to stop working and executing the standby mode.

6. The method of claim 5, wherein the method further comprises:

The fourth control instruction set is generated in a case where it is determined that the solar charging device (18) does not satisfy the operating condition, or in a case where the engine is not in the ignition operation state, or in a case where the first gas pressure is not less than the first preset pressure value, or in a case where the particulate trapping device (14) has completed regeneration, or in a case where the in-vehicle information control display system (20) receives the termination auxiliary regeneration instruction.

7. A control device of an auxiliary regeneration system of a particle capturing device based on solar power supply, which is characterized in that the auxiliary regeneration system of the particle capturing device comprises: the system comprises an energy supply controller (1), an air filter (2), an air supply device (3), an air supply pipeline (300), an air supplementing branch (301), a pressure releasing branch (302), a first electric valve (4), a one-way valve (5), a first pressure sensor (6), a second heating device (7), a first oxygen sensor (8), a three-way catalyst (9), a second oxygen sensor (10), a temperature sensor (11), a gas pressure difference sensor (12), a first heating device (13), a particle capturing device (14), a first pipeline (141), a second pipeline (142), a second pressure sensor (15), a second electric valve (16), an engine electronic control unit (17), a solar charging device (18), a vehicle-mounted power supply (19), a vehicle-mounted information control display system (20), a remote interactive communication system (21), a central server (22) and a portable communication control terminal (23); the first pressure sensor (6) is arranged on a pipeline from the one-way valve (5) to the second heating device (7), the first oxygen sensor (8) is arranged on the upstream of the three-way catalyst (9), the second oxygen sensor (10) is arranged on the downstream of the three-way catalyst (9), the temperature sensor (11) is arranged on the upstream of the particle trapping device (14), the gas pressure difference sensor (12) is used for detecting the gas pressure difference between the upstream and the downstream of the particle trapping device (14), the second pressure sensor (15) is arranged on a pipeline from the air supply device (3) to the second electric valve (16), the air supply device (3) is arranged on the air supply pipeline (300), the downstream gas pipeline connected with the air supply device (3) is divided into two branches, the two branches are respectively a gas supplementing branch (301) and a pressure releasing branch (302), the first electric valve (4) is arranged on the gas supplementing branch (301), the second electric valve (16) is arranged on the pressure releasing branch (302), the particle trapping device (14) is arranged on the first pipeline (141) and is arranged on the downstream of the three-way catalyst (9) and is arranged on the second electric branch (14) and is arranged on the outer part of the air trapping device (7); the air supply device (3), the first electric valve (4), the second electric valve (16), the first heating device (13), the second heating device (7) and the solar charging device (18) are all connected with the energy supply controller (1) through signal lines and power lines; the solar charging device (18) is used for receiving a control signal of the energy supply controller (1), converting solar radiation energy into electric energy through a photoelectric effect or a photochemical effect and providing electric energy for the particle capture device auxiliary regeneration system under the condition that the solar charging device (18) can receive enough solar radiation energy and the particle capture device auxiliary regeneration system needs the solar charging device (18) to provide electric energy; the control device includes:

The first judging module is used for judging whether the solar charging device (18) meets working conditions or not;

the second judging module is used for judging whether the electronic control unit (17) of the engine is in a power-on state or not under the condition that the solar charging device (18) meets the working condition;

the control module is used for controlling the auxiliary regeneration system of the particle trapping device to execute a standby mode under the condition that the electronic control unit (17) of the engine is in a power-on state, and executing the standby mode comprises the steps of acquiring working condition information of the auxiliary regeneration system of the particle trapping device, closing an air supply device (3) of the auxiliary regeneration system of the particle trapping device, closing a first electric valve (4), closing a second electric valve (16), closing a second heating device (7) and closing a first heating device (13);

the generation module is used for exiting the standby mode to generate a first control instruction set when the engine and the working condition information are determined to meet preset conditions and an auxiliary regeneration demand instruction is received, and the first control instruction set is used for opening the first electric valve (4) and the air supply device (3);

The working condition information at least comprises a first preset temperature value, a second preset temperature value, a first preset pressure value, a first gas pressure in a gas supplementing branch (301) of the auxiliary regeneration system of the particle capturing device and a gas temperature at an inlet of an upstream pipeline of the particle capturing device (14).

8. A processor for running a program, wherein the program runs to execute the control method of the solar-powered particle capture device auxiliary regeneration system according to any one of claims 1 to 6.

9. A vehicle comprising a particle trap device assisted regeneration system, wherein the particle trap device assisted regeneration system is controlled using the method of any one of claims 1 to 6.