WO2022227432A1 - Rapid restarting apparatus for charging controller, and charging pile control system - Google Patents

Abstract

The present invention relates to a rapid restarting apparatus for a charging controller, and a charging pile control system using the rapid restarting apparatus. A switching power source module, an alternating current power supply module, a power supply on/off module, and a power supply control module are arranged; the power supply control module controls, according to a restart control instruction outputted by a charging controller, the power supply on/off module to disconnect the alternating current power supply module and the switching power source module, and after a predetermined time period, connect the alternating current power supply module and the switching power source module, so that the switching power source module is powered on at a predetermined time after being powered off, and therefore, the remote restart of the charging controller is achieved. The present invention achieves the remote power-off and restart of the charging pile control system by means of the rapid restarting apparatus for the charging controller, thereby being capable of rapidly solving some of the faults, improving the intelligent operation and maintenance levels of a charging pile, relieving the operation and maintenance pressure of a large number of charging facilities that are increased in a burst mode, and promoting the healthy development of the charging facility industry.

Description

A charging controller rapid restart device and charging pile control system technical field

The invention relates to the technical field of electric vehicle charging control, in particular to a charging controller quick restart device and a charging pile control system.

Background technique

With the rapid increase in the number of electric vehicle charging piles in China, the later operation and maintenance of charging piles are facing huge challenges. At present, the operation and maintenance of public charging piles are still faced with problems such as frequent hardware and software failures, the operation and maintenance costs remain high, and electric vehicle owners continue to complain. At present, the charging piles that have been built on the market can basically realize the status monitoring of charging piles, upload fault codes, and complete the function of fault location. However, most of the maintenance work is still done manually, which is low in efficiency and high in cost. Therefore, the intelligent operation and maintenance of charging piles has become the focus of attention in the industry.

In the face of a software failure of the charging pile, the power-off and restart of the control system is a routine step for the operation and maintenance personnel. Some charging piles can restore their normal functions through the power-off and restart of the charging pile control system. Therefore, if the charging pile can be quickly restarted remotely, it can reduce operation and maintenance costs to a certain extent and reduce customer complaints.

SUMMARY OF THE INVENTION

Based on the above-mentioned situation in the prior art, the purpose of the present invention is to provide a fast restarting device of a charging controller and a charging pile control system using the fast restarting device, so as to solve the problem that the electric vehicle charging pile in the prior art is difficult to realize remote self-reset of faults. The problem.

In order to achieve the above object, according to an aspect of the present invention, a fast restart device for a charging controller is provided, the fast restart device for the charging controller is connected to the charging controller, and the fast restart device includes a switching power supply module, an AC power supply module, a power supply module, and a power supply module. On-off module, and power supply control module; wherein,

The power supply control module, according to the restart control instruction output by the charging controller, controls the power supply on-off module to disconnect the AC power supply module and the switching power supply module, and connect after a predetermined time;

The power supply on-off module is connected between the AC power supply module and the switching power supply module, and is turned off and on according to the control of the power supply control module, so that the switching power supply module is powered off and powered on after a predetermined time;

The charging controller is powered by the switching power supply, and restarts are realized through the power-on and power-off of the switching power supply.

Further, the power supply control module includes an intermediate relay and a time delay relay; the power supply on-off module includes an AC contactor.

Further, the restart control instruction includes closing the switch output node;

The switch output node is closed, so that the coil of the intermediate relay is energized, the first and second normally open contacts of the intermediate relay are closed, and the normally closed contact is disconnected.

Further, the normally closed contact of the intermediate relay is disconnected, so that the coil of the AC contactor is de-energized, and the AC contactor disconnects the AC power supply module and the switching power supply module.

Further, the first normally open contact of the intermediate relay is connected to the power supply circuit of the intermediate relay, the first normally open contact is closed, the coil of the intermediate relay is energized, and the intermediate relay self-locks to maintain the current operation.

Further, the second normally open contact of the intermediate relay is closed, and the delay relay is powered.

Further, after the delay relay is energized, the contacts are disconnected after the predetermined time, so that the coil of the intermediate relay is de-energized, the first and second normally open contacts of the intermediate relay are disconnected, and the Closed contacts are closed.

Further, the normally closed contact of the intermediate relay is closed, so that the coil of the AC contactor is energized, and the AC contactor restores the connection between the AC power supply module and the switching power supply module.

Further, the first and second normally open contacts of the intermediate relay are disconnected, and the self-locking of the intermediate relay is released.

According to another aspect of the present invention, a charging pile control system is provided, including an AC power distribution device, a power conversion device, a DC output device, a charging interface device, a billing control device, a human-computer interaction device, and a charging controller;

The charging controller performs on-off control on the AC power output by the AC power distribution device, and performs data transmission with the power conversion device, so as to realize the control of the control system;

It also includes the charging controller rapid restarting device according to the first aspect of the present invention, and the charging controller realizes restarting through the charging controller rapid restarting device.

In summary, the present invention provides a charging controller quick restart device and a charging pile control system using the quick restart device. By setting a switching power supply module, an AC power supply module, a power supply on-off module, and a power supply control module, the power supply The control module controls the power supply on-off module to disconnect the AC power supply module and the switching power supply module according to the restart control instruction output by the charging controller, and connect it after a predetermined time, so that the switching power supply module can be powered off at a predetermined time. When the power is turned on, the remote restart of the charging controller is realized. The invention realizes the remote power-off and restart of the charging pile control system through the charging controller quick restart device, so that some faults can be quickly solved, the intelligent operation and maintenance level of the charging pile is improved, the operation and maintenance pressure of the explosive growth of a large number of charging facilities is relieved, and the promotion of The charging facility industry is developing healthily.

Description of drawings

Fig. 1 is the structural block diagram of the charging controller quick restart device of the present invention;

Fig. 2 is the circuit schematic diagram of the charging controller quick restart device of the present invention;

FIG. 3 is a circuit schematic diagram of the charging pile control system of the present invention.

Detailed ways

In order to make the objectives, technical solutions and advantages of the present invention clearer, the present invention will be further described in detail below with reference to the specific embodiments and the accompanying drawings. It should be understood that these descriptions are exemplary only and are not intended to limit the scope of the invention. Also, in the following description, descriptions of well-known structures and techniques are omitted to avoid unnecessarily obscuring the concepts of the present invention.

The technical solutions of the present invention will be described in detail below with reference to the accompanying drawings. According to an embodiment of the present invention, a rapid restarting device for a charging controller is provided. The block diagram of the device is shown in FIG. 1 . The rapid restarting device for the charging controller is connected to the charging controller, and the rapid restarting device includes a switching power supply. module, AC power supply module, power supply on-off module, and power supply control module.

The power supply control module, according to the restart control instruction output by the charging controller, controls the power supply on-off module to disconnect the AC power supply module and the switching power supply module, and connect it after a predetermined time. The power supply control module may include an intermediate relay and a delay relay. The restart control instruction includes closing the switch output node; the switch output node is closed, so that the coil of the intermediate relay is energized, the first and second normally open contacts of the intermediate relay are closed, and the normally closed contact is disconnected .

The power supply on-off module is connected between the AC power supply module and the switching power supply module, and is switched off and on according to the control of the power supply control module, so that the switching power supply module is powered off and powered on after a predetermined time. The power supply on-off module may include an AC contactor.

The normally closed contact of the intermediate relay is disconnected, so that the coil of the AC contactor is de-energized, and the AC contactor disconnects the AC power supply module and the switching power supply module. The first normally open contact of the intermediate relay is connected to the power supply circuit of the intermediate relay, the first normally open contact is closed, the coil of the intermediate relay is energized, and the intermediate relay self-locks to maintain the current action. The second normally open contact of the intermediate relay is closed, and the delay relay is energized.

After the delay relay is energized, the contacts are disconnected after the predetermined time, so that the coil of the intermediate relay is de-energized, the first and second normally open contacts of the intermediate relay are disconnected, and the normally closed contacts closure. The normally closed contact of the intermediate relay is closed, so that the coil of the AC contactor is energized, and the AC contactor restores the connection between the AC power supply module and the switching power supply module. The first and second normally open contacts of the intermediate relay are disconnected, and the self-locking of the intermediate relay is released.

The charging controller is powered by the switching power supply, and restarts are realized through the power-on and power-off of the switching power supply.

FIG. 2 shows a schematic circuit diagram of the fast restart device of the charging controller. The solution of this embodiment is further described below by taking the circuit shown in FIG. 2 as an example.

The power supply on-off module and power supply control module of the fast restart device of the charging controller are connected between the AC power supply module and the switching power supply module. The power supply on-off module can be realized by the AC contactor KM1, and the switching power supply module can be the switching power supply UP, Connect the AC contactor KM1 in series before the switching power supply UP, and control the power-on and power-off of the switching power supply UP by controlling the coil power supply circuit of the AC contactor KM1. Among them, each relay control coil is powered by 220V.

The power supply control module can be realized by the intermediate relay K1 and the delay relay KT. The normally closed node K1 _NC1 of the intermediate relay K1 is connected in series in the coil loop of the AC contactor KM1. Under normal conditions, the coil of the AC contactor KM1 is in a charged state. At this time, the AC contactor KM1 is closed, and the switching power supply UP outputs 12V supply. Charging pile control system; when the intermediate relay K1 is actuated, its normally closed node K1 _NC1 is disconnected, the coil of the AC contactor KM1 is de-energized, the AC contactor KM1 is disconnected, the switching power supply UP is de-energized, and the charging pile control system is de-energized .

When the charging controller receives the reset command, the switch output node DO1 of the charging controller is closed, at this time, the coil of the intermediate relay K1 is charged, the normally closed node K1 _NC1 of the intermediate relay K1 is disconnected, the AC contactor KM1 is disconnected, and the switch The power supply UP loses power, which causes the charging pile control system to lose power; at the same time, the first normally open contact K1 _NO1 and the second normally open contact K1 _NO2 of the intermediate relay K1 are closed, forming self-locking with the coil of the intermediate relay K1 and delaying the delay The coil of the relay KT is electrified, and the delay relay KT delays a predetermined time, which is determined by the performance and actual demand of the delay relay KT. After the delay time of the delay relay KT arrives, the normally closed electric shock of the delay relay KT is disconnected, the coil of the intermediate relay K1 is de-energized, the first normally open contact K1 _NO1 and the second normally open contact K1 of the intermediate relay K1 are de-energized. _NO2 resumes disconnection, self-locking is released, normally closed contact K1 _NC1 resumes closing, the coil of AC contactor KM1 is energized, AC contactor KM1 is closed, the switching power supply UP is powered on, and the charging pile control system is restarted.

The following is a detailed description of the work flow of the remote quick start circuit of the charging pile control system in conjunction with a specific example of the circuit work process.

Still referring to the circuit schematic diagram in Figure 2, under normal conditions, the AC contactor KM1 is closed, the switching power supply UP is powered on, the charging controller is powered, and the charging pile control system operates normally.

When the charging pile control system receives an instruction to reset and restart the charging pile, the charging controller controls the charging pile control system to perform a power-off restart. The process of power-off and restart can be performed according to the following process:

Step 1: The switch output node DO1 of the charging controller is closed, and the switch output node DO1 is connected to the coil power supply circuit of the intermediate relay K1. At this time, the coil of the intermediate relay K1 is charged, and the normally closed contact of the intermediate relay _K1 is disconnected. , the coil of the AC contactor KM1 is de-energized, and the AC contactor KM1 is disconnected, so that the switching power supply UP is de-energized, causing the charging controller to be de-energized, and then the charging pile control system is de-energized, and the switch output node DO1 is disconnected;

Step 2: At the same time, the coil of the intermediate relay K1 is electrified, so that the first normally open contact K1 _NO1 of the intermediate relay K1 is closed, self-locking with the coil of the intermediate relay K1, and the intermediate relay K1 keeps moving;

Step 3: At the same time, the coil of the intermediate relay K1 is electrified, so that the second normally open contact K1 _NO2 of the intermediate relay K1 is closed, so that the coil of the delay relay KT is electrified;

The fourth step: the delay relay KT starts to delay the predetermined time, the delay relay KT delays the predetermined time, the contact of the delay relay KT is disconnected, and the coil of the intermediate relay K1 is de-energized;

Step 5: The normally closed contact K1 _NC1 of the intermediate relay K1 is closed again, the coil of the AC contactor KM1 is powered on again, the AC contactor KM1 is closed, the switching power supply is powered on, the charging controller is powered on again, and the charging pile control system Reboot, complete reset;

Step 6: At the same time, the first normally open contact K1 _NO1 and the second normally open contact K1 _NO2 of the intermediate relay K1 resume to disconnect, the self-lock is released, the coil of the intermediate relay K1 remains de-energized, and the delay relay KT The coil is de-energized. At this point, the entire restart process is complete.

According to another embodiment of the present invention, a charging pile control system is provided. The circuit schematic diagram of the charging pile control system is shown in FIG. 3 , and the system includes an AC power distribution device (including QF, KM, OF1, and switching power supply), power conversion device (referring to the charging module in Figure 3), DC output device (referring to FU, RS, K1 in Figure 3), charging interface device (referring to the charging gun in Figure 3), meter A charging control device, a human-computer interaction device, a charging controller (referring to the charging controller in FIG. 3 ) and an operation management platform (that is, referring to the cloud platform in FIG. 3 ); in the embodiment of this application, the charging control device The human-computer interaction device may be one or more processors or chips with communication interfaces capable of implementing communication protocols, and if necessary, may also include memory and related interfaces, system transmission buses, etc.; the processors or chips execute programs. The relevant code implements the corresponding function.

The charging controller performs on-off control of the AC power output by the AC power distribution device, and performs data transmission with the power conversion device, so as to realize the control of the control system. The charging controller in this implementation can also implement functions such as DC circuit insulation detection, data transmission with the vehicle BMS, collection of user power consumption information and transmission to the user terminal, and upload of data to the operation management center. The system further includes the charging controller rapid restart device according to the first embodiment of the present invention, and the charging controller realizes restart through the charging controller rapid restart device. In the charging pile control system, the charging controller is powered by a switching power supply, and the front stage of the switching power supply is equipped with a miniature circuit breaker, which provides protection for the charging pile control system and facilitates maintenance by staff. During the normal operation of the charging pile, the charging controller is always in a charged state. When there is a charging demand, the charging controller controls the charging pile to complete the charging function of the electric vehicle. When a fault alarm occurs on the charging pile, such as a discharge fault, a contactor sampling fault, an electronic lock fault, etc. that cannot be recovered, the charging controller can be restarted by the quick restarting device for the charging controller provided by the first embodiment of the present invention, Generally speaking, the restart operation can restore the normal use of the charging pile.

To sum up, the present invention relates to a fast restarting device of a charging controller and a charging pile control system using the fast restarting device. According to the restart control command output by the charging controller, the module controls the power supply on-off module to disconnect the AC power supply module and the switching power supply module, and turn it on after a predetermined time, so that the switching power supply module can be powered off at a predetermined time. Electricity, realizes the remote restart of the charging controller. The invention realizes the remote power-off and restart of the charging pile control system through the charging controller quick restart device, so that some faults can be quickly solved, the intelligent operation and maintenance level of the charging pile is improved, the operation and maintenance pressure of the explosive growth of a large number of charging facilities is relieved, and the promotion of The charging facility industry is developing healthily.

It should be understood that the above-mentioned specific embodiments of the present invention are only used to illustrate or explain the principle of the present invention, but not to limit the present invention. Therefore, any modifications, equivalent replacements, improvements, etc. made without departing from the spirit and scope of the present invention should be included within the protection scope of the present invention. Furthermore, the appended claims of this invention are intended to cover all changes and modifications that fall within the scope and boundaries of the appended claims, or the equivalents of such scope and boundaries.

Claims (10)

1. A fast restarting device for a charging controller, characterized in that the fast restarting device for the charging controller is connected to the charging controller, and the fast restarting device comprises a switching power supply module, an AC power supply module, a power supply on-off module, and a power supply control module; wherein ,

   The power supply control module, according to the restart control instruction output by the charging controller, controls the power supply on-off module to disconnect the AC power supply module and the switching power supply module, and turns on after a predetermined time;

   The power supply on-off module is connected between the AC power supply module and the switching power supply module, and is turned off and on according to the control of the power supply control module, so that the switching power supply module is powered off and powered on after a predetermined time;

   The charging controller is powered by the switching power supply, and restarts are realized through the power-on and power-off of the switching power supply.
2. The device according to claim 1, wherein the power supply control module comprises an intermediate relay and a time delay relay; the power supply on-off module comprises an AC contactor.
3. The apparatus according to claim 2, wherein the restart control instruction comprises closing a switch output node;

   The switch output node is closed, so that the coil of the intermediate relay is energized, the first and second normally open contacts of the intermediate relay are closed, and the normally closed contact is disconnected.
4. The device according to claim 3, wherein the normally closed contact of the intermediate relay is disconnected, so that the coil of the AC contactor is de-energized, and the AC contactor disconnects the AC power supply module and the switching power supply module Connection.
5. The device according to claim 3, wherein the first normally open contact of the intermediate relay is connected to the power supply circuit of the intermediate relay, the first normally open contact is closed, and the coil of the intermediate relay is energized, The intermediate relay self-locks to maintain the current action.
6. The device according to claim 3, wherein the second normally open contact of the intermediate relay is closed, and the delay relay is energized.
7. The device according to claim 6, characterized in that, after the delay relay is energized, the contact is disconnected after the predetermined time, so that the coil of the intermediate relay is de-energized, and the first and The second normally open contact opens and the normally closed contact closes.
8. The device according to claim 7, wherein the normally closed contact of the intermediate relay is closed, so that the coil of the AC contactor is energized, and the AC contactor restores the connection between the AC power supply module and the switching power supply module .
9. The device according to claim 7, wherein the first and second normally open contacts of the intermediate relay are disconnected, and the self-locking of the intermediate relay is released.
10. A charging pile control system, characterized in that it includes an AC power distribution device, a power conversion device, a DC output device, a charging interface device, a billing control device, a human-computer interaction device, and a charging controller;

    The charging controller performs on-off control on the AC power output by the AC power distribution device, and performs data transmission with the power conversion device, so as to realize the control of the control system;

    Also included is the charging controller rapid restarting device according to any one of claims 1-9, the charging controller realizes restarting through the charging controller rapid restarting device.

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