CN212433630U - Charging pile calibration system - Google Patents

Abstract

The utility model relates to a fill electric pile's calibration system fills electric pile and includes charge controller, its characterized in that: the calibration system comprises a calibration controller used for calibrating the charging controller, a first MCU is arranged in the charging controller, a second MCU is arranged in the calibration controller, the first MCU and the second MCU are in communication connection, a sampling pin is arranged on the first MCU, a calibration pin is arranged on the second MCU, the sampling pin on the first MCU is connected with the calibration pin on the second MCU, and the calibration pin is used for sending a calibration signal to the first MCU through the second MCU. The calibration system is more convenient and easy to realize, and the calibration controller has strong universality; in addition, the calibration system can assemble the calibrated charging controller and other equipment into the charging pile after being configured by only calibrating the charging controller independently, so that the problem of replacement of the whole charging pile due to failure of the charging controller is solved.

Description

Charging pile calibration system

Technical Field

The utility model relates to a fill the electric pile field, in particular to fill electric pile's calbiration system.

Background

Along with the popularization of new energy vehicles, in order to meet the charging requirements of more electric vehicles, more and more charging piles appear, the charging piles are installed in public buildings (public buildings, markets, public parking lots and the like) and residential area parking lots or charging stations, and the electric vehicles of various models can be charged according to different voltage grades. The input end of the charging pile is directly connected with an alternating current power grid, and the output end of the charging pile is provided with a charging plug for charging the electric automobile. Fill electric pile is the key interface that electric automobile charges and electric energy measurement, in order to fill electric pile's precision and high reliability, consequently before using, need to fill electric pile and calibrate.

The invention patent of China with the application number of CN201910266044.1 (application publication number of CN109870649A) discloses a calibration system and a method of an alternating current charging pile calibration device, wherein the system comprises a calibration control and display device, a standard alternating current charging pile, an error calculation device and an alternating current charging pile calibration device; the control input end of the standard alternating-current charging pile is connected with the calibration control and display device, the output end of the standard alternating-current charging pile is respectively connected with the error calculation device and the alternating-current charging pile calibration device, the output end of the alternating-current charging pile calibration device is connected with the error calculation device, and the output end of the error calculation device is connected with the calibration control and display device. The calibration system can be used for calibrating the alternating-current charging pile calibrating device, and the reliable operation of the alternating-current charging pile calibrating device is guaranteed. In the calibration system, the whole charging pile can be calibrated after being electrified, the whole charging pile needs to work, and in addition, a high-voltage power supply needs to be started when the charging pile is electrified, so that safety accidents are easily caused; and additionally, the standard alternating-current charging pile is used as a reference during calibration, and errors between the standard alternating-current charging pile and the alternating-current charging pile calibrating device are calculated, so that the alternating-current charging pile calibrating device is calibrated, the standard alternating-current charging pile and the alternating-current charging pile calibrating device are required to be calibrated when the system works normally, and the calibration can be realized only after two charging piles acquire electric energy pulse information and electric parameters, so that the calibration system is complex in operation and long in time required for calibration. Further improvements are therefore desirable.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that to prior art's current situation, provide a simple structure and calibrate more convenient calibration system of filling electric pile.

The utility model provides a technical scheme that above-mentioned technical problem adopted does: the utility model provides a fill electric pile's calibration system, fill electric pile and include charge controller, its characterized in that: the calibration system comprises a calibration controller used for calibrating the charging controller, a first MCU is arranged in the charging controller, a second MCU is arranged in the calibration controller, the first MCU and the second MCU are in communication connection, a sampling pin is arranged on the first MCU, a calibration pin is arranged on the second MCU, the sampling pin on the first MCU is connected with the calibration pin on the second MCU, and the calibration pin is used for sending a calibration signal to the first MCU through the second MCU.

As an improvement, the first MCU and the second MCU are respectively provided with a data transmitting pin and a data receiving pin, the data transmitting pin of the first MCU is connected with the data receiving pin of the second MCU, and the data receiving pin of the first MCU is connected with the data transmitting pin of the second MCU and used for realizing the communication connection of the first MCU and the second MCU.

Preferably, the first MCU and the second MCU are in communication connection through one interface of UART, RS232, RS485, CAN, SPI or I2C.

Furthermore, a power supply pin and a grounding pin are respectively arranged on the first MCU and the second MCU, the power supply pin of the first MCU is connected with an external power supply, the grounding pin of the first MCU is grounded, the power supply pin on the first MCU is connected with the power supply pin of the second MCU, and the grounding pin on the first MCU is connected with the grounding pin of the second MCU and used for supplying power for the calibration controller through the charging controller.

Further, a 2 nd pin of the first MCU outputs a reference voltage, and the 2 nd pin of the first MCU is connected to the 2 nd pin of the second MCU, so as to provide the reference voltage for the second MCU through the first MCU.

Still be equipped with bleeder circuit in the charge controller, bleeder circuit one end ground connection, bleeder circuit's the other end corresponds the collection end for charge controller, bleeder circuit's middle part with sampling pin on the first MCU is connected.

Specifically, bleeder circuit includes two first resistances and the second resistance that establishes ties mutually, the one end correspondence of first resistance is the acquisition end of charge controller, the one end ground connection of second resistance, the sampling pin on the first MCU is connected to the connecting wire between first resistance and the second resistance.

In this embodiment, the calibration signal is a voltage signal.

In this aspect, the calibration signal is a current signal.

In order to facilitate collection, the collection end of the charging controller is arranged outside the charging controller.

Compared with the prior art, the utility model has the advantages of: the calibration controller is in communication connection with the charging controller, so that the calibration controller sends a calibration signal to the charging controller to calibrate the charging controller, and the calibration system is more convenient and easy to implement, and the calibration controller can adapt to calibration of various types of charging controllers and has strong universality; in addition, the calibration system does not need to install the charging controller on the charging pile for calibration, and the charging pile can be assembled after the calibrated charging controller and other equipment are configured by only calibrating the charging controller independently, so that the problem of replacement of the whole charging pile due to failure of the charging controller is reduced, and the production efficiency of the charging pile is improved.

Drawings

Fig. 1 is a schematic block diagram of a calibration system according to an embodiment of the present invention;

fig. 2 is a flowchart illustrating calibration between the charging controller and the calibration controller according to an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the following embodiments.

The charging pile comprises a charging controller, the charging controller serves as a control module of the charging pile, and a sampling signal of a sampling part of the charging pile is finally output through the charging controller.

The utility model provides a fill calibration system of electric pile is including being used for carrying out the calibration controller that calibrates to the charge controller, be equipped with first MCU in the charge controller, be equipped with second MCU in the calibration controller, first MCU and second MCU communicate mutually and connect, be equipped with the sampling pin on the first MCU, be equipped with the calibration pin on the second MCU, the sampling pin on the first MCU is connected with the calibration pin on the second MCU, be used for sending calibration signal for first MCU through second MCU. In this embodiment, the calibration signal is a voltage signal or a current signal.

In order to realize the communication connection between the first MCU and the second MCU, the first MCU and the second MCU are respectively provided with a data transmitting pin and a data receiving pin, the data transmitting pin of the first MCU is connected with the data receiving pin of the second MCU, and the data receiving pin of the first MCU is connected with the data transmitting pin of the second MCU. In this embodiment, the first MCU and the second MCU are connected to each other through one of UART, RS232, RS485, CAN, SPI, or I2C.

The first MCU and the second MCU are respectively provided with a power supply pin and a grounding pin, the power supply pin of the first MCU is connected with an external power supply VCC, the grounding pin of the first MCU is grounded, the power supply pin on the first MCU is connected with the power supply pin of the second MCU, and the grounding pin on the first MCU is connected with the grounding pin of the second MCU and used for supplying power for the calibration controller through the charging controller. In addition, the 2 nd pin of the first MCU outputs a reference voltage, and the 2 nd pin of the first MCU is connected with the 2 nd pin of the second MCU for providing the reference voltage for the second MCU through the first MCU. The charging controller supplies power and provides a reference source for the calibration controller through the connection relation, so that the calibration controller does not need other external power supplies, the calibration controller obtains reference voltage from the charging controller, and the calibration controller performs calibration by taking the reference of the charging controller as a reference, so that the accuracy of the charging controller after calibration is improved.

Still be equipped with bleeder circuit 1 in the charge controller, bleeder circuit 1 one end ground connection, the other end of bleeder circuit 1 corresponds to charge controller's collection end V-E, and the middle part of bleeder circuit 1 is connected with the sampling pin on the first MCU. In this embodiment, the voltage dividing circuit 1 includes a first resistor R1 and a second resistor R2 connected in series, one end of the first resistor R1 corresponds to the acquisition end V-E of the charge controller, one end of the second resistor R2 is grounded, and a connection line between the first resistor R1 and the second resistor R2 is connected to a sampling pin on the first MCU. The acquisition end V-E and the grounding end PGND are sampling loops when the charging controller works normally, when the calibration signal is voltage, a high-voltage signal is converted into a low-voltage signal convenient to acquire through the voltage division circuit, and the acquisition end V-E is suspended during calibration.

As shown in fig. 1, a first MCU in the charge controller corresponds to the MCU1, the MCU1 thereof is provided with 6 pins, the 1 st pin is a power supply pin, and the power supply pin is connected to the external power VCC; the 2 nd pin is a reference pin which outputs a reference voltage; the 3 rd pin is a sampling pin which receives an AD signal; the 4 th pin is a data transmission pin TX 1; the 5 th pin is a data receiving pin RX 1; the 6 th pin is a grounding pin; the second MCU in the calibration controller is correspondingly MCU2, the MCU2 is provided with 6 pins, the 1 st pin is a power supply pin, and the power supply pin is connected with the 1 st pin of the MCU 1; the 2 nd pin is connected with a 2 nd pin of the MCU1 and used for acquiring the reference voltage Vref of the charge controller; the 3 rd pin is a calibration pin, and the calibration pin is connected with the 3 rd pin of the MCU 1; the 4 th pin is a data receiving pin RX 2; the 5 th pin is a data transmission pin TX 2; the 6 th pin is a grounding pin, wherein the AD signal received by the sampling pin on the first MCU is only a calibration analog signal given by the visual demonstration calibration controller and is sent to the charge controller, and the DA output by the calibration pin on the second MCU is a analog signal required to be given when the calibration controller calibrates.

When the calibration controller is used, the charging controller is connected with the calibration controller according to the circuit diagram shown in fig. 1, the charging controller supplies power and provides reference voltage for the calibration controller, in addition, the RX2 in the calibration controller is connected with the TX1 in the charging controller, the TX2 in the calibration controller is connected with the RX1 in the charging controller, at this time, the calibration controller and the charging controller communicate with each other, and a calibration signal can be sent to a sampling pin of the charging controller through the calibration pin of the calibration controller, so that the calibration of the charging controller is completed.

Certainly, the calibration system can also be used for calibrating an analog temperature signal, when the calibration signal is a temperature signal, the voltage of the acquisition end V-E of the charge controller is set to be a fixed value, the first resistor R1 is a resistor which can change along with temperature or humidity, the theoretical voltage of the 3 rd pin of the charge controller at different temperatures is calculated according to different resistance values corresponding to the first resistor R1 at different temperatures, and when the calibration signal is actually calibrated, the acquisition end V-E is suspended; during actual calibration, theoretical voltage values at different temperatures are sent to the charging controller through the calibration controller, and the resistance value of the first resistor R1 is changed similarly when the acquisition end V-E is connected with a fixed value, so that calibration of temperature signals is simulated.

As shown in fig. 2, the method for calibrating by using the calibration system includes the following steps:

step 1, judging whether the charging controller needs to be calibrated, if so, setting calibration parameters of a plurality of gears in the charging controller, and turning to step 2; if not, continuously judging whether the charging controller needs to be calibrated or not;

step 2, judging whether the charging controller and the calibration controller establish communication connection, if so, turning to step 3; if not, continuously judging whether the charging controller and the calibration controller establish communication connection;

step 3, the charging controller sends a parameter to be calibrated of one gear to the calibration controller;

step 4, judging whether the calibration controller receives the parameter to be calibrated sent by the charge controller, if so, sending the calibration value corresponding to the parameter to be calibrated to the charge controller by the calibration controller, and turning to step 5; if not, the step 7 is carried out;

step 5, judging whether the charging controller receives a calibration value, if so, calibrating the current gear, and turning to step 6; if not, the step 7 is carried out;

step 6, judging whether the charging controller is calibrated or not, if so, ending; if not, the charging controller sends the parameter to be calibrated of another gear to the calibration controller, and the process goes to step 4.

And 7, the calibration between the charging controller and the calibration controller is unsuccessful, and the operation is finished.

The value range of the number of gears of the parameter to be calibrated is 3-7.

Of course, when the parameter to be calibrated is a high voltage signal or a high current signal, the calibration system used in the calibration method must be provided with a voltage dividing circuit, and the calibration value sent by the calibration controller to the charge controller corresponds to a small voltage or small current value converted by the voltage dividing circuit of the parameter to be calibrated at a certain gear set in the charge controller.

The calibration method is described by using a specific example, when the calibration signal is a high voltage signal, the voltage acquisition range of the acquisition end V-E of the charge controller is 0-800V, and in addition, the gear to be calibrated of the acquisition end V-E is 5, which are respectively 0V, 200V, 400V, 600V and 800V, the ratio of the first resistor R1 and the second resistor R2 in the voltage division circuit 1 is 399:1, that is, the AD theoretical value sampled by the sampling pin on the first MCU is 399:1

VCC is the voltage that collection end V-E theory exported, and 5 shelves AD values that wait to calibrate the parameter correspondence respectively are: 0V, 0.5V, 1V, 1.5V, and 2V, therefore, the parameters to be calibrated of 5 gears set in the charge controller are converted into AD values of 0V, 0.5V, 1V, 1.5V, and 2V after passing through the voltage divider circuit, and the calibration value corresponding to the parameters to be calibrated of the 5 gears after passing through the voltage divider circuit conversion is needed in advance during calibrationThe voltage of the 3 rd pin of the MCU1 is adjusted to the calibration value after the charging controller receives the calibration value, and the voltage which can be output by the acquisition end V-E is the calibrated voltage.

When the charging controller needs to calibrate the 0V voltage, only the communication is needed to tell the calibration controller to calibrate the voltage of the 0V gear at present, when the calibration controller receives the parameter to be calibrated of the 0V gear, the calibration controller gives a 0V voltage signal through the DA, the calibration controller sends the 0V voltage signal to the charging controller, and when the charging controller receives the 0V calibration value, the charging controller calibrates the voltage of the 0V gear, so that the calibration of the gear can be completed; similarly, when the charging controller sends a parameter to be calibrated at a 200V gear to the calibration controller, and when the calibration controller receives the parameter to be calibrated at the 200V gear, the calibration controller sends a 0.5V voltage signal through the DA, the calibration controller sends the 0.5V voltage signal to the charging controller, when the charging controller receives the 0.5V voltage calibration value, the charging controller calibrates the voltage at the 200V gear, and when the voltage at the 3 rd pin of the charging controller is adjusted to be 0.5V, the acquisition end of the charging controller outputs the 200V voltage; the calibration of 400V, 600V and 800V gears is realized by sequentially using the same method, and the calibration of the voltage of the charging pile can be completed through the steps.

On the one hand, the calibration system and the calibration method do not need to provide high voltage which can ensure the work of the whole charging pile, and only need to ensure the work voltage of the charging controller, so that the safety of workers is improved; during calibration, tedious operations such as starting a high-voltage power supply and the like are not needed, so that the time for calibration is shortened; in addition, the calibration value is set to be a small voltage signal through the voltage division circuit in the calibration method, and the high voltage can be calibrated, so that the method is safer and more effective. On the other hand, the calibration system does not need to install the charging controller on the charging pile and then calibrate the charging controller, and the charging pile can be assembled after being configured with other equipment by only calibrating the charging controller independently, so that the production efficiency of the charging pile is improved, and the problem of replacement of the whole charging pile due to failure of the charging controller is reduced; and the suitability of this calibration controller is strong, can satisfy the calibration of various charge controller, and connect simply, the commonality is strong.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the technical principle of the present invention, and these improvements and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. The utility model provides a fill electric pile's calibration system, fill electric pile and include charge controller, its characterized in that: the calibration system comprises a calibration controller used for calibrating the charging controller, a first MCU is arranged in the charging controller, a second MCU is arranged in the calibration controller, the first MCU and the second MCU are in communication connection, a sampling pin is arranged on the first MCU, a calibration pin is arranged on the second MCU, the sampling pin on the first MCU is connected with the calibration pin on the second MCU, and the calibration pin is used for sending a calibration signal to the first MCU through the second MCU.

2. The system for calibrating a charging pile according to claim 1, wherein: the first MCU and the second MCU are respectively provided with a data transmitting pin and a data receiving pin, the data transmitting pin of the first MCU is connected with the data receiving pin of the second MCU, and the data receiving pin of the first MCU is connected with the data transmitting pin of the second MCU and used for realizing communication connection of the first MCU and the second MCU.

3. The system for calibrating a charging pile according to claim 2, wherein: the first MCU and the second MCU are in communication connection through one interface of UART, RS232, RS485, CAN, SPI or I2C.

4. The system for calibrating a charging pile according to claim 1, wherein: equally divide on first MCU and the second MCU and do not be equipped with power supply pin and ground connection pin, external power supply (VCC) is connected to first MCU's power supply pin, first MCU's ground connection pin ground connection, power supply pin on the first MCU is connected with second MCU's power supply pin, ground connection pin on the first MCU is connected with second MCU's ground connection pin for supply power for calibration controller through the charge controller.

5. The system for calibrating a charging pile according to claim 1, wherein: and the 2 nd pin of the first MCU outputs reference voltage, and the 2 nd pin of the first MCU is connected with the 2 nd pin of the second MCU and used for providing the reference voltage for the second MCU through the first MCU.

6. The system for calibrating a charging pile according to claim 1, wherein: still be equipped with bleeder circuit (1) in the charge controller, bleeder circuit (1) one end ground connection, the other end of bleeder circuit (1) corresponds for charge controller's collection end (V-E), the middle part of bleeder circuit (1) with sampling pin on the first MCU is connected.

7. The system for calibrating a charging pile according to claim 6, wherein: bleeder circuit (1) includes two first resistance (R1) and second resistance (R2) that connect in series mutually, the one end of first resistance (R1) is corresponding for charge controller's collection end (V-E), the one end ground connection of second resistance (R2), the sampling pin on the first MCU is connected to the connecting wire between first resistance (R1) and second resistance (R2).

8. The system for calibrating a charging pile according to claim 1, wherein: the calibration signal is a voltage signal.

9. The system for calibrating a charging pile according to claim 1, wherein: the calibration signal is a current signal.

10. The system for calibrating a charging pile according to claim 7, wherein: and the acquisition end (V-E) of the charging controller is arranged outside the charging controller.

Images