CN209999653U - Circuit structure of wireless debugging modules of injection molding machine driver - Google Patents

Abstract

The utility model provides a circuit structure of wireless debugging module of injection molding machine driver, including data processing circuit, serial communication circuit, wireless transmission circuit and display circuit, data processing circuit includes the data processing chip, the data processing chip passes through serial communication circuit and is connected with the driver, in order to carry out the data interaction, wireless transmission circuit is connected with the data processing chip, receive the driver parameter information that the data processing chip sent, convert into radio signal, send to debugging equipment, the debugging data that the debugging equipment sent is received to the wireless transmission circuit, through data processing chip and serial communication circuit, transmit to the driver, the display circuit is connected with the data processing chip, receive the display data that the data processing chip sent and show.

Description

Circuit structure of wireless debugging modules of injection molding machine driver

Technical Field

The utility model relates to an kind of injection molding machine driver debugging technical field especially relates to the circuit structure of kind of wireless debugging modules of injection molding machine driver.

Background

In recent years, with the rapid development of driver technology, drivers have been widely applied to various fields by , for example, in the field of injection molding machines, the drivers are used as professional running devices and are internally provided with a large number of adjustable parameters, at present, in the field of injection molding machines, two common driver debugging methods exist, drivers are operating panels provided with the drivers, operators debug the drivers on the operating panels, and the existing partial drivers may not have operating panels, in this case, the second debugging method is to connect the drivers and computers in a wired manner, for example, through serial ports or internet ports, and then use computer end software as an upper computer to debug the drivers, the two methods both need the debuggers to go to the debugging site, when the drivers are abnormal, the debuggers often need to take time to go to the site for debugging, which is time and labor consuming, so wireless debugging modules are provided, when the debuggers are on the site, the debuggers can be wirelessly connected with wireless modules in the injection molding machines through computers or mobile devices, such as mobile phones, IPAD, thereby the tedious wiring process of wire connection is avoided, and the remote debugging of the operators can be conveniently debugged by the wireless debugging of the wireless debugging, and the operators can not need to remotely debug the on-site, and the remote debugging personnel can be debugged on-site through the wireless information of the wireless debugging personnel, and the wireless debugging personnel.

Disclosure of Invention

The to-be-solved technical problem aim at provides kinds of circuit structure of wireless debugging module of injection molding machine driver for make the parameter information of injection molding machine can remote routing to in debugging equipment, make things convenient for the debugging personnel to carry out the parameter adjustment.

In order to realize the purpose, the utility model discloses a technical scheme as follows:

circuit structure of wireless debugging module of injection molding machine driver comprises a data processing circuit, a serial port communication circuit, a wireless transmission circuit and a display circuit, wherein the data processing circuit comprises a data processing chip;

the data processing chip is connected with the driver through the serial port communication circuit to carry out data interaction;

the wireless transmission circuit is connected with the data processing chip, receives the driver parameter information sent by the data processing chip, converts the driver parameter information into a wireless signal and sends the wireless signal to debugging equipment;

the wireless transmission circuit receives debugging data sent by the debugging equipment and transmits the debugging data to the driver through the data processing chip and the serial port communication circuit;

the display circuit is connected with the data processing chip, and receives and displays the display data sent by the data processing chip.

Preferably, the display circuit comprises a nixie tube display circuit and an LED display circuit, and the LED display circuit is connected with the nixie tube display circuit.

Preferably, the nixie tube display circuit comprises an th nixie tube, a second nixie tube, a third nixie tube, a fourth nixie tube and a fifth nixie tube, wherein the th nixie tube, the second nixie tube, the third nixie tube, the fourth nixie tube and the fifth nixie tube are respectively connected with the data processing chip through corresponding triodes.

Preferably, the wireless transmission circuit comprises a wireless transmission chip, and the wireless transmission chip is connected with a state indicating circuit and used for displaying the working state of the wireless transmission chip.

Preferably, the status indication circuit includes a twenty-second resistor, a twenty-third resistor and a second light emitting diode, wherein an terminal of the twenty-second resistor is connected to the twenty-third pin of the wireless transmission chip, another terminal of the twenty-second resistor is connected to a terminal of the twenty-third resistor and then connected to the input power source, another terminal of the twenty-third resistor is connected to the input terminal of the second light emitting diode, and another terminal of the second light emitting diode is connected to the twenty-second pin of the wireless transmission chip.

Preferably, the wireless transmission circuit is further connected with a key circuit, and a plurality of keys are arranged in the key circuit to control the working state of the wireless transmission chip.

Preferably, the serial port communication circuit includes a communication chip, a tenth pin of the communication chip is connected to a sixteenth pin of the data processing chip, and a twelfth pin of the communication chip is connected to a seventeenth pin of the data processing chip.

Preferably, a fourteenth pin of the communication chip is connected to a second interface of a second connector, and a third interface of the second connector is connected to a thirteenth pin of the communication chip.

Preferably, the nineteenth pin of the wireless transmission chip is connected to terminals of the forty-third pin and the thirty-fifth resistor of the data processing chip, the twentieth pin of the wireless transmission chip is connected to terminals of the forty-second pin and the thirty-sixth resistor of the data processing chip, the twentieth pin of the wireless transmission chip is connected to terminals of the twentieth resistor, and the other terminal of the twentieth resistor is connected to input power source after being connected to the other terminal of the thirty-fifth resistor and the other terminal of the thirty-sixth resistor.

Adopt the utility model discloses, through setting up wireless transmission circuit, can be wireless signal with the parameter information conversion of driver to remote transmission carries out remote parameter debugging to the driver of injection molding machine to the convenient debugging personnel in debugging equipment.

Drawings

Fig. 1 is a schematic diagram of a wireless transmission circuit of wireless debugging modules of the drivers of the injection molding machine provided by embodiments of the present invention;

fig. 2 is a schematic diagram of a display circuit of a wireless debugging modules of the drivers of the injection molding machine provided by embodiments of the present invention;

fig. 3 is a schematic diagram of a data processing circuit of wireless debugging modules of the injection molding machine drivers provided by embodiments of the present invention;

fig. 4 is a schematic diagram of a serial port communication circuit of kinds of wireless debugging modules of drivers of injection molding machines provided by embodiments of the present invention.

Detailed Description

The following is a description of the technical solution of the present invention in steps with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

Example

Referring to fig. 1 to 4, the present embodiment provides a circuit structure of wireless debugging modules of injection molding machine driver, including a data processing circuit, a serial port communication circuit, a wireless transmission circuit and a display circuit, where the data processing circuit includes a data processing chip,

the data processing chip is connected with the driver through the serial port communication circuit to carry out data interaction;

the wireless transmission circuit is connected with the data processing chip, receives the driver parameter information sent by the data processing chip, converts the driver parameter information into a wireless signal and sends the wireless signal to the debugging equipment;

the wireless transmission circuit receives debugging data sent by the debugging equipment and transmits the debugging data to the driver through the data processing chip and the serial port communication circuit;

the display circuit is connected with the data processing chip, receives the display data sent by the data processing chip and displays the display data.

In this embodiment, a data processing chip is disposed in the data processing circuit, wherein the data processing chip is of a model STM32F103R4T6A, referring to fig. 3, the data processing circuit in fig. 3 has a data processing chip U3, and the data processing chip U3 has a plurality of pins, and the connection manner of each pin can be intuitively understood from fig. 3 and fig. 1, 2, and 4, and this embodiment is not described in detail in text.

In fig. 3, the data processing circuit further includes part of peripheral auxiliary circuits, including a capacitor C61, a capacitor C60, a capacitor C57, a capacitor C56, an electrolytic capacitor C7, a capacitor C32, a capacitor C33, an electrolytic capacitor C34, a resistor R24, a resistor R31, and a chip U7, and the connection manner of the above components can be intuitively seen from fig. 3, and the description of this embodiment is not repeated.

Referring to fig. 4, the serial communication circuit in fig. 4 includes a communication chip U12, wherein the tenth pin 11 of the communication chip U12 is connected to the sixteenth pin 16 of the data processing chip U3, and the twelfth pin 12 of the communication chip U12 is connected to the seventeenth pin 17 of the data processing chip U3.

The fourteenth pin 14 of the communication chip U12 is connected to the second interface 2 of the second connector J2, and the third interface 3 of the second connector J2 is connected to the thirteenth pin 13 of the communication chip U12.

The communication chip U12 is connected with the driver through the second connector J2, and the driver transmits the parameter information of the driver to the data processing chip U3 through the communication chip U12.

Referring to fig. 4, the serial communication circuit further includes a resistor R51, a resistor R52, and a th connector J1.

In this embodiment, referring to fig. 1, the wireless transmission circuit includes a wireless transmission chip U13 and a key circuit.

The nineteenth pin 19 of the wireless transmission chip U13 is connected to the forty-third pin 43 of the data processing chip U3 and the end of the thirty-fifth resistor R35, respectively, the twentieth pin 20 of the wireless transmission chip U13 is connected to the forty-second pin 42 of the data processing chip U3 and the end of the thirty-sixth resistor R36, the twentieth pin 21 of the wireless transmission chip U13 is connected to the end of the twenty- resistor R21, and the other end of the twentieth resistor R21 is connected to the other end of the thirty-fifth resistor R35 and the other end of the thirty-sixth resistor R36, respectively, and then connected to the -th input power supply.

After the wireless transmission chip U13 is connected with the data processing chip U3, the parameter information of the driver received by the data processing chip U3 can be transmitted to the wireless transmission chip U13, then the parameter information of the driver is converted into a wireless signal through the wireless transmission chip U13 and transmitted to remote debugging equipment, so that debugging personnel correspondingly debug according to the parameter information of the driver, debugging data are generated, then the debugging equipment sends the debugging data to the wireless transmission chip U13, the wireless transmission chip Y13 transmits the received debugging data to the driver through the data processing chip U3 and the serial port communication circuit, and remote debugging of the parameters of the driver by the remote debugging personnel is achieved.

, the voltage of the th input power supply in this embodiment is 3.3V.

The wireless transmission chip U13 is connected with a status indicating circuit for displaying the working status of the wireless transmission chip U13.

The state indicating circuit comprises a twenty-second resistor R22, a twenty-third resistor R23 and a second light emitting diode D2, wherein a end of the twenty-second resistor R22 is connected with a twenty-third pin 23 of the wireless transmission chip U13, another end of the twenty-second resistor R22 is connected with an end of the twenty-third resistor R23 and then connected with a th input power supply, another end of the twenty-third resistor R23 is connected with an input end of the second light emitting diode D2, and another end of the second light emitting diode D2 is connected with a twenty-second pin 22 of the wireless transmission chip U13.

The operating status of the wireless transmission chip includes two states, the th state is connected with the server or the debugging device and is in a state of sending the parameter information of the driver and receiving the debugging data, and the th state is not connected with the server or the debugging device and does not send the parameter information of the driver and receive the debugging data.

When the vehicle is in the th working state, the second light-emitting diode D2 emits light to prompt staff.

In fig. 1, the wireless transmission circuit further includes a key circuit, and the key circuit is used to control the wireless transmission chip U13 to be in the th state or the second working state.

The key circuit comprises a plurality of keys, namely a key S1, a key S2, a key S3, a key S4, a key S5, a key S6, a key S7 and a key S8 in the figure 1, and the wireless transmission chip U13 is controlled by arranging the keys.

Referring to fig. 2, the display circuit includes a nixie tube display circuit and an LED display circuit, the LED display circuit is connected to the nixie tube display circuit, and the LED display circuit is further connected to the data processing chip U3.

The nixie tube display circuit comprises an th nixie tube H1, a second nixie tube H2, a third nixie tube H3, a fourth nixie tube H4 and a fifth nixie tube H5.

The connection mode of each nixie tube can be seen visually in fig. 2, wherein a triode Q2, a triode Q3, a triode Q4, a triode Q5 and a triode Q6 are further arranged between each nixie tube and the data processing chip U3, and the connection or disconnection of the circuit is controlled through the corresponding triode.

Through setting up wireless transmission circuit, can be wireless signal with the parameter information conversion of driver to remote transmission carries out remote parameter debugging to the driver of injection molding machine to the debugging equipment in, the convenient debugging personnel.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (9)

1. The circuit structure of the wireless debugging module of the injection molding machine driver is characterized by comprising a data processing circuit, a serial port communication circuit, a wireless transmission circuit and a display circuit, wherein the data processing circuit comprises a data processing chip;

   the data processing chip is connected with the driver through the serial port communication circuit to carry out data interaction;

   the wireless transmission circuit is connected with the data processing chip, receives the driver parameter information sent by the data processing chip, converts the driver parameter information into a wireless signal and sends the wireless signal to debugging equipment;

   the wireless transmission circuit receives debugging data sent by the debugging equipment and transmits the debugging data to the driver through the data processing chip and the serial port communication circuit;

   the display circuit is connected with the data processing chip, and receives and displays the display data sent by the data processing chip.
2. 2. The circuit structure of wireless debugging modules for driver of injection molding machine according to claim 1, wherein said display circuit comprises a nixie tube display circuit and an LED display circuit, said LED display circuit being connected to said nixie tube display circuit.
3. 3. The circuit structure of wireless debugging modules for driver of injection molding machine according to claim 2, wherein said nixie tube display circuit comprises , second, third, fourth and fifth nixie tubes, and wherein , second, third, fourth and fifth nixie tubes are respectively connected to said data processing chip via corresponding triodes.
4. 4. The circuit structure of wireless debugging modules for driver of injection molding machine according to claim 1, wherein said wireless transmission circuit comprises a wireless transmission chip, and said wireless transmission chip is connected with a status indication circuit for displaying the operating status of said wireless transmission chip.
5. 5. The circuit structure of wireless debugging module of injection molding machine driver of claim 4, wherein said status indication circuit comprises a twenty-second resistor, a twenty-third resistor and a second light emitting diode, wherein the terminal of said twenty-second resistor is connected to the twenty-third pin of said wireless transmission chip, the other terminal of said twenty-second resistor is connected to the terminal of said twenty-third resistor and then connected to the th input power supply, the other terminal of said twenty-third resistor is connected to the input terminal of said second light emitting diode, and the other terminal of said second light emitting diode is connected to the twenty-second pin of said wireless transmission chip.
6. 6. The circuit structure of kinds of wireless debugging modules of injection molding machine driver according to claim 4, wherein said wireless transmission circuit is further connected with a key circuit, and said key circuit is provided with a plurality of keys for controlling the operating status of said wireless transmission chip.
7. 7. The circuit structure of wireless debugging modules of driver of injection molding machine according to claim 1, wherein said serial port communication circuit comprises a communication chip, the tenth pin of said communication chip is connected to the sixteenth pin of said data processing chip, and the twelfth pin of said communication chip is connected to the seventeenth pin of said data processing chip.
8. 8. The circuit structure of wireless debugging modules for driver of injection molding machine according to claim 7, wherein the fourteenth pin of said communication chip is connected to the second interface of the second connector, and the third interface of said second connector is connected to the thirteenth pin of said communication chip.
9. 9. The circuit structure of wireless debugging modules for driver of injection molding machine according to claim 5, wherein the nineteenth pin of said wireless transmission chip is connected to the forty-third pin of said data processing chip and to the terminal of the thirty-fifth resistor, respectively, the twentieth pin of said wireless transmission chip is connected to the forty-second pin of said data processing chip and to the 0 terminal of the thirty-sixth resistor, respectively, the twentieth pin of said wireless transmission chip is connected to the terminal of the twentieth resistor, and the other terminal of said twentieth resistor is connected to the th input power after being connected to the other terminal of the thirty-fifth resistor and to the other terminal of the thirty-sixth resistor.

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