CN115328014B - A scribing knife control system, method, device and storage medium - Google Patents

Abstract

The present invention provides a scoring knife control system, method, equipment and storage medium, belonging to the technical field of manufacturing equipment, and the system includes a PLC control circuit and a temperature control circuit; the PLC control circuit is used to obtain a scoring knife adjustment value by differential analysis of preset reference control data according to scoring data; the temperature control circuit is used to convert the voltage of the scoring knife adjustment value to obtain a voltage value, and convert the temperature of the voltage value to obtain a temperature value, and heat or cool the scoring knife according to the temperature value. The present invention can stabilize the scoring, thereby controlling the depth of the scoring line of the broken cover, preventing the scoring line from being too deep and easy to explode the cover, resulting in the direct scrapping of the pull ring cover, or the batch scrapping of the V card caused by the scoring line of the pull ring cover being too shallow, reducing the risk of quality accidents, ensuring the stability of quality, saving manpower and material resources, improving the yield rate, and improving work efficiency.

Description

Reticle cutter control system, method, equipment and storage medium

Technical Field

The invention mainly relates to the technical field of manufacturing instruments, in particular to a scoring blade control system, a scoring blade control method, a scoring blade control device and a scoring blade storage medium.

Background

The existing scribing control system is used for mechanically controlling the scribing and nicking tool to work, and because the flexibility of the scribing and nicking tool for pulling the ring cover is not high, the problem that the ring cover is directly scrapped due to too deep scribing exists frequently, or the batch scrapping accident of the V card is caused due to too shallow scribing of the ring cover is solved, so that manpower and material resources are wasted, the yield is influenced, and the working efficiency is also reduced.

Disclosure of Invention

The invention aims to solve the technical problem of providing a reticle cutter control system, a reticle cutter control method, reticle cutter control equipment and a storage medium aiming at the defects of the prior art.

The technical scheme for solving the technical problems is that the reticle cutter control system comprises a PLC control circuit and a temperature control circuit;

the PLC control circuit is used for importing the scribing data, obtaining preset reference control data corresponding to preset channels corresponding to the scribing cutters one by one from a preset database, and respectively carrying out difference analysis on the preset reference control data according to the scribing data to obtain the scribing cutter adjustment values corresponding to the preset channels;

the temperature control circuit is used for respectively carrying out voltage conversion on the adjustment values of the scribing cutters to obtain voltage values corresponding to the preset channels one by one, respectively carrying out temperature conversion on the voltage values to obtain temperature values corresponding to the preset channels one by one, and respectively carrying out heating or cooling treatment according to the scribing cutters corresponding to the temperature values.

Based on the above-mentioned control system of the reticle cutter, the invention also provides a control method of the reticle cutter.

A scoring blade control method comprising the steps of:

importing the scribing data, and obtaining preset reference control data corresponding to preset channels corresponding to the scribing cutters one by one from a preset database;

respectively carrying out difference analysis on each preset reference control data according to the scribing data to obtain a scribing cutter adjustment value corresponding to each preset channel;

respectively carrying out voltage conversion on the adjustment values of the dividing knives to obtain voltage values corresponding to the preset channels one by one;

temperature conversion is carried out on each voltage value to obtain a temperature value corresponding to each preset channel one by one;

And heating, maintaining or cooling the corresponding scribing cutter according to each temperature value.

Based on the above-mentioned control method of the dividing knife, the invention also provides a control device of the dividing knife.

A reticle knife control device comprising a memory, a processor and a computer program stored in the memory and executable on the processor, the reticle knife control method as described above being implemented when the processor executes the computer program.

Based on the above-mentioned method for controlling the reticle cutter, the invention also provides a computer readable storage medium.

Another technical solution of the present invention to solve the above technical problems is a computer-readable storage medium storing a computer program which, when executed by a processor, implements the reticle blade control method as described above.

The method has the advantages that the difference value analysis of the preset reference control data is carried out on the score data to obtain the score knife adjustment value, the voltage of the score knife adjustment value is converted to obtain the voltage value, the temperature of the voltage value is converted to obtain the temperature value, and the temperature of the score knife corresponding to the temperature value is increased or decreased according to the temperature of the score knife corresponding to the temperature value, so that the score line depth of the broken cover can be controlled, the condition that the pull ring cover is directly scrapped due to the fact that the score line is too deep or the condition that the V card is scrapped in batches due to the fact that the score line is too shallow is prevented, the risk of quality accidents is reduced, the stability of quality is guaranteed, manpower and material resources are saved, the yield is improved, and the working efficiency is also improved.

Drawings

FIG. 1 is a block diagram of a scoring blade control system according to one embodiment of the present invention;

FIG. 2 is a circuit diagram of a power conversion circuit according to an embodiment of the present invention;

FIG. 3 is a circuit diagram of a PLC control circuit according to another embodiment of the present invention;

FIG. 4 is a circuit diagram of a data input control board according to another embodiment of the present invention;

FIG. 5 is a circuit diagram of a temperature control board according to another embodiment of the present invention;

FIG. 6 is a circuit diagram of an indicator light control unit according to another embodiment of the present invention;

FIG. 7 is a second circuit diagram of an indicator control unit according to another embodiment of the present invention;

FIG. 8 is a third circuit diagram of an indicator control unit according to another embodiment of the present invention;

FIG. 9 is a fourth circuit diagram of an indicator light control unit according to another embodiment of the present invention;

FIG. 10 is a circuit diagram of a temperature measuring unit according to another embodiment of the present invention;

FIG. 11 is a circuit diagram of a temperature control circuit according to another embodiment of the present invention;

fig. 12 is a flowchart of a method for controlling a reticle cutter according to an embodiment of the invention.

Detailed Description

The principles and features of the present invention are described below with reference to the drawings, the examples are illustrated for the purpose of illustrating the invention and are not to be construed as limiting the scope of the invention.

Fig. 1 is a block diagram of a reticle knife control system according to an embodiment of the present invention.

As shown in fig. 1, a reticle cutter control system comprises a PLC control circuit and a temperature control circuit;

the PLC control circuit is used for importing the scribing data, obtaining preset reference control data corresponding to preset channels corresponding to the scribing cutters one by one from a preset database, and respectively carrying out difference analysis on the preset reference control data according to the scribing data to obtain the scribing cutter adjustment values corresponding to the preset channels;

the temperature control circuit is used for respectively carrying out voltage conversion on the adjustment values of the scribing cutters to obtain voltage values corresponding to the preset channels one by one, respectively carrying out temperature conversion on the voltage values to obtain temperature values corresponding to the preset channels one by one, and respectively carrying out heating or cooling treatment according to the scribing cutters corresponding to the temperature values.

It should be understood that the scribe line data is measured by a scribe line detector and manually entered by a touch screen.

Specifically, according to the compensation amount (i.e., the compensation control amount) provided by each channel (i.e., the preset channel), the output module provides a corresponding control value for the single-phase voltage regulating module controller of each channel, the control value is converted into a corresponding voltage (i.e., the voltage value), the corresponding voltage value is converted into temperature energy (i.e., the temperature value) through the heater, and the reticle cutter is compensated, so that the result of automatically controlling the reticle is obtained.

In the above embodiment, the difference value analysis of each preset reference control data is performed on the score data to obtain the score knife adjustment value, the voltage conversion of each score knife adjustment value is performed to obtain the voltage value, the temperature conversion of each voltage value is performed to obtain the temperature value, and the temperature rising or reducing treatment is performed on the score knife corresponding to each temperature value, so that the score line can be stabilized, the depth of the score line of the pull cover can be controlled, the condition that the pull cover is directly scrapped due to the too deep score line or the condition that the V card is scrapped in batches due to the too shallow score line of the pull cover is prevented, the risk of quality accidents is reduced, the stability of quality is ensured, the manpower and material resources are saved, the yield is improved, and the working efficiency is also improved.

Optionally, as an embodiment of the present invention, the PLC control circuit is specifically configured to:

importing the scribing data, and obtaining preset reference control data corresponding to preset channels corresponding to the scribing cutters one by one from a preset database;

establishing a function according to the preset reference control data to obtain a reference control data function set corresponding to the preset reference control data one by one;

performing difference calculation on the score data function sets and the reference control data function sets respectively to obtain score difference values corresponding to the preset channels one by one;

Comparing each score line difference value with a corresponding preset adjustment value interval of the preset channel respectively, and taking a preset compensation quantity corresponding to the preset difference value interval as a compensation control quantity of the corresponding preset channel if the score line difference value is positioned in the corresponding preset adjustment value interval;

And obtaining the current temperature of each scribing cutter, and respectively carrying out summation calculation on the current temperature of each scribing cutter and the corresponding compensation control quantity to obtain the adjustment value of the scribing cutter corresponding to each preset channel.

It should be understood that if the scribe line difference value is not within the corresponding preset adjustment value interval, 0 is used as the compensation control amount of the corresponding preset channel.

It should be understood that the cold start operation mode, that is, the corresponding data information is respectively called from the preset program (i.e., the preset database) to be loaded, and the reference control data (i.e., the preset reference control data) is respectively provided for the multiple channels.

Specifically, in the warm-up start operation mode, the score data is loaded into the system after being collected, and reference control data is provided for a plurality of channels after being updated. And converting the data type and the expression form according to the reference control data (namely the preset reference control data) provided by each channel to obtain a data function set (namely the reference control data function set) which can be identified by program control.

It should be understood that updating refers to updating by manually entering data, i.e. the data entered this time replaces the data entered last time.

It should be understood that the data type conversion means, for example, converting 16-bit data into 32-bit data, and the conversion of the expression form is converting a number into a proportional relationship, that is, the data conversion should be converting 0 to 27648 into a proportion of 0 to 100, for example, the number is 0 at the minimum and can only be 100 at the maximum, that is, the proportion of 0 to 100 intervals.

It should be understood that the data functions are respectively substituted into the control program (i.e. the PLC control circuit) to perform step-by-step operation, processing and conversion, so as to obtain the compensation amounts (i.e. the compensation control amounts) corresponding to the channels.

Specifically, the input data (i.e., the scribe data) is converted and subjected to addition and subtraction operation with original preset reference data (i.e., the preset reference control data) to obtain three types of results, the three types of results are larger than the preset data (i.e., the preset reference control data), the three types of results are smaller than the preset data (i.e., the preset reference control data), the data are equal to the preset data (i.e., the preset reference control data), a plurality of preset intervals (i.e., the preset difference intervals) are arranged in a program, the operation results (i.e., the scribe data difference) and the preset intervals (i.e., the preset difference intervals) are compared and screened, the data fall into which interval (i.e., the preset difference interval), and different intervals (i.e., the preset difference intervals) output different compensation control amounts.

In the above embodiment, the adjustment value of the reticle cutter is obtained by respectively analyzing the difference value of each=preset reference control data by the reticle data, so that the purpose of automatically adjusting the reticle can be achieved, the reticle is always stabilized within the standard control range, and the product quality is effectively ensured.

Optionally, as an embodiment of the present invention, as shown in fig. 1 and 2, the reticle blade control system further includes a power conversion circuit, where the power conversion circuit includes a switching power supply, a first air switch, a second air switch, and a third air switch;

The inlet wire end of first air switch is connected on 220V's three-phase power, the three-phase line outlet of first air switch is used for giving the temperature control circuit power supply, just one of the three-phase line outlet of first air switch looks line outlet with the inlet wire end of second air switch links together, the outlet wire end of second air switch with switching power supply's power input links together, switching power supply's power output is used for exporting 24V voltage and links together with the inlet wire end of third air switch, the outlet wire end of third air switch exports 24V voltage and is used for giving the PLC control circuit power supply, the ground connection of first air switch, the ground connection of second air switch, the ground connection of third air switch and switching power supply's ground connection all ground connection.

Specifically, as shown in fig. 2, the reticle knife control system further includes a power conversion circuit, where the power conversion circuit includes a switching power supply U, a first air switch F1, a second air switch F2, and a third air switch F3;

The inlet wire end of first air switch F1 is connected on 220V's three-phase power, a looks outlet wire end L3 in the three-phase outlet wire end of first air switch F1 with the inlet wire end of second air switch F2 links together, the outlet wire end of second air switch F2 with switching power supply U's power input links together, switching power supply U's power output end output 24V voltage and with the inlet wire end of third air switch F3 links together, the outlet wire end of third air switch F3 outputs 24V voltage, the ground terminal of first air switch F1, the ground terminal of second air switch F2, the ground terminal of third air switch F3 and switching power supply's ground terminal all is grounded.

The power conversion circuit in the embodiment provides stable power for the system.

Alternatively, as an embodiment of the present invention, as shown in fig. 3 and 5, the PLC control circuit includes a PLC control board, a display screen, a temperature measurement unit, and a temperature control board including a plurality of output terminals, where the plurality of output terminals of the temperature control board are in one-to-one correspondence with the preset channels;

The power end of the PLC control board, the power end of the temperature measuring unit and the power end of the display screen are all connected to the outlet end of the third air switch, the grounding end of the PLC control board, the grounding end of the display screen, the grounding end of the temperature control board and the grounding end of the temperature measuring unit are all grounded,

The PLC control panel is used for importing the scribing data, obtaining preset reference control data corresponding to preset channels corresponding to each scribing cutter one by one from a preset database, establishing a function according to the scribing data to obtain a scribing data function set, establishing a function according to each preset reference control data to obtain a reference control data function set corresponding to each preset reference control data one by one, carrying out difference value calculation on the scribing data function set and each reference control data function set to obtain a scribing difference value corresponding to each preset channel one by one, and comparing each scribing difference value with a preset adjustment value interval of the corresponding preset channel, wherein if the scribing difference value is located in the corresponding preset adjustment value interval, the preset compensation quantity corresponding to the preset difference value interval is used as the compensation control quantity of the corresponding preset channel;

the temperature measuring unit is used for obtaining the current temperature of each scribing cutter and sending the current temperature of each scribing cutter to the PLC control board;

The PLC control panel is further used for respectively carrying out summation calculation on the current temperature of each scribing cutter and the corresponding compensation control quantity to obtain a scribing cutter adjustment value corresponding to each preset channel, and sending the scribing cutter adjustment value to the temperature control panel and the display screen;

The 485 port of the display screen is connected with the output end of the PLC control board, and the display screen is used for displaying the reticle cutter adjusting value;

And a plurality of output ends of the temperature control plate are respectively connected with corresponding input ends in the temperature control circuit, and the temperature control plate is used for sending the reticle knife adjustment values corresponding to the preset channels to the temperature control circuit.

It should be appreciated that the model of the PLC control board can be CPU314C-2DP.

It should be understood that the touch control screen (i.e. the display screen) is used for loading reference control data information (i.e. the preset reference control data) and selecting and switching different control modes to obtain corresponding control modes.

It should be understood that the corresponding data information and logic signals may be displayed by a touch screen (i.e., the display screen).

Specifically, the power end of the PLC control board, the power end of the temperature control board SM03, the power end of the temperature measurement unit and the power end of the display screen are all connected to the outlet end of the third air switch F3, the grounding end of the PLC control board, the grounding end of the display screen, the grounding end of the temperature control board SM03 and the grounding end of the temperature measurement unit are all grounded, the 485 port of the display screen is connected with the output end of the PLC control board, and the Q0.0 port, Q0.1 port, Q0.2 port, Q0.3 port, Q0.4 port, Q0.5 port and Q0.6 port of the temperature control board are respectively connected with the corresponding input ends in the temperature control circuit.

In the embodiment, the control of the system is convenient, the scribing is always stable within the standard control range, and the product quality is effectively ensured.

Alternatively, as an embodiment of the present invention, as shown in fig. 10, the temperature measuring unit includes a temperature measuring plate, K-type thermocouples corresponding to the respective reticle blades one by one, and temperature transmitter modules corresponding to the respective K-type thermocouples one by one;

the power end of the temperature measuring plate and the power end of each temperature transmitter module are connected to the outlet end of the third air switch, and the grounding end of the temperature measuring plate is grounded;

The output ends of the K-type thermocouples are respectively connected with the input ends of the corresponding temperature transmitter modules, and the K-type thermocouples are used for acquiring the current temperature of the corresponding dividing knife and transmitting the current temperature of the corresponding dividing knife to the temperature transmitter modules;

Each output end of the temperature transmitter module is respectively connected with a corresponding input end in the temperature measuring plate, and the temperature transmitter module is used for converting the current temperature of the corresponding dividing knife into dividing knife voltage signals and sending each dividing knife voltage signal to the temperature measuring plate;

the temperature measuring board is used for sending the voltage signals of the reticle cutters to the PLC control board;

the PLC control board is also used for obtaining the current temperature of each reticle cutter according to the voltage signals of each reticle cutter.

It should be appreciated that the size of the K-type thermoelectric is 1.5 x 200mm and the model of the temperature transmitter module is MIK-ST500.

Specifically, the temperature measurement unit includes a temperature measurement plate SM04, a first K-type thermocouple BT1, a second K-type thermocouple BT2, a third K-type thermocouple BT3, a fourth K-type thermocouple BT4, a fifth K-type thermocouple BT5, a sixth K-type thermocouple BT6, a seventh K-type thermocouple BT7, a first temperature transmitter module TT1, a second temperature transmitter module TT2, a third temperature transmitter module TT3, a fourth temperature transmitter module TT4, a fifth temperature transmitter module TT5, a sixth temperature transmitter module TT6, and a seventh temperature transmitter module TT7;

The L+ port of the temperature measurement board SM04, the power end of the first temperature transmitter module TT1, the power end of the second temperature transmitter module TT2, the power end of the third temperature transmitter module TT3, the power end of the fourth temperature transmitter module TT4, the power end of the fifth temperature transmitter module TT5, the power end of the sixth temperature transmitter module TT6 and the power end of the seventh temperature transmitter module TT7 are all connected to the outlet end of the third air switch F3, and the M port of the temperature measurement board SM04 is grounded;

the PIW272 port of the temperature measuring plate SM04 is connected with the V port of the first temperature transmitter module TT1, the two output ends of the first K-type thermocouple BT1 are respectively connected with the 1 port of the first temperature transmitter module TT1 and the 3 port of the first temperature transmitter module TT1, the PIW274 port of the temperature measuring plate SM04 is connected with the V port of the second temperature transmitter module TT2, the two output ends of the second K-type thermocouple BT2 are respectively connected with the 1 port of the second temperature transmitter module TT2 and the 3 port of the second temperature transmitter module TT2, the PIW276 port of the temperature measuring plate SM04 is connected with the V port of the third temperature transmitter module TT3, the two output ends of the third K-type thermocouple BT3 are respectively connected with the 1 port of the third temperature transmitter module 3 and the 3 port of the third temperature transmitter module TT3, the PIW278 port of the temperature measuring plate SM04 is connected with the V port of the fourth temperature transmitter module TT4, the two output ends of the fourth K-type thermocouple BT4 are respectively connected with the 1 port of the fourth temperature transmitter module TT4 and the 3 port of the fourth temperature transmitter module TT4, the PIW280 port of the temperature measuring plate SM04 is connected with the V port of the fifth temperature transmitter module TT5, the two output ends of the fifth K-type thermocouple BT5 are respectively connected with the 1 port of the fifth temperature transmitter module TT5 and the 3 port of the fifth temperature transmitter module TT5, the PIW282 port of the temperature measuring plate SM04 is connected with the V port of the sixth temperature transmitter module 6, two output ends of the sixth K-type thermocouple BT6 are respectively connected with the 1 port of the sixth temperature transmitter module TT6 and the 3 port of the sixth temperature transmitter module TT6, the PIW284 port of the temperature measuring plate SM04 is connected with the V port of the seventh temperature transmitter module TT7, and two output ends of the seventh K-type thermocouple BT7 are respectively connected with the 1 port of the seventh temperature transmitter module TT7 and the 3 port of the seventh temperature transmitter module TT 7.

In the embodiment, the aim of automatically adjusting the scribing can be achieved, so that the scribing is always stable within the standard control range, and the product quality is effectively ensured.

Alternatively, as an embodiment of the present invention, as shown in fig. 11, the temperature control circuit includes air switches in one-to-one correspondence with each of the reticle blades, ac voltage regulation modules in one-to-one correspondence with each of the air switches, and heaters in one-to-one correspondence with each of the air switches;

The wire inlet ends of the air switches are respectively connected with the wire outlet ends of the corresponding phases of the first air switches, the wire outlet ends of the air switches are respectively connected with one corresponding input end of the corresponding alternating current voltage regulating module, the output ends of the temperature control panel are respectively connected with the other corresponding input end of the corresponding alternating current voltage regulating module, the alternating current voltage regulating module is used for respectively carrying out voltage conversion on the regulating values of the dividing knives to obtain voltage values corresponding to the preset channels one by one, the grounding ends of the air switches are grounded, the grounding ends of the alternating current voltage regulating modules are grounded, the output ends of the alternating current voltage regulating modules are respectively connected with the input ends of the corresponding heaters, and the heaters are used for respectively carrying out temperature conversion on the voltage values to obtain temperature values corresponding to the preset channels one by one and carrying out heating or cooling treatment on dividing knives corresponding to the temperature values according to the dividing knives.

It should be understood that the AC voltage regulation module is a single-phase thyristor AC voltage regulation module, and the models of the single-phase thyristor AC voltage regulation module are MT2AC-1-220V55A.

Specifically, the temperature control circuit includes a fourth air switch F4, a fifth air switch F5, a sixth air switch F6, a seventh air switch F7, an eighth air switch F8, a ninth air switch F9, a tenth air switch F10, a first ac voltage regulating module A1, a second ac voltage regulating module A2, a third ac voltage regulating module A3, a fourth ac voltage regulating module A4, a fifth ac voltage regulating module A5, a sixth ac voltage regulating module A6, a seventh ac voltage regulating module A7, a first heater W1, a second heater W2, a third heater W3, a fourth heater W4, a fifth heater W5, a sixth heater W6, and a seventh heater W7;

The wire inlet end of the fourth air switch F4 is connected with the wire outlet end L3 of the first air switch F1, the wire inlet end of the fifth air switch F5 is connected with the wire outlet end L3 of the first air switch F1, the wire inlet end of the sixth air switch F6 is connected with the wire outlet end L2 of the first air switch F1, the wire inlet end of the seventh air switch F7 is connected with the wire outlet end L2 of the first air switch F1, the wire inlet end of the eighth air switch F8 is connected with the wire outlet end L1 of the first air switch F1, the wire inlet end of the ninth air switch F9 is connected with the wire outlet end L1 of the first air switch F1, the wire inlet end of the tenth air switch F10 is connected with the wire outlet end L2 of the first air switch F1, the wire outlet end of the fourth air switch F4 is connected with one input end of the first alternating current voltage regulating module A1, the outlet end of the fifth air switch F5 is connected with an input end of the second AC voltage regulating module A2, the outlet end of the sixth air switch F6 is connected with an input end of the third AC voltage regulating module A3, the outlet end of the seventh air switch F7 is connected with an input end of the fourth AC voltage regulating module A4, the outlet end of the eighth air switch F8 is connected with an input end of the fifth AC voltage regulating module A5, the outlet end of the ninth air switch F9 is connected with an input end of the sixth AC voltage regulating module A6, the outlet end of the tenth air switch F10 is connected with an input end of the seventh AC voltage regulating module A7, the Q0.0 port of the temperature control board SM03 is connected with the com port of the first AC voltage regulating module A1, the Q0.1 port of the temperature control board SM03 is connected with the com port of the second ac voltage regulating module A2, the Q0.2 port of the temperature control board SM03 is connected with the com port of the third ac voltage regulating module A3, the Q0.3 port of the temperature control board SM03 is connected with the com port of the fourth ac voltage regulating module A4, the Q0.4 port of the temperature control board SM03 is connected with the com port of the fifth ac voltage regulating module A5, the Q0.5 port of the temperature control board SM03 is connected with the com port of the sixth ac voltage regulating module A6, the Q0.6 port of the temperature control board SM03 is connected with the com port of the seventh ac voltage regulating module A7, the ground terminal of the fourth air switch F4, The grounding end of the fifth air switch F5, the grounding end of the sixth air switch F6, the grounding end of the seventh air switch F7, the grounding end of the eighth air switch F8, the grounding end of the ninth air switch F9, the grounding end of the tenth air switch F10, the grounding end of the first ac voltage regulating module A1, the grounding end of the second ac voltage regulating module A2, the grounding end of the third ac voltage regulating module A3, the grounding end of the fourth ac voltage regulating module A4, the grounding end of the fifth ac voltage regulating module A5, The grounding end of the sixth alternating current voltage regulating module A6 and the grounding end of the seventh alternating current voltage regulating module A7 are both grounded, the two output ends of the first alternating current voltage regulating module A1 are connected with the two input ends of the first heater W1, the two output ends of the second alternating current voltage regulating module A2 are connected with the two input ends of the second heater W2, the two output ends of the third alternating current voltage regulating module A3 are connected with the two input ends of the third heater W3, the two output ends of the fourth alternating current voltage regulating module A4 are connected with the two input ends of the fourth heater W4, the two output ends of the fifth alternating current voltage regulating module A5 are connected with the two input ends of the fifth heater W5, the two output ends of the sixth alternating current voltage regulating module A6 are connected with the two input ends of the sixth heater W6, and the two output ends of the seventh alternating current voltage regulating module A7 are connected with the two input ends of the seventh alternating current voltage regulating module W7.

In the embodiment, the situation that the pull ring cover is directly scrapped due to too deep scribing or the situation that the V card is scrapped in batches due to too shallow scribing of the pull ring cover is prevented, manpower and material resources are saved, the yield is improved, and the working efficiency is also improved.

Optionally, as an embodiment of the present invention, the temperature control circuit is specifically configured to:

respectively converting voltage values of the adjustment values of the dividing knives to obtain voltage values corresponding to the preset channels;

Respectively carrying out temperature value conversion on each voltage value to obtain a temperature value corresponding to each preset channel;

And respectively carrying out temperature raising treatment on the corresponding dividing knife according to each temperature value to raise the temperature of the corresponding dividing knife, or respectively carrying out temperature lowering treatment on the corresponding dividing knife according to each temperature value to lower the temperature of the corresponding dividing knife.

In the above embodiment, the voltage values of the adjustment values of each scoring blade are respectively converted to obtain the voltage values, the temperature values of each voltage value are respectively converted to obtain the temperature values, and the temperature of the scoring blade is raised by the temperature raising treatment of each scoring blade according to each temperature value, so that the scoring depth of an object to be scored is increased, or the temperature of the scoring blade is lowered by the temperature lowering treatment of each scoring blade according to each temperature value, so that the scoring depth of the object to be processed is reduced, and the situations of direct scrapping of a pull ring cover caused by too deep scoring, batch scrapping accidents of V cards caused by too shallow scoring of the pull ring cover are prevented.

Alternatively, as another embodiment of the present invention, as shown in fig. 3 to 5, the PLC control circuit further includes a data input control board, and a 4M port of the data input control board is grounded.

Specifically, the PLC control circuit further includes a data input control board SM01, and the 4M port of the data input control board SM01 is grounded with 0VDC.

In the above embodiment, the interface can be used as an expansion input interface, so that subsequent interface expansion is facilitated.

Alternatively, as another embodiment of the present invention, as shown in fig. 6 to 9, the PLC control circuit further includes an indication lamp control unit including an indication lamp control board, a first switch, a second switch, an indication lamp, a first solenoid valve, a second solenoid valve, a third solenoid valve, a fourth solenoid valve, a fifth solenoid valve, a sixth solenoid valve, and a seventh solenoid valve;

the 1L+ port of the indicator light control board, one end of the first switch, one end of the second switch, the 2L+ port of the indicator light control board and the 3L+ port of the indicator light control board are all connected to the outlet end of the third air switch, and the two 2M ports of the indicator light control board, the 3M port of the indicator light control board, one end of the indicator light, one end of the first electromagnetic valve, one end of the second electromagnetic valve, one end of the third electromagnetic valve, one end of the fourth electromagnetic valve, one end of the fifth electromagnetic valve, one end of the sixth electromagnetic valve and one end of the seventh electromagnetic valve are all grounded;

The I124.0 port of the indicator light control board is connected with the other end of the first switch, the I124.1 port of the indicator light control board is connected with the other end of the second switch, the Q124.0 port of the indicator light control board is connected with the other end of the first electromagnetic valve, the Q124.1 port of the indicator light control board is connected with the other end of the second electromagnetic valve, the Q124.2 port of the indicator light control board is connected with the other end of the third electromagnetic valve, the Q124.3 port of the indicator light control board is connected with the other end of the fourth electromagnetic valve, the Q124.4 port of the indicator light control board is connected with the other end of the fifth electromagnetic valve, the Q124.5 port of the indicator light control board is connected with the other end of the sixth electromagnetic valve, the Q124.6 port of the indicator light control board is connected with the other end of the seventh electromagnetic valve, and the Q125.0 port of the indicator light control board is connected with the other end of the indicator light.

Preferably, the first electromagnetic valve, the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve, the fifth electromagnetic valve, the sixth electromagnetic valve and the seventh electromagnetic valve are all 4V110-06 in model number.

Specifically, the indicator light control unit includes an indicator light control board SM02, a first switch S1, a second switch S2, an indicator light L, a first electromagnetic valve YV1, a second electromagnetic valve YV2, a third electromagnetic valve YV3, a fourth electromagnetic valve YV4, a fifth electromagnetic valve YV5, a sixth electromagnetic valve YV6, and a seventh electromagnetic valve YV7;

The 1l+ port of the indicator light control board SM02, one end of the first switch S1, one end of the second switch S2, the 2l+ port of the indicator light control board SM02, and the 3l+ port of the indicator light control board SM02 are all connected to the outlet port +24vdc of the third air switch, and the two 2M ports of the indicator light control board SM02, the 3M port of the indicator light control board SM02, one end of the indicator light L, one end of the first electromagnetic valve YV1, one end of the second electromagnetic valve YV2, one end of the third electromagnetic valve YV3, one end of the fourth electromagnetic valve YV4, one end of the fifth electromagnetic valve YV5, one end of the sixth electromagnetic valve YV6, and one end of the seventh electromagnetic valve YV7 are all grounded to 0VDC;

the I124.0 port of the indicator light control board SM02 is connected with the other end of the first switch S1, the I124.1 port of the indicator light control board SM02 is connected with the other end of the second switch S2, the Q124.0 port of the indicator light control board SM02 is connected with the other end of the first electromagnetic valve YV1, the Q124.1 port of the indicator light control board SM02 is connected with the other end of the second electromagnetic valve YV2, the Q124.2 port of the indicator light control board SM02 is connected with the other end of the third electromagnetic valve YV3, the Q124.3 port of the indicator light control board SM02 is connected with the other end of the fourth electromagnetic valve YV4, the Q124.4 port of the indicator light control board SM02 is connected with the other end of the fifth electromagnetic valve YV5, the Q124.5 port of the indicator light control board SM02 is connected with the other end of the sixth electromagnetic valve YV6, and the Q124.3 port of the indicator light control board SM02 is connected with the other end of the indicator light control board YV 7.

In the above embodiment, the system is controlled to be turned on or off, and the operation condition of the system is intuitively known through the indicator lamp.

Optionally, as another embodiment of the invention, the invention has the beneficial effects that a plurality of sample cover reticles are sampled to obtain a group of reticle data, the reticle data are loaded into a program to be operated to obtain positive or negative compensation quantity of each corresponding channel, the compensation quantity is converted through data to obtain corresponding pulse width amplitude, the corresponding heater is controlled by the amplitude to obtain corresponding heat radiation energy, and the reticle knife is influenced by heat radiation to form a proportional change, so that the reticle is correspondingly changed, the purpose of automatically adjusting the reticle is achieved, the reticle is always stabilized within a standard control range, and the product quality is effectively ensured.

Optionally, as another embodiment of the present invention, the compensation amount (i.e. the compensation control amount) is a value, the value is processed by a program, a pulse output is generated at an output point, the output pulse frequency is determined by the value of the compensation amount, the values are in a proportional relationship, a 24 v dc voltage is pulse-controlled to obtain a 0-5 output voltage, the output voltage is provided to a control end of the single-phase voltage regulating module, the controlled single-phase voltage regulating module outputs a corresponding 0-220 v adjustable voltage, the output corresponding voltage control heater is converted into a corresponding temperature, and the corresponding temperature carries out temperature rise and fall compensation on the reticle knife, so as to achieve the purpose of automatically controlling the reticle.

Optionally, as another embodiment of the present invention, the present invention may select a chiller preprocessing program to load preset data to process a chiller, the apparatus may enter production control after preheating, acquire sample reticle data, load the acquired data into the program to perform operation processing, and obtain a phase result, and output the phase result to a terminal to control execution of each target.

Optionally, as another embodiment of the present invention, the PLC module (i.e. the PLC control circuit) of the present invention performs an operation process on the collected data information and the control signal according to the control program, and controls the terminal device through the output module according to the processing result, and simultaneously, the corresponding data information and the logic signal can be displayed through the touch screen.

Alternatively, as another embodiment of the present invention, the temperature maintaining process is performed on the corresponding reticle blade according to each of the temperature values, respectively, so that the temperature of the corresponding reticle blade is maintained.

It should be appreciated that if the temperature value is 0, the temperature of the scoring blade is maintained.

Fig. 12 is a flow chart of a control method of a scoring blade according to an embodiment of the present invention.

Alternatively, as another embodiment of the present invention, as shown in fig. 12, a reticle blade control method includes:

importing the scribing data, and obtaining preset reference control data corresponding to preset channels corresponding to the scribing cutters one by one from a preset database;

respectively carrying out difference analysis on each preset reference control data according to the scribing data to obtain a scribing cutter adjustment value corresponding to each preset channel;

respectively carrying out voltage conversion on the adjustment values of the dividing knives to obtain voltage values corresponding to the preset channels one by one;

temperature conversion is carried out on each voltage value to obtain a temperature value corresponding to each preset channel one by one;

and heating or cooling the corresponding scribing cutter according to each temperature value.

Alternatively, another embodiment of the present invention provides a reticle knife control device including a memory, a processor, and a computer program stored in the memory and executable on the processor, which when executed by the processor, implements the reticle knife control method as described above. The device may be a computer or the like.

Alternatively, another embodiment of the present invention provides a computer-readable storage medium storing a computer program which, when executed by a processor, implements the reticle blade control method as described above.

It will be clear to those skilled in the art that, for convenience and brevity of description, specific working procedures of the apparatus and units described above may refer to corresponding procedures in the foregoing method embodiments, which are not described herein again.

In the several embodiments provided by the present application, it should be understood that the disclosed apparatus and method may be implemented in other manners. For example, the apparatus embodiments described above are merely illustrative, e.g., the division of elements is merely a logical functional division, and there may be additional divisions of actual implementation, e.g., multiple elements or components may be combined or integrated into another system, or some features may be omitted, or not performed.

The units described as separate units may or may not be physically separate, and units shown as units may or may not be physical units, may be located in one place, or may be distributed over a plurality of network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the embodiment of the present invention.

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. For such understanding, the technical solution of the present invention is essentially or part of what contributes to the prior art, or all or part of the technical solution may be embodied in the form of a software product stored in a storage medium, comprising several instructions for causing a computer device (which may be a personal computer, a server, a network device, etc.) to perform all or part of the steps of the method of the various embodiments of the present invention. The storage medium includes a U disk, a removable hard disk, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk, an optical disk, or other various media capable of storing program codes.

The present invention is not limited to the above embodiments, and various equivalent modifications and substitutions can be easily made by those skilled in the art within the technical scope of the present invention, and these modifications and substitutions are intended to be included in the scope of the present invention. Therefore, the protection scope of the invention is subject to the protection scope of the claims.

Claims (9)

1. A scribing knife control system, characterized by comprising a PLC control circuit and a temperature control circuit; The PLC control circuit is used to import the line cutting data, and obtain the preset reference control data corresponding to the preset channels corresponding to each line cutting knife from the preset database, and perform difference analysis on each preset reference control data according to the line cutting data to obtain the line cutting knife adjustment value corresponding to each preset channel; The temperature control circuit is used to perform voltage conversion on each of the adjustment values of the scoring knife to obtain voltage values corresponding to each of the preset channels, and to perform temperature conversion on each of the voltage values to obtain temperature values corresponding to each of the preset channels, and to perform temperature increase or temperature decrease processing on the corresponding scoring knife according to each of the temperature values; The PLC control circuit is specifically used for: Importing the scoring data, and obtaining the preset reference control data corresponding to the preset channels corresponding to each scoring knife from the preset database; Establishing a function according to the line data to obtain a line data function group; and establishing a function according to each of the preset reference control data to obtain a reference control data function group corresponding to each of the preset reference control data; Perform difference calculations on the scoreline data function group and each of the reference control data function groups to obtain scoreline differences corresponding to each of the preset channels; Compare each of the scribed line differences with the preset adjustment value interval of the corresponding preset channel respectively; if the scribed line difference is within the corresponding preset adjustment value interval, use the preset compensation amount corresponding to the preset adjustment value interval as the compensation control amount of the corresponding preset channel; The current temperature of each scribing knife is obtained, and the current temperature of each scribing knife and the corresponding compensation control amount are respectively summed and calculated to obtain the scribing knife adjustment value corresponding to each preset channel. 2. The scribing knife control system according to claim 1, characterized in that the scribing knife control system further comprises a power conversion circuit, the power conversion circuit comprises a switching power supply, a first air switch, a second air switch and a third air switch; The input end of the first air switch is connected to a 220V three-phase power supply, the three-phase output end of the first air switch is used to power the temperature control circuit, and one of the three-phase output ends of the first air switch is connected to the input end of the second air switch, the output end of the second air switch is connected to the power input end of the switching power supply, the power output end of the switching power supply is used to output a 24V voltage and is connected to the input end of the third air switch, the output end of the third air switch outputs a 24V voltage for powering the PLC control circuit, and the grounding end of the first air switch, the grounding end of the second air switch, the grounding end of the third air switch and the grounding end of the switching power supply are all grounded. 3. The scribing knife control system according to claim 2, characterized in that the PLC control circuit comprises a PLC control board, a display screen, a temperature measurement unit and a temperature control board comprising a plurality of output terminals, and the plurality of output terminals of the temperature control board correspond one-to-one to each of the preset channels; The power supply end of the PLC control board, the power supply end of the temperature control board, the power supply end of the temperature measuring unit and the power supply end of the display screen are all connected to the outlet end of the third air switch, and the grounding end of the PLC control board, the grounding end of the display screen, the grounding end of the temperature control board and the grounding end of the temperature measuring unit are all grounded. The PLC control board is used to import the engraving data, and obtain the preset reference control data corresponding to the preset channels corresponding to each engraving knife from the preset database; and establish a function according to the engraving data to obtain the engraving data function group; and respectively establish a function according to each of the preset reference control data to obtain the reference control data function group corresponding to each of the preset reference control data; and respectively perform difference calculation between the engraving data function group and each of the reference control data function groups to obtain the engraving difference corresponding to each of the preset channels; and respectively compare each of the engraving difference with the preset adjustment value interval of the corresponding preset channel; if the engraving difference is within the corresponding preset adjustment value interval, the preset compensation amount corresponding to the preset adjustment value interval is used as the compensation control amount of the corresponding preset channel; The temperature measuring unit is used to obtain the current temperature of each scoring knife and send the current temperature of each scoring knife to the PLC control board; The PLC control board is also used to respectively calculate the sum of the current temperature of each of the scoring knives and the corresponding compensation control amount to obtain the scoring knife adjustment value corresponding to each of the preset channels, and send the scoring knife adjustment value to the temperature control board and the display screen; The 485 port of the display screen is connected to the output end of the PLC control board, and the display screen is used to display the adjustment value of the scoring knife; The multiple output ends of the temperature control board are respectively connected to the corresponding input ends in the temperature control circuit, and the temperature control board is used to send the scoring knife adjustment value corresponding to each of the preset channels to the temperature control circuit. 4. The scribing knife control system according to claim 3, characterized in that the temperature measurement unit comprises a temperature measurement board, a K-type thermocouple corresponding to each of the scribing knives, and a temperature transmitter module corresponding to each of the K-type thermocouples; The power supply end of the temperature measuring board and the power supply end of each of the temperature transmitter modules are connected to the outlet end of the third air switch, and the grounding end of the temperature measuring board is grounded; The output end of each K-type thermocouple is respectively connected to the input end of the corresponding temperature transmitter module, and the K-type thermocouple is used to obtain the current temperature of the corresponding scoring knife and send the current temperature of the corresponding scoring knife to the temperature transmitter module; Each output end of the temperature transmitter module is connected to the corresponding input end of the temperature measurement board, and the temperature transmitter module is used to convert the current temperature of the corresponding scoring knife into a scoring knife voltage signal, and send each scoring knife voltage signal to the temperature measurement board; The temperature measurement board is used to send the voltage signal of each of the scoring knives to the PLC control board; The PLC control board is also used to obtain the current temperature of each of the scribing knives according to the voltage signal of each of the scribing knives. 5. The scribing knife control system according to claim 3, characterized in that the temperature control circuit comprises an air switch corresponding to each scribing knife, an AC voltage regulating module corresponding to each air switch, and a heater corresponding to each air switch; The inlet end of each of the air switches is respectively connected to the outlet end of the corresponding phase of the first air switch, the outlet end of each of the air switches is respectively connected to an input end of the corresponding AC voltage regulating module, the output ends of the temperature control board are respectively connected to another input end of the corresponding AC voltage regulating module, the AC voltage regulating module is used to perform voltage conversion on each of the scoring knife adjustment values to obtain voltage values corresponding to each of the preset channels one by one, the grounding end of each of the air switches is grounded, the grounding end of each of the AC voltage regulating modules is grounded, the output end of each of the AC voltage regulating modules is respectively connected to the input end of the corresponding heater, the heater is used to perform temperature conversion on each of the voltage values to obtain temperature values corresponding to each of the preset channels, and the corresponding scoring knife is heated or cooled according to each of the temperature values. 6. The scribing knife control system according to claim 1, characterized in that the temperature control circuit is specifically used for: Convert each of the scribing knife adjustment values into a voltage value to obtain a voltage value corresponding to each of the preset channels; Convert each of the voltage values into a temperature value to obtain a temperature value corresponding to each of the preset channels; According to each temperature value, the corresponding scoring knife is heated up so that the temperature of the corresponding scoring knife increases; or, according to each temperature value, the corresponding scoring knife is cooled down so that the temperature of the corresponding scoring knife decreases. 7. A scribing knife control method, characterized in that it comprises the following steps: Importing the scoring data, and obtaining the preset reference control data corresponding to the preset channels corresponding to each scoring knife from the preset database; Performing difference analysis on each of the preset reference control data according to the line data to obtain a line cutter adjustment value corresponding to each of the preset channels; Performing voltage conversion on each of the scribing knife adjustment values respectively to obtain voltage values corresponding to each of the preset channels; Performing temperature conversion on each of the voltage values to obtain temperature values corresponding to each of the preset channels; According to each of the temperature values, the corresponding scoring knife is heated or cooled; The process of performing difference analysis on each of the preset reference control data according to the line data to obtain the line cutter adjustment value corresponding to each of the preset channels includes: Establishing a function according to the line data to obtain a line data function group; and establishing a function according to each of the preset reference control data to obtain a reference control data function group corresponding to each of the preset reference control data; Perform difference calculations on the scoreline data function group and each of the reference control data function groups to obtain scoreline differences corresponding to each of the preset channels; Compare each of the scribed line differences with the preset adjustment value interval of the corresponding preset channel respectively; if the scribed line difference is within the corresponding preset adjustment value interval, use the preset compensation amount corresponding to the preset adjustment value interval as the compensation control amount of the corresponding preset channel; The current temperature of each scribing knife is obtained, and the current temperature of each scribing knife and the corresponding compensation control amount are respectively summed and calculated to obtain the scribing knife adjustment value corresponding to each preset channel. 8. A scribing knife control device, comprising a memory, a processor, and a computer program stored in the memory and executable on the processor, wherein when the processor executes the computer program, the scribing knife control method according to claim 7 is implemented. 9. A computer-readable storage medium storing a computer program, wherein when the computer program is executed by a processor, the scribing knife control method according to claim 7 is implemented.