CN205335171U

CN205335171U - Coil drive circuit of contactor

Info

Publication number: CN205335171U
Application number: CN201521142970.1U
Authority: CN
Inventors: 苏俊熙; 符威
Original assignee: Mornsun Guangzhou Science and Technology Ltd
Current assignee: Mornsun Guangzhou Science and Technology Ltd
Priority date: 2015-12-31
Filing date: 2015-12-31
Publication date: 2016-06-22
Anticipated expiration: 2025-12-31

Abstract

The utility model provides a coil drive circuit of contactor, by diode D3, N -MOS manages Q2, resistance R1, resistance R2 and resistance R3 constitute, wherein, square signal's rising edge is formed by the narrow pulse signal CLK of clock, N -MOS pipe Q2 for control coil drive circuit switches on the back, in the actuation stage of contactor, through the attract current ics2 of square wave generator from attract current sense terminal detecting coil, the falling edge of output square -wave signal signal after the comparison operation carries out, the square signal's that forms with the narrow pulse signal CLK of clock rising edge constitutes actuation duty cycle signal together, the break -make that is used for control coil drive circuit's N -MOS pipe Q2, get into the holding stage up to the contactor, in the holding stage of contactor, through the holding current ics1 of square wave generator from holding current detection end detecting coil, carry out the falling edge of output square -wave signal signal after the comparison operation, the square signal's that forms with the narrow pulse signal CLK of clock rising edge forms holding duty cycle signal together for control coil drive circuit's N -MOS pipe Q2's break -make.

Description

Coil drive circuit of contactor

Technical Field

The utility model relates to an ac contactor field, concretely relates to coil drive circuit and coil drive current's of contactor control method.

Background

The traditional contactor operating system consists of a coil, a static iron core, an armature and a reaction spring. When the coil of the contactor is electrified, an attraction force is generated between the static iron core and the armature, when the attraction force is larger than the counterforce of the spring, the armature is attracted to the static iron core until the armature is contacted with the static iron core, the main contact is closed, and the process is called as an attraction process. The process that the coil is continuously electrified, the armature keeps contact with the static iron core, and the main contact keeps a closed state is called a holding process. When the current in the coil is reduced or interrupted, the attraction force of the static iron core to the armature is reduced, and when the attraction force is smaller than the reaction force of the spring, the armature returns to the open position, and the main contacts are separated, and the process is called a releasing process.

The contactor is used for frequently connecting and disconnecting an AC circuit and a DC circuit, and the contactor can be used for remotely controlling a low-voltage electrical appliance. The main control object is an electric motor, and the electric motor can also be used for controlling electric loads such as an electric heater, an electric welding machine, an illuminating lamp and the like. At present, the using amount of the national contactors is large, when the contactors with medium and large capacity are in a holding state, the active power consumed by each contactor is about 60W on average, and the power factor is only about 0.3. The reduction of the energy consumption of the contactor makes a great contribution to energy conservation and emission reduction.

The existing contactor electricity-saving device adopts the mode of converting alternating current into direct current, attracting large current and keeping small current, thereby greatly reducing the iron loss and copper loss of an electromagnetic coil and the loss of a short-circuit ring and reducing the active power consumption by more than 90 percent. However, these technologies have certain defects, and only the problem of active power consumption is solved, but the power factor cannot be improved, and some power saving technologies can also reduce the power factor. As in the 200510029373.2 patent, the solenoid coil is energized in a pulsed fashion, causing the solenoid coil to operate at a constant low current; by adopting the mode to work, a large amount of harmonic waves can be generated, the effective value of the input current does not follow the input voltage, the power factor is very low, and the actual PF value is smaller than 0.3 when a prototype is manufactured according to the technology. The techniques of the patents 201210196762.4 and 201010040019.9, according to which a prototype is made with a power factor of less than 0.1, excite the solenoid coil near the zero crossing of the input ac voltage so that the input current and output voltage are in a similar anti-phase state.

In the national standard GB21518-2008, three energy efficiency classes are distinguished according to the contactor coil losses. Generally, the traditional contactor has 3-level energy efficiency, and the contactor with the electricity saving technology can achieve 2-level energy efficiency. For contactors with capacity above 100A, coil holding power consumption needs to be reduced below 1VA to achieve class 1 energy efficiency. Most of the existing contactor electricity-saving technologies do not consider the problem of power factor, and the existing electricity-saving technologies are adopted, so that 1-level energy efficiency is difficult to achieve.

To the foretell defect that prior art exists, the utility model provides an alternating current contactor's power saving circuit can improve power factor when reducing contactor coil active power consumption for traditional contactor reaches 1 level efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a coil drive circuit that sampling and circuit operating condition switch in a flexible way, and easily design the realization is provided.

Correspondingly, the utility model discloses another technical problem that will solve is, provides a coil drive current's control method that sampling and circuit operating condition switch are nimble, and easily design realization.

In order to achieve the above object of the present invention, the present invention provides a coil driving circuit of a contactor, which is suitable for a square wave generator to control the driving current of an adjusting coil, the coil driving circuit is composed of a diode D3, a N-MOS transistor Q2, a resistor R1, a resistor R2 and a resistor R3, the cathode of the diode D3 is connected to the input end of the coil of the contactor, and the cathode of the diode D3 is further led out as the first input end of the coil driving circuit; the anode of the diode D3 is respectively connected with the drain of the N-MOS tube Q2 and the output end of the contactor coil, the source of the N-MOS tube Q2 is respectively connected with one end of the resistor R3 and one end of the resistor R1, and the other end of the resistor R3 is grounded; the other end of the resistor R1 is grounded through a resistor R2; the grid electrode of the N-MOS tube Q2 is led out to be used as a second input end and is used for being connected with the square wave signal output end of the square wave generator; one end of the resistor R3 is led out to be used as a holding current detection end; the other end of the resistor R1 is led out to be used as a pull-in current detection end; the contactor control circuit comprises a contactor, a clock narrow pulse signal CLK, a coil driving circuit, an N-MOS tube Q2, a square wave generator, a detection coil, a pull-in current Ics2, a pull-in duty ratio signal and a pull-in duty ratio signal, wherein the clock narrow pulse signal CLK forms a rising edge of the square wave signal to control the conduction of the N-MOS tube Q2 of the coil driving circuit, the pull-in current Ics2 of the detection coil is detected from a pull-in current detection end by the square wave generator in the pull-in stage of the contactor, and the falling edge of the square wave signal is output after comparison operation and forms the; in the holding stage of the contactor, the square wave generator is used for detecting the holding current Ics1 of the coil from the holding current detection end, the falling edge of the square wave signal is output after comparison operation is carried out, and the falling edge and the rising edge of the square wave signal formed by the clock narrow pulse signal CLK form a holding duty ratio signal together for controlling the on-off of the N-MOS tube Q2 of the coil driving circuit.

Preferably, the pull-in current Ics2 of the coil driving circuit is 10 to 20 times the pull-in current Ics 1.

Preferably, the current peak value of the pull-in current Ics2 of the coil driving circuit isThe current peak of the holding current Ics1 is

Preferably, the square-wave generator comprises a signal generation module and a first logic circuit, a first input end of the first logic circuit is connected with the DELAY signal DELAY, a second input end of the first logic circuit is connected with an output of the signal generation module, and an output of the first logic circuit is used as a first square-wave output end GATE1 of the square-wave generator; the signal generation module is used for generating a duty cycle signal SIGN1 for controlling the N-MOS transistor Q1 so as to control the on-off of the N-MOS transistor Q1; the DELAY signal DELAY is used for controlling the first logic circuit to shield the signal SIGN1 in the pull-in stage, so that the first square wave output end of the square wave generator does not output a signal to enable the PFC circuit to be out of operation; in the holding stage, the first logic circuit is controlled not to shield the signal SIGN1, so that the first square wave output end of the square wave generator outputs a signal for controlling the operation of the PFC circuit.

Preferably, the square wave generator comprises a clock generation module, a first comparator, a second comparator, a delay signal generation module and a second logic circuit, and the specific connection relationship is that a first input end of the first comparator is connected with a holding current detection end of the coil driving circuit, and a second input end of the first comparator is connected with a first voltage reference; a first input end of the second comparator is connected with a pull-in current detection end of the coil driving circuit, and a second input end of the second comparator is connected with a second voltage reference; the output of the clock generation module, the output of the first comparator, the output of the second comparator and the output of the delay signal generation module are respectively connected with the input of a second logic circuit, and the output of the second logic circuit is used as a second square wave output end of the square wave generator.

The utility model also provides a control method of the driving current of the contactor coil, the driving current of the coil is adjusted by adopting a peak current control mode to control the duty ratio of the N-MOS tube Q2 of the coil driving circuit, the duty ratio control of the N-MOS transistor Q2 of the coil driving circuit comprises the following steps that a clock controls the conduction stage of a switching tube, a clock narrow pulse signal CLK forms the rising edge of a square wave signal to control the conduction of the N-MOS transistor Q2 of the coil driving circuit, in the pull-in stage of the contactor, pull-in current Ics2 of the coil is detected by a square wave generator, the falling edge of a square wave signal is output after comparison operation is carried out, the pull-in duty ratio signal is formed together with the rising edge of the square wave signal formed by the clock narrow pulse signal CLK, the on-off of an N-MOS tube Q2 of the coil driving circuit is controlled until the contactor enters a holding stage; in the holding stage of the contactor, the holding current Ics1 of the coil is detected by the square wave generator, the falling edge of the square wave signal is output after comparison operation, and the falling edge and the rising edge of the square wave signal formed by the clock narrow pulse signal CLK form a holding duty ratio signal together for controlling the on-off of the N-MOS tube Q2 of the coil driving circuit.

Preferably, the comparison operation step of the square-wave generator is that in the pull-in stage of the contactor, the DELAY signal DELAY controls the second logic circuit to shield the first comparator COM1 and not shield the second comparator COM 2; the pull-in current Ics2 detected by the square wave generator is transmitted to the second comparator COM2, when the pull-in current Ics2 is equal to the second voltage reference, the second comparator COM2 outputs a high level signal, and controls the second logic circuit to output a low level signal so as to generate a falling edge of the square wave signal; in the holding phase of the contactor, the DELAY signal DELAY controls the second logic circuit to shield the second comparator COM2 and not shield the first comparator COM1, the holding current Ics1 detected by the square wave generator is transmitted to the first comparator COM1, when the holding current Ics1 is equal to the first voltage reference, the first comparator COM1 outputs a high level signal, and the second logic circuit is controlled to output a low level signal to generate the falling edge of the square wave signal.

Compared with the prior art, the beneficial effects of the utility model are that, can set up the actuation electric current and the holding current of contactor coil relatively conveniently, make control circuit's simple simultaneously, reduce components and parts, the cost is reduced and the volume.

Drawings

Fig. 1 is an overall circuit schematic diagram of a coil driving circuit of a contactor according to a first embodiment of the present invention applied to a power saving circuit;

FIG. 2 is a waveform diagram of a key node in the circuit of FIG. 1;

FIG. 3 is a logic diagram of controlling the duty ratio of a switching tube in a PFC circuit inside a square-wave generator;

fig. 4 is a logic timing diagram of key signals related to the duty cycle of a switching tube in the PFC circuit implemented by the logic block diagram shown in fig. 3;

FIG. 5 is a logic diagram of controlling the duty ratio of the switching tube in the coil driving circuit inside the square-wave generator;

FIG. 6 is a logic timing diagram of the key signals of the duty cycle of the switching tube in the coil driving circuit implemented by the logic block diagram shown in FIG. 5;

fig. 7 is a control logic block diagram of the internal power supply part of the square wave generator.

Detailed Description

First embodiment

As shown in fig. 1, the power saving circuit of an ac contactor includes a coil driving circuit, a rectifying and filtering circuit, a PFC circuit, an auxiliary power supply circuit, and a square wave generator.

The rectification filter circuit is used for rectifying input alternating current into pulsating direct current; the input narrow pulse current is filtered into smooth current, other high-order harmonic components except for 50Hz power frequency components are eliminated, and the smooth current is output to the PFC circuit and comprises an inductor L1, a rectifier bridge DB1 and a capacitor C1, wherein the inductor L1 is connected between an alternating current input end and an input end of the rectifier bridge DB1 in series, and an output end of the rectifier bridge DB1 is connected with the capacitor C1 in parallel and then led out to serve as an output end of a rectifier filter circuit.

The PFC circuit is used for receiving electric energy after rectification and filtering, enabling an effective value of input current to change along with input voltage and outputting the electric energy to the coil driving circuit and the auxiliary power supply circuit, and comprises a transformer T1, an N-MOS tube Q1, a diode D2 and a capacitor C3, wherein the transformer comprises a primary winding and a secondary winding, the specific connection relationship is that the homonymous end of the primary winding is connected with the output end of the rectification and filtering circuit, the synonym end of the primary winding is respectively connected with the drain electrode of the N-MOS tube Q1 and the anode of the diode D2, the cathode of the diode D2 is grounded through the capacitor C3, and the cathode of the diode D2 is led out to serve as the output end of the PFC circuit; the grid electrode of the N-MOS transistor Q1 is connected with the first output end of the square wave generator, and the source electrode of the N-MOS transistor Q1 is grounded; the secondary winding is connected with an auxiliary power supply circuit.

The auxiliary power supply circuit is used for providing electric energy for the square wave generator in the holding stage of the contactor, and consists of a diode D1 and a second capacitor C2, wherein the specific connection relationship is that the anode of a first diode D1 is connected with the PFC circuit, the cathode of a diode D1 is grounded through a capacitor C2, and the cathode of a diode D1 is led out to serve as the output end VDD of the auxiliary power supply circuit.

The coil driving circuit is used for controlling the current of the contactor coil and consists of a diode D3, an N-MOS tube Q2, a resistor R1, a resistor R2 and a resistor R3. The specific connection relationship is that the cathode of the diode D3 is connected with the output end of the PFC circuit, and the cathode of the diode D3 is also led out to be used as the output positive end of the coil driving circuit and is used for being connected with one end of the coil of the contactor; the anode of the diode D3 is connected with the drain of the N-MOS tube Q2, and the drain of the N-MOS tube Q2 is also led out to be used as the output negative terminal of the coil driving circuit and is used for being connected with the other end of the contactor coil; the grid electrode of the N-MOS transistor Q2 is connected with the second output end of the square wave generator, the source electrode of the N-MOS transistor Q2 is grounded through a resistor R3, and the resistor R1 and the resistor R2 are connected in series and then connected in parallel with the R3. The connection point of the resistor R1 and the resistor R2 is a first output end of the coil driving circuit, the source electrode of the N-MOS transistor Q2 is a second output end of the coil driving circuit, and the two output ends are connected to the square wave generator and used as feedback signals of the current of the coil of the contactor to respectively control pull-in current and pull-in current of the coil of the contactor. The inductance of the contactor coil is large, the contactor coil works in a continuous mode in a pull-in state and a pull-in state, and the current ripple is small.

The square wave generator U1 comprises a first pin, a second pin, a third pin, a fourth pin, a fifth pin, a sixth pin and a seventh pin. The first pin is connected with the grid electrode of an N-MOS tube Q1 to control the work of the PFC circuit. The second pin is connected with the output end of the auxiliary power supply circuit and used for providing electric energy required by the holding state for the square wave generator. The third pin is grounded. The fourth pin is connected with the second output end of the coil driving circuit and used for detecting the current of the contactor coil in the pull-in stage. And the fifth pin is connected with the first output end of the coil driving circuit and used for detecting the current of the coil of the contactor in the holding stage. The sixth pin is connected with the grid electrode of the N-MOS tube Q2, and the current of the coil of the contactor is controlled by controlling the on-off of the N-MOS tube Q2. The seventh pin is connected with the drain electrode of the N-MOS transistor Q1 and used for providing the square wave generator with electric energy required by the first start-up.

The square wave generator sends a square wave signal to control the PFC circuit, and in the pull-in stage, the delay signal shields the signal of the signal generation module through the first logic circuit, so that the PFC circuit does not work; in the holding stage, the delay signal does not shield the signal of the signal generating module through the first logic circuit, so that the PFC circuit works normally.

The current of the coil of the contactor is controlled by adopting peak current, and in the pull-in process, the pull-in current of the coil of the contactor is controlled by comparing a second voltage reference REF2 with a voltage signal at the second output end of the coil driving circuit; during the holding process, the holding current of the coil of the contactor is controlled by comparing a first voltage reference REF1 with a voltage signal at a first output terminal of the coil driving circuit; by setting the voltage division ratio k of the resistor R1 to the resistor R2, the pull-in current can be k times REF2/REF1 times the holding current.

FIG. 2 is a waveform of the critical node voltage of FIG. 1. Before time t1, in the pull-in stage of the contactor, the square wave generator does not output a GATE1 signal, and the PFC circuit does not work; the square wave generator outputs a square wave signal GATE2 with a larger duty cycle, and a larger current flows through the contactor coil. In the holding stage of the contactor after the time t, the square wave generator outputs a GATE1 signal, and the PFC circuit works normally; the square wave generator outputs a square wave signal GATE2 with a smaller duty cycle and a smaller current flows through the contactor coil.

More specifically, the square wave generator has a first voltage reference REF1, a second voltage reference REF2, a DELAY signal DELAY, a first comparator, a second comparator, a first control logic circuit, a second control logic circuit, a start power supply circuit, a clock generation circuit, and a signal generation module.

As shown in fig. 3, the control block diagram of the PFC circuit portion is that the DELAY signal DELAY and the signal generation module are respectively connected to an input of a first logic circuit, and an output of the first logic circuit is connected to a first pin of a square wave generator. The signal generation module sends out a square wave signal SIGN1 for controlling the on-off of the N-MOS transistor Q1. As shown in fig. 4, before time t1, in a pull-in stage, the delay signal controls the first logic circuit to shield the signal SIGN1, so that the GATE1 signal is not output from the first pin of the square wave generator; after time t1, in the hold phase, the delay signal controls the first logic circuit not to mask signal SIGN1, so that the GATE1 signal is output from the first pin of the square-wave generator to control the PFC circuit to operate.

A control block diagram of the coil drive circuit portion is shown in fig. 5. The fourth pin of the square wave generator and the second voltage reference REF2 are connected to the inputs of the second comparator, respectively. The fifth pin of the square wave generator and the first voltage reference REF1 are connected to the inputs of the first comparator, respectively. The output of the clock generation circuit, the output of the first comparator, the output of the second comparator, and the DELAY signal DELAY are coupled to the input of the second logic circuit, respectively. And the output of the second logic circuit is connected with a seventh pin of the square wave generator.

The logic of the signals is shown in fig. 7. Before time t1 is a pull-in phase, and after t1 is a hold phase. the time period from t1 to t2 is the transition period of the coil current from the pull-in current to the pull-in current, and the patent does not describe the transition period. In the pull-in stage, the DELAY signal DELAY controls the second logic circuit to shield the COM1 signal output by the first comparator and not shield the COM2 signal output by the second comparator. The clock generating circuit outputs a narrow pulse periodic signal CLK, the CLK signal controls the second logic circuit to output a high level, at the moment, the N-MOS tube Q2 is conducted, the contactor coil is excited, and the CS2 signal voltage rises. When the voltage of the CS2 signal is equal to the second voltage reference REF2, the COM2 signal becomes high, the second logic circuit is controlled to output low, the N-MOS transistor Q2 is turned off, the CS2 signal voltage is lower than the second voltage reference REF2, and the COM2 signal becomes low. The values of the resistor R1 and the resistor R2 are far larger than that of the resistor R3, and the current peak value of the contactor coil in the pull-in state is

\frac{R E F 2}{R 3} * \frac{R 1 + R 2}{R 2} .

In the hold state, the DELAY signal DELAY controls the second logic circuit to not mask the COM1 signal output by the first comparator and to mask the COM2 signal output by the second comparator. The clock generating circuit outputs a narrow pulse periodic signal CLK, the CLK signal controls the second logic circuit to output a high level, at the moment, the N-MOS tube Q2 is conducted, the contactor coil is excited, and the CS1 signal voltage rises. When the voltage of the CS1 signal is equal to the first voltage reference REF1, the COM1 signal becomes high, the second logic circuit is controlled to output low, the N-MOS transistor Q2 is turned off, the CS1 signal voltage is lower than the first voltage reference REF1, and the COM1 signal becomes low. The current peak value of the coil of the contactor in a holding state is

The control block diagram of the power supply part of the square wave generator is shown in fig. 7. The input of the starting power supply circuit is connected with the seventh pin of the square wave generator, and the output of the starting power supply circuit is connected with the second pin of the square wave generator. In the pull-in state, the PFC circuit does not work, the auxiliary group power supply circuit cannot provide energy, and the starting circuit converts the high voltage of the seventh pin into the low voltage VCC to supply power to the circuit in the square wave generator. In the holding state, the auxiliary power supply circuit can normally work to supply power to the square wave generator, and the DELAY signal DELAY controls the starting power supply circuit to stop working.

The above is only a preferred embodiment of the present invention, and it should be noted that the above preferred embodiment should not be considered as limiting the present invention, and the protection scope of the present invention should be subject to the scope defined by the claims.

Claims

1. A coil driving circuit of a contactor is suitable for a square wave generator to control and adjust the driving current of a coil, and is characterized in that:

the coil driving circuit consists of a diode D3, an N-MOS transistor Q2, a resistor R1, a resistor R2 and a resistor R3, wherein the cathode of a diode D3 is connected with the input end of the contactor coil, and the cathode of a diode D3 is led out to serve as a first input end of the coil driving circuit; the anode of the diode D3 is respectively connected with the drain of the N-MOS tube Q2 and the output end of the contactor coil, the source of the N-MOS tube Q2 is respectively connected with one end of the resistor R3 and one end of the resistor R1, and the other end of the resistor R3 is grounded; the other end of the resistor R1 is grounded through a resistor R2; the grid electrode of the N-MOS tube Q2 is led out to be used as a second input end and is used for being connected with the square wave signal output end of the square wave generator; one end of the resistor R3 is led out to be used as a holding current detection end; the other end of the resistor R1 is led out to be used as a pull-in current detection end; wherein,

the rising edge of the square wave signal is formed by the clock narrow pulse signal CLK, which is used to control the conduction of the N-MOS transistor Q2 of the coil driving circuit,

in the pull-in stage of the contactor, the pull-in current Ics2 of the coil is detected from the pull-in current detection end by a square wave generator, the falling edge of a square wave signal is output after comparison operation is carried out, and the falling edge and the rising edge of the square wave signal formed by a clock narrow pulse signal CLK form a pull-in duty ratio signal together, so that the pull-in duty ratio signal is used for controlling the on-off of an N-MOS tube Q2 of a coil driving circuit until the contactor enters the pull-in stage;

In the holding stage of the contactor, the square wave generator is used for detecting the holding current Ics1 of the coil from the holding current detection end, the falling edge of the square wave signal is output after comparison operation is carried out, and the falling edge and the rising edge of the square wave signal formed by the clock narrow pulse signal CLK form a holding duty ratio signal together for controlling the on-off of the N-MOS tube Q2 of the coil driving circuit.

2. A coil driving circuit of a contactor according to claim 1, wherein: the pull-in current Ics2 of the coil drive circuit is 10 to 20 times the pull-in current Ics 1.

3. A coil driving circuit of a contactor according to claim 1 or claim 2, wherein: the current peak value of the pull-in current Ics2 of the coil driving circuit isThe current peak of the holding current Ics1 is。

4. A coil driving circuit of a contactor according to claim 1, wherein: the square wave generator comprises a signal generating module and a first logic circuit, wherein the first input end of the first logic circuit is connected with a DELAY signal DELAY, the second input end of the first logic circuit is connected with the output of the signal generating module, and the output of the first logic circuit is used as the first square wave output end GATE1 of the square wave generator; wherein,

The signal generation module is used for generating a duty ratio signal SIGN1 for controlling the N-MOS transistor Q1 so as to control the on-off of the N-MOS transistor Q1;

the DELAY signal DELAY is used for controlling the first logic circuit to shield the signal SIGN1 in the pull-in stage, so that the first square wave output end of the square wave generator does not output a signal to enable the PFC circuit to be out of operation; in the holding stage, the first logic circuit is controlled not to shield the signal SIGN1, so that the first square wave output end of the square wave generator outputs a signal for controlling the operation of the PFC circuit.

5. A coil driving circuit of a contactor according to claim 1, wherein: the square wave generator comprises a clock generation module, a first comparator, a second comparator, a delay signal generation module and a second logic circuit, wherein the specific connection relationship is that a first input end of the first comparator is connected with a holding current detection end of the coil driving circuit, and a second input end of the first comparator is connected with a first voltage reference; a first input end of the second comparator is connected with a pull-in current detection end of the coil driving circuit, and a second input end of the second comparator is connected with a second voltage reference; the output of the clock generation module, the output of the first comparator, the output of the second comparator and the output of the delay signal generation module are respectively connected with the input of a second logic circuit, and the output of the second logic circuit is used as a second square wave output end of the square wave generator.