CN105704898A - Complete intelligent electricity-saving device - Google Patents

Abstract

The present invention discloses a complete intelligent electricity-saving device. The device comprises a first relay, a second relay, a first inductor and a second inductor connected in series, an MCU module, and a power module, an acquisition module, an electric power carrier module and a driving module which are connected with the MCU module. The first inductor is an overvoltage winding, and the second inductor is a power reduction winding; the power module supplies work voltage to the MCU module; and the power carrier module receives power carrier signals sent by a centralized controller, performs demodulation processing of the power carrier signals, sends the processed power carrier signals to the MCU module, receives feedback instructions fed back through the MCU module, converts the feedback instructions to power carrier signals, and sends the power carrier signals to the centralized controller through coupling the power carrier signals on an alternate current power line, wherein the feedback instructions are work state information of a current discharge lamp. The electricity-saving device is simple to operate and convenient for usage.

Description

Full-intelligent electricity saver

Technical Field

The invention relates to a full-intelligent electricity saver.

Background

With the continuous improvement of living standard, people have higher and higher requirements on urban lighting environment, so that not only safety lighting is required, but also lighting for improving urban image is added. The relevant departments stipulate: during normal lighting periods, the standard specified illuminance should be achieved, and during periods when normal lighting is not required (e.g., the next midnight), only the safe illuminance may be retained, with the illuminance value generally held at half of the standard. The image illumination of the city is several times of the standard illumination at present, far exceeds the national standard, and wastes a large amount of energy under the condition of only needing to keep the safe illumination. Therefore, in the time period without the need of urban image illumination, the illumination is reduced to the safe illumination so as to achieve the purpose of energy saving.

Disclosure of Invention

The invention aims to provide a fully intelligent electricity saver which can solve the defects in the prior art.

The invention adopts the following technical scheme:

a fully intelligent power saver comprising: the system comprises a first relay, a second relay, a first inductor, a second inductor, an MCU module, a power module, an acquisition unit, a power carrier module and a driving unit, wherein the first inductor and the second inductor are connected in series;

wherein,

the first inductor is an overvoltage winding, and the second inductor is a power reduction winding;

the power supply module provides working voltage for the MCU module;

the power carrier module receives a power carrier signal, demodulates the power carrier signal and sends the demodulated power carrier signal to the MCU module; receiving a feedback instruction fed back by the MCU module, converting the feedback instruction into a power carrier signal, and transmitting the power carrier signal to the MCU module; the feedback instruction is the current working state information of the discharge lamp;

the MCU module generates a corresponding MCU instruction according to a power carrier signal sent by the power carrier module or a received voltage signal which is acquired by the acquisition unit and subjected to isolation protection;

the driving unit receives the MCU instruction and drives the first relay or the second relay to act; the driving unit comprises a pulse square wave generator and at least one driving module;

the output end of the pulse square wave generator is connected with the first input end of the driving module, the pulse square wave generator inputs a high-frequency square wave pulse signal to the first input end of the driving module, the driving module is also provided with a second input end for inputting a low-frequency driving signal, the driving module comprises a signal conversion circuit unit and a driving circuit unit, and the signal conversion circuit unit is connected with the driving circuit unit through a pulse transformer;

when the second input end of the driving module is at a high level, the signal conversion circuit unit converts the input low-frequency driving signal and the input high-frequency square wave pulse signal into an alternating-current high-frequency pulse signal, and the pulse transformer outputs a driving voltage signal through the driving circuit unit after isolating and transforming the alternating-current high-frequency pulse signal; the number of the driving modules is at least two, the first input end of each driving module is respectively connected with the output end of the pulse square wave generator, and the second input end of each driving module is respectively used for inputting corresponding low-frequency driving signals;

the power module comprises a voltage conversion unit, an overvoltage protection unit and a power supply, wherein the input end of the voltage conversion unit is connected with the power supply to receive a first voltage provided by the power supply, and the output end of the voltage conversion unit is connected with the electronic element;

the power module comprises a voltage conversion unit, an overvoltage protection unit and a power supply, wherein the input end of the voltage conversion unit is connected with the power supply to receive a first voltage provided by the power supply, and the output end of the voltage conversion unit is connected with the electronic element; the acquisition unit includes: the data acquisition module is used for acquiring and/or outputting data of the system to be measured; the slave logic control module is connected with the data acquisition module and is used for carrying out logic control on the data acquisition module; the slave logic control module and the master logic control module are used for controlling the master logic control module; an electrical isolation module for electrical isolation is connected between the slave logic control module and the master logic control module; the main logic control module is also connected with a bus bridge module, and the bus bridge module is used for realizing the communication of the main logic control module; the electrical isolation module includes: the power isolation module is respectively connected with the slave logic control module and the master logic control module and is used for power isolation; the signal isolation module is respectively connected with the slave logic control module and the master logic control module and is used for signal isolation; the slave logic control module comprises: the slave data packaging module is respectively connected with the data acquisition module and the electrical isolation module and is used for packaging the first data acquired by the data acquisition module and transmitting the first data to the master logic control module through the electrical isolation module; the main logic control module comprises: the main data decapsulation module is respectively connected with the electrical isolation module and the bus bridge module and is used for decapsulating the first data received by the electrical isolation module; and/or the slave logic control module further comprises: and the slave data decapsulation module is connected with the electrical isolation module and used for decapsulating the second data received by the electrical isolation module and outputting the decapsulated second data to the system side to be measured.

The connecting point of the first relay and the second relay is connected with one end of the first inductor and one end of the second inductor which are connected in series; the other end of the first inductor is connected with a first static contact of the first relay, and the other end of the second inductor is connected with a second static contact of the second relay; the movable contact of the first relay is connected with the acquisition unit, and the movable contact of the second relay is connected with the standard inductor.

The voltage conversion unit includes: the device comprises a power supply circuit, an energy storage booster circuit, a positive voltage generating circuit, a negative voltage generating circuit and a reference voltage generating circuit; the energy storage booster circuit comprises a booster chip and an inductor;

the output end of the power supply circuit is respectively connected with the input end of the boosting chip and the first end of the inductor;

the second end of the inductor is respectively connected with the control end of the boosting chip, the input end of the positive voltage generating circuit, the input end of the negative voltage generating circuit and the input end of the reference voltage generating circuit;

the power supply circuit is used for providing a unipolar input voltage;

the boosting chip is used for controlling the voltage at two ends of the inductor and respectively providing the voltage at two ends of the inductor to the positive voltage generating circuit, the negative voltage generating circuit and the reference voltage generating circuit;

the positive voltage generating circuit is used for generating a positive voltage according to the voltage at two ends of the inductor;

the negative voltage generating circuit is used for generating a negative voltage according to the voltage at two ends of the inductor;

the reference voltage generating circuit is used for generating reference voltage according to the voltage at two ends of the inductor.

The positive voltage generating circuit is a first charge pump circuit, wherein the first charge pump circuit is used for generating a positive voltage according to the voltage at two ends of the inductor, the first charge pump circuit comprises an N-level charge pump circuit, and N is a positive integer greater than or equal to 1.

The Nth-stage charge pump circuit of the first charge pump circuit comprises a first capacitor, a first diode and a second diode; wherein,

the cathode of the first capacitor is connected with the second end of the inductor, and the anode of the first capacitor is respectively connected with the anode of the first diode and the cathode of the second diode; the anode of the second diode is connected with the cathode of the first diode in the N-1 st level charge pump circuit of the first charge pump circuit;

and the negative electrode of the first diode outputs the positive voltage according to the voltage at the two ends of the inductor and the voltage of the positive electrode of the first capacitor.

The overvoltage protection unit comprises first to fifth electronic switches, first to sixth resistors and an eighth diode, a first end of the first electronic switch is connected with an output end of the voltage conversion unit through the first resistor and grounded through the first two resistors, a second end of the first electronic switch is connected with the power supply through the third resistor to receive a second voltage provided by the power supply, a first end of the first two electronic switch is connected with a second end of the first electronic switch, a second end of the first two electronic switch is connected with the power supply through the fourth resistor to receive the second voltage, a first end of the first three electronic switch is connected with the power supply through the fifth resistor to receive the second voltage, and a second end of the first three electronic switch is connected with a cathode of the eighth diode, the third end of the first three electronic switch is connected with the power supply to receive the second voltage, the anode of the eighth diode is connected with the second end of the first two electronic switch, the first end of the first four electronic switch is connected with the cathode of the eighth diode, the second end of the first four electronic switch is connected with the first end of the first three electronic switch, the first end of the first five electronic switch is connected with the second end of the first four electronic switch, the second end of the first five electronic switch is connected with the power supply through the first six resistors to receive the second voltage and is connected with a power supply signal pin of the power supply, and the third ends of the first start-up, the first two electronic switch, the first four electronic switch and the first five electronic switch are all grounded.

When the voltage output by the output end of the voltage conversion unit is equal to the working voltage of the electronic element, the first electronic switch is turned off, the first two electronic switches are turned on, the eighth diode is turned off, the first four electronic switches are turned off, the first three electronic switches are turned off, the first five electronic switches are turned on, the second end of the first five electronic switches outputs a low-level signal to the power supply starting signal pin, and the power supply works normally; when the voltage output by the output end of the voltage conversion unit is greater than the working voltage of the electronic element, the first electronic switch is turned on, the first two electronic switch is turned off, the eighth diode is turned on, the first four electronic switch is turned on, the first three electronic switch is turned on, the first five electronic switch is turned off, the second end of the first five electronic switch outputs a high-level signal to the power supply starting signal pin, and the power supply stops voltage output.

The negative voltage generating circuit is a second charge pump circuit, wherein the second charge pump circuit is used for outputting the negative voltage according to the voltage at two ends of the inductor, the second charge pump circuit comprises M stages of charge pump circuits, and M is a positive integer greater than or equal to 1.

Each stage of the second charge pump circuit includes a second capacitor, a third diode, and a fourth diode.

The anode of the second capacitor is connected with the second end of the inductor, and the cathode of the second capacitor is respectively connected with the anode of the third diode and the cathode of the fourth diode; the cathode of the third diode is connected with the anode of a third diode in the M-1 stage charge pump circuit of the second charge pump circuit;

and the anode of the fourth diode outputs the negative voltage according to the cathode voltage of the second capacitor.

The invention has the advantages that: the operation is simple and the use is convenient.

Drawings

The invention is described in detail below with reference to examples and figures, in which:

fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a block diagram of the power supply circuit.

Fig. 3 is a circuit diagram of fig. 2.

Fig. 4 is a schematic structural diagram of the voltage conversion unit.

Fig. 5 is a circuit diagram of the driving unit of the present invention.

Fig. 6 is a circuit diagram of the driving module of fig. 5.

Fig. 7 is a circuit diagram of an acquisition unit of the present invention.

Detailed Description

The embodiments of the invention are further illustrated in the following figures:

as shown in fig. 1, a fully intelligent power saver disclosed for an embodiment of the present invention mainly includes: the device comprises a first relay KA1, a first inductor L2, a first relay coil 101, a second relay KA2, a second inductor L3, a second relay coil 102, an MCU module 103, a power module 104, a power carrier module 105, an acquisition unit 106 and a driving unit 107.

The power module 104, the power carrier module 105, the collecting unit 106 and the driving unit 107 are respectively connected with the MCU module 103, and the power module 104 receives the voltage of AC220V ± 20% in the power grid (L in fig. 1 represents the live wire and N represents the zero wire), and converts the received voltage into the operating voltage of the MCU module 103, so that the MCU module 103 operates normally. The power carrier module 105 communicates with a centralized controller (not shown) at the discharge lamp control box for sending and receiving power carrier signals. When the centralized controller sends a power carrier signal to the fully intelligent power saver of the present invention, the power carrier module 105 receives the power carrier signal sent by the centralized controller, demodulates the power carrier signal and sends the demodulated power carrier signal to the MCU module 103, and then the MCU module 103 generates a corresponding MCU command to drive an output signal. When the MCU module 103 needs to feed back corresponding information to the centralized controller, that is, the current operating state information of the discharge lamp, the MCU module 103 sends a relevant instruction to the power carrier module 105, and the power carrier module 105 converts the received instruction into a power carrier signal and sends the power carrier signal to the centralized controller by coupling the power carrier signal to the ac power line. The power carrier module 105 communicates with the centralized controller, so that the discharge lamp 108 can be remotely controlled, that is, the intelligent control of the lighting of the discharge lamp 108 can be completed.

The sampling module 106 is mainly used for collecting voltage signals in a line, and transmitting the collected voltage signals to the MCU module 103 after isolation protection. The MCU module 103 is mainly configured to receive the voltage signal processed by the sampling module 106 and the power carrier signal sent by the power carrier module 105, generate a corresponding MCU command according to the received signal, and feed back the current operating state information of the discharge lamp 108 to the centralized controller through the power carrier module 105.

The driving unit 107 is mainly used for receiving an MCU instruction sent by the MCU module 103, and then powering on or powering off the first relay coil 101 or the second relay coil 102 according to the MCU instruction, so as to drive the first relay KA1 or the second relay KA2 to operate. As shown in fig. 1, the first relay coil 101 and the second relay coil 102 are connected to a driving unit 107, respectively.

The first relay KA1 and the second relay KA2 are provided with three contacts, namely a movable contact, a first fixed contact and a second fixed contact. In the embodiment disclosed in the invention, the second stationary contact of the first relay KA1 is connected with the first stationary contact of the second relay KA2, the first inductor L2 is connected in series with the second inductor L3, and the connection point of the first relay KA1 and the second relay KA2 is connected with one end of the first inductor L2 connected in series with the second inductor L3, as shown in fig. 1.

In addition, the other end of the first inductor L2 is connected with the first stationary contact of the first relay KA1, and the other end of the second inductor L3 is connected with the second stationary contact of the second relay KA 2; the movable contact of the first relay KA1 is connected to the pickup unit 106, and the movable contact of the second relay KA2 is connected to the standard inductor L1 in the discharge lamp circuit.

It should be noted that the first inductor L2 is an overvoltage winding, and when the line voltage is too high, the MCU module 103 sends a corresponding MCU command to make the driving unit 107 drive the first relay KA1 to operate, so as to connect the first inductor L2 to the line.

The second inductor L3 is a power reduction winding, and when the power of the discharge lamp needs to be reduced, the MCU module 103 controls the operation of the second relay KA2 to connect the second inductor L3 to the line.

As shown in fig. 2 and 3, the power module 10 includes a voltage converting unit 12, an overvoltage protection unit 16, and a power supply 18. The voltage conversion unit 12 is connected to the overvoltage protection unit 16. The power supply 18 is connected to both the voltage converting unit 12 and the over-voltage protection unit 16. The voltage converting unit 12 is configured to convert the first voltage provided by the power supply 18 into an operating voltage, and output the converted voltage from an output terminal of the voltage converting unit 12. The overvoltage protection unit 16 is configured to control the power supply 18 to stop outputting the voltage when the voltage output by the output terminal of the voltage conversion unit 12 is greater than the working voltage, so as to protect the voltage.

The overvoltage protection unit 16 includes three first electronic switches Q13-Q15 as electronic switches, two first four electronic switches Q16 and a first five electronic switch Q17 as electronic switches, an eighth diode D, and six resistors R11-R16. The base of the first one-by-one electronic switch Q13 is connected to the output terminal of the voltage converting unit 12 through the first one-by-one resistor R11, and is grounded through the first two-by-one resistor R12. The collector of the first one-to-one electronic switch Q13 is connected to the power supply 18 through the resistor R13 to receive a second voltage (e.g., a 5V _ Standby voltage) provided by the power supply 18. The emitter of the first electronic switch Q13 is grounded. The base of the first two-electronic switch Q14 is connected to the collector of the first one-electronic switch Q13. The collector of the first two-electronic switch Q14 is connected to the power supply 18 through the first four-resistor R14 to receive the second voltage. The emitter of the first two-electron switch Q14 is grounded. The base of the first third electronic switch Q15 is connected to the power supply 18 through the first fifth resistor R5 to receive the second voltage. The collector of the first third electronic switch Q15 is connected to the cathode of the eighth diode D. The emitter of the first third electronic switch Q15 is connected to the power supply 18 to receive the second voltage. The anode of the eighth diode D is connected to the collector of the first two-electronic switch Q14. The gate of the first fourth electronic switch Q16 is connected to the collector of the first third electronic switch Q15. The drain of the first fourth electronic switch Q16 is connected to the base of the first third electronic switch Q15. The source of the first four electronic switch Q16 is connected to ground. The gate of the first fifth electronic switch Q17 is connected to the drain of the first fourth electronic switch Q16. The first five electronic switch is a MOS transistor, and a drain thereof is connected to the power supply 18 through the resistor first six R16 to receive the second voltage, and is connected to a PS _ ON (power ON-ON) signal pin of the power supply 18. The source of the MOS transistor Q17 is grounded.

In this embodiment, the electronic switches Q11, Q12, Q16 and Q17 are all NMOS transistors, the electronic switches Q13 and Q14 are all NPN transistors, and the first electronic switch Q15 is a PNP transistor. The resistance value of the resistor R11 is R1, the resistance value of the resistor R12 is R2, the voltage output by the output end of the voltage conversion unit 12 is Vout, and the voltage V1 received by the base of the first one-to-one electronic switch Q13 satisfies a formula one: v1 ═ Vout × r2/(r1+ r 2). In other embodiments, the MOS transistors Q11, Q12, Q16 and Q17 can be replaced by NPN transistors and other switches with the same function, and the first electronic switch Q13 and the first two electronic switches Q14 can be replaced by NMOS transistors and other switches with the same function. The first electronic switch Q15 can be replaced by a PMOS transistor and other switches with the same function. When the voltage output by the output end of the voltage conversion unit is greater than the working voltage of the electronic element, the power supply circuit controls the power supply to stop outputting the voltage through the overvoltage protection unit, so that the situation that the electronic element is damaged due to overhigh input voltage is effectively avoided.

As shown in fig. 4, the negative voltage generating circuit 4 is a 1-stage charge pump circuit capable of generating a negative voltage, wherein the capacitor C2 and the diodes D2 and D3 form a charge pump circuit, the second capacitor C2 is a positive electrode, the left end of the second capacitor C2 is a negative electrode, the right end of the second capacitor C2 is a negative electrode, the third diode D2 is a negative electrode, and the fourth diode D3 is a positive electrode. The anode of the second capacitor C2 is connected to the right end of the inductor L1, the cathode of the second capacitor C2 is connected to the anode of the third diode D2 and the cathode of the fourth diode D3, respectively, the anode of the fourth diode D3 outputs a negative voltage, and the cathode of the third diode D2 is grounded. The specific operating principle of the negative voltage generating circuit 4 is as follows: the capacitor C2 is charged through the output voltage of the inductor L1, the polarity of the capacitor C2 is positive left and negative right, and then a charging path of the inductor L1 to the capacitor C2 is disconnected; because the voltage across the capacitor C2 cannot change abruptly, the right negative voltage is output through the diode D3 to obtain the negative voltage VGL. If M is greater than or equal to 2, the cathode of the third diode D2 is connected with the anode of the third diode in the M-1 st stage charge pump circuit, so that the multi-stage charge pump circuit is formed. The negative voltage generating circuit 4 may further include a capacitor C3 and a zener diode D8 at the output end of the M-stage charge pump circuit, the capacitor C3 is used for filtering the output negative voltage, and the zener diode D8 realizes voltage stabilization output. The reference voltage generating circuit comprises at least one voltage stabilizing diode, the anode of the voltage stabilizing diode is connected with the second end of the inductor, and the cathode of the voltage stabilizing diode outputs reference voltage according to the anode voltage of the voltage stabilizing diode.

The reference voltage generating circuit 5 includes a zener diode D1, an anode of the zener diode D1 is connected to the right end of the inductor L1, and a cathode thereof outputs a negative voltage VGL. The reference voltage generating circuit 5 may further include a capacitor C1, and the capacitor C1 is used for filtering the output negative voltage.

The voltage conversion circuit provided by the embodiment adopts the multi-stage charge pump circuit to respectively realize the output of positive voltage and negative voltage, changes the magnitude of the output positive voltage and negative voltage by changing the stage number of the charge pump circuit, and has the advantages of simple circuit structure, flexibility and adjustability. The driving circuit realizes signal isolation by using the pulse transformer through the design of the whole circuit, so that compared with the traditional driving circuit which adopts a photoelectric coupling signal isolation mode, the driving circuit of the invention does not need an additional independent power supply, thereby saving the power supply and having better working stability.

As shown in fig. 5 and 6, the driving unit of the present invention comprises a driving circuit including a pulse square wave generator MD1 and a driving module MD 2; the output terminal OUT of the pulse square wave generator MD1 is connected to the first input terminal IN1 of the driving module MD2, the driving module MD2 further has a second input terminal IN2 for inputting the low-frequency driving signal DRIVEA, the driving module includes a signal conversion circuit unit 100 and a driving circuit unit 200, and the signal conversion circuit unit 100 and the driving circuit unit 200 are connected through a pulse transformer T1.

The signal conversion circuit unit 100 includes a nand gate unit 111 and a full-bridge inverter circuit unit 112, two output ends of the nand gate unit 101 are respectively connected to two input ends of the full-bridge inverter circuit unit 112, the pulse transformer T1 has a primary winding and a secondary winding, two output ends of the full-bridge inverter circuit unit 112 are respectively connected to two input ends of the primary winding, and two output ends of the secondary winding are respectively connected to two input ends of the driving circuit unit 200; the driving circuit unit 200 includes a full-bridge rectifier circuit 201 and an output circuit 202, the full-bridge rectifier circuit 201 is connected to two output terminals of the secondary winding of the pulse transformer T1, the full-bridge rectifier circuit 201 has a positive output terminal and a negative output terminal, and the output circuit 202 is connected to the positive output terminal and the negative output terminal.

IN the nand gate unit 111, a first input end of the nand gate device UA is a first input end IN1 of the driving module MD2, a second input end of the nand gate device UA is connected to a first input end of the nand gate device UB, the first input end of the nand gate device UB is a second input end IN2 of the driving module MD2, and the second input end of the nand gate device UB is connected to an output end of the nand gate device UA. In the above-mentioned full-bridge inverter circuit unit 112, one end of the gate resistor R101 and one end of the gate resistor R103 are respectively connected to the output end of the nand gate device UB, the other end of the gate resistor R101 is connected to the gate of the P-channel fet V1, the source of the P-channel fet V1 is connected to one end of the current-limiting resistor R105, the other end of the current-limiting resistor R105 is connected to the power source VCC, the power source VCC is further connected to the current-limiting resistor R106, the other end of the current-limiting resistor R106 is connected to the source of the P-channel fet V2, the gate of the P-channel fet V2 is connected to the gate resistor R102, the other end of the gate resistor R102 is connected to the output end of the nand gate device UA, the output end of the nand gate device UA is further connected to the gate resistor R104, the other end of the gate resistor R104 is connected to the gate of the N-channel fet V4, the source of the N, the source electrode of the N-channel field effect transistor V3 is also connected with a power ground, the drain electrode of the P-channel field effect transistor V2 and the drain electrode of the N-channel field effect transistor V4 are respectively connected with one end of the primary winding of the pulse transformer T1, and the drain electrode of the P-channel field effect transistor V1 and the drain electrode of the N-channel field effect transistor V3 are respectively connected with the other end of the primary winding of the pulse transformer T1.

The full-bridge rectifier circuit 201 includes four diodes D101, D102, D10103, D104, one end of the secondary winding of the pulse transformer T1 is connected to the anode of the diode D101 and the cathode of the diode D103, the cathode of the diode D101 is connected to the cathode of the diode D102, the anode of the diode D102 and the cathode of the diode D104 are connected to the other end of the secondary winding of the pulse transformer T1, the anode of the diode D104 is connected to the anode of the diode D103, in the full-bridge rectifier circuit 201, the anode of the diode D101 or the diode D102 is the positive output terminal, and the cathode of the diode D103 or the diode D104 is the negative output terminal.

The output circuit 202 includes a diode D105, a P-channel fet V5, a resistor R107, and a resistor R108, wherein the _ anode of the diode D105 is connected to the positive output terminal, the gate of the P-channel fet V5, and the resistor R107, the other end of the resistor R107 is connected to the negative output terminal and the drain of the P-channel fet V5, the cathode of the diode D105 is connected to the source of the P-channel fet V5 and the resistor R108, and a driving voltage signal output terminal is formed between the other end G of the resistor R108 and the negative output terminal E. The field effect transistors V1, V2, V3, V4, and V5 may be MOSFETs.

The driving circuit mainly adopts the working principle that a driving module is as follows: a first input IN1 of the driving module MD2 is connected to the output OUT of the pulsed square wave generator MD1, and a second input IN2 of the driving module MD2 is connected to an external low-frequency driving signal, typically a pulsed square wave generator MD1 outputting a pulsed square wave with a frequency IN the range of tens of khz to tens of khz, and an external low-frequency driving signal DRIVEA connected to the input IN2 with a frequency IN the range of a few tenths of hz to hundreds of hz; under the condition that the second input terminal IN2 of the driving module MD2 is high: when the first input terminal IN1 of the driving module MD2 is at a high level, the output pin of the nand gate device UA is at a low level, and the output pin of the nand gate device UB is at a high level; when the first input terminal IN1 of the driving module MD2 is at a low level, the output pin of the nand gate device UA is at a high level, and the output pin of the nand gate device UB is at a low level. Therefore, when the input terminal IN2 is at high level, the output pins of the nand gate devices UA and UB output two complementary dc high frequency pulse signals with the same frequency and pulse width as the first input terminal IN1, the two complementary dc high frequency pulse signals drive the full bridge inverter circuit composed of P-channel fets V1, V2 and N-channel fets V3, V4 through the gate resistors R101, R102, R103 and R104, and then the dc high frequency pulse signals are inverted into ac high frequency pulse signals, the ac high frequency pulse signals are isolated and transformed by the pulse transformer T1, the ac high frequency pulse signals output by the pulse transformer T1 are rectified by the full bridge rectifier circuit 201 composed of diodes D101, D102, D103 and D104, the positive output terminal of the gate is positive voltage, the P-channel fet V5 is IN cut-off state due to the same source voltage, so that there is driving voltage at the output terminals G and E of the driving voltage signals, finally, the driven power tube is conducted; under the condition that the second input terminal IN2 of the driving module MD2 is low: the output pins of the nand gate devices UA and UB both output high levels, so that the field effect transistors V3 and V4 on the inverter bridge are turned on, and thus both ends of the primary winding of the pulse transformer T1 are connected to the power ground without voltage, and at this time, the output terminal of the pulse transformer T1 has no voltage, so that a voltage difference is generated between the gate and the source of the P-channel field effect transistor V5 to turn on the P-channel field effect transistor V, and the driving voltage signal output terminals G and E are turned on through R108, that is, a voltage is lost between G and E, and finally, the driven power transistor is in a blocking state. IN summary, the driving voltage signal outputted between the driving voltage signal output terminals G and E follows the low frequency driving signal at the second input terminal IN2 of the driving module MD2, when the second input terminal IN2 is at high level, there is driving signal at G and E of the driving module, otherwise there is no driving signal, so as to achieve the purpose of driving circuit. The voltage conversion circuit provided by the embodiment adopts the multi-stage charge pump circuit to respectively realize the output of positive voltage and negative voltage, changes the magnitude of the output positive voltage and negative voltage by changing the stage number of the charge pump circuit, and has the advantages of simple circuit structure, flexibility and adjustability. The driving circuit realizes signal isolation by using the pulse transformer through the design of the whole circuit, so that compared with the traditional driving circuit which adopts a photoelectric coupling signal isolation mode, the driving circuit of the invention does not need an additional independent power supply, thereby saving the power supply and having better working stability.

As shown in fig. 7, the acquisition unit of the present invention includes: a data acquisition module 211, a slave logic control module 212, a master logic control module 213, an electrical isolation module 214, and a bus bridge module 215. The data acquisition module is used for acquiring and/or outputting data of the system to be measured; the slave logic control module is connected with the data acquisition module and is used for carrying out logic control on the data acquisition module; the slave logic control module and the master logic control module are used for controlling the master logic control module; an electrical isolation module for electrical isolation is connected between the slave logic control module and the master logic control module; the main logic control module is also connected with a bus bridge module, and the bus bridge module is used for realizing the communication of the main logic control module; the electrical isolation module includes: the power isolation module is respectively connected with the slave logic control module and the master logic control module and is used for power isolation; the signal isolation module is respectively connected with the slave logic control module and the master logic control module and is used for signal isolation; the slave logic control module comprises: the slave data packaging module is respectively connected with the data acquisition module and the electrical isolation module and is used for packaging the first data acquired by the data acquisition module and transmitting the first data to the master logic control module through the electrical isolation module; the main logic control module comprises: the main data decapsulation module is respectively connected with the electrical isolation module and the bus bridge module, and is used for decapsulating the first data received by the electrical isolation module and sending the decapsulated first data through the bus bridge module; and/or the slave logic control module further comprises: the slave data decapsulation module is connected with the electrical isolation module and used for decapsulating the second data received by the electrical isolation module and outputting the decapsulated second data to a system side to be measured; the main logic control module further comprises: the master data packaging module is respectively connected with the bus bridge module and the electrical isolation module, and is used for packaging second data received by the bus bridge module and sending the second data to the slave logic control module through the electrical isolation module; the main logic control module further comprises: a first memory controller and a first memory; the first storage controller is respectively connected with the main data decapsulation module, the first storage and the bus bridge module, and is used for storing the first data output by the main data decapsulation module into the first storage and sending the first data stored in the first storage in batches in times through the bus bridge module; and/or, a second memory controller and a second memory; the second storage controller is respectively connected with the main data packaging module, the second storage and the bus bridge module, and is used for storing second data received by the bus bridge module into the second storage and sending the second data stored in the second storage to the main data packaging module in batches. The signal isolation module is as follows: an isolation chip, a magnetic isolator, an optical coupler isolator or an optoelectronic isolator. The slave logic control module is a slave FPGA module, and the master logic control module is a master FPGA module. The main logic control module further comprises: the first buffer is connected with the first storage controller and used for buffering the first data output by the main data decapsulation module under the control of the first storage controller and sending the buffered first data to the first storage in batches in times through the first storage controller; and/or the second buffer is connected with the second storage controller and used for buffering second data received from the bus bridge module under the control of the second storage controller and sending the buffered second data to the slave logic control module through the second storage controller in batches in times.

The bus bridge module is a PCI bridge chip. The data acquisition module comprises: a digital input/output module, a digital-to-analog conversion module, and/or an analog-to-digital conversion module. The digital input/output module comprises a plurality of digital input channels and a plurality of digital output channels; and/or the digital-to-analog conversion module comprises a plurality of paths of synchronous analog output channels; and/or the digit of the analog-to-digital conversion module is 24 bits, and the sampling rate is 4 million samples per second; or the analog-to-digital conversion module is provided with a plurality of analog signal input channels, and comprises an input selection unit, a programmable gain amplifier unit and an analog-to-digital conversion unit, wherein the input selection unit is used for carrying out gating control on the plurality of analog signal input channels, the programmable gain amplifier unit is used for amplifying the analog signals input by the plurality of analog signal input channels, and the analog-to-digital conversion unit is used for converting the amplified analog signals into digital signals for output; and/or the digital input/output module, the digital-to-analog conversion module and the analog-to-digital conversion module are sequentially in communication connection.

According to the acquisition module, the slave logic control module is arranged on the side close to a system to be measured, the main logic control module is arranged on the side close to an upper computer (also called a host), data transmitted between the slave logic control module and the main logic control module are digital signals, and the electrical isolation module is arranged on the part of the data acquisition card for transmitting the digital signals, namely the signal isolation link is arranged on the digital part of the signals, so that the interference of common-mode voltage and the like introduced into the system to be measured is avoided, the signal loss caused by isolating analog signals is avoided, and the isolated acquisition of the data is realized at lower cost.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. A fully intelligent power saver is characterized by comprising: the system comprises a first relay, a second relay, a first inductor, a second inductor, an MCU module, a power module, an acquisition unit, a power carrier module and a driving unit, wherein the first inductor and the second inductor are connected in series;

wherein,

the first inductor is an overvoltage winding, and the second inductor is a power reduction winding;

the power supply module provides working voltage for the MCU module;

the power carrier module receives a power carrier signal, demodulates the power carrier signal and sends the demodulated power carrier signal to the MCU module; receiving a feedback instruction fed back by the MCU module, converting the feedback instruction into a power carrier signal, and transmitting the power carrier signal to the MCU module; the feedback instruction is the current working state information of the discharge lamp;

the MCU module generates a corresponding MCU instruction according to a power carrier signal sent by the power carrier module or a received voltage signal which is acquired by the acquisition unit and subjected to isolation protection;

the driving unit receives the MCU instruction and drives the first relay or the second relay to act; the driving unit comprises a pulse square wave generator and at least one driving module;

the output end of the pulse square wave generator is connected with the first input end of the driving module, the pulse square wave generator inputs a high-frequency square wave pulse signal to the first input end of the driving module, the driving module is also provided with a second input end for inputting a low-frequency driving signal, the driving module comprises a signal conversion circuit unit and a driving circuit unit, and the signal conversion circuit unit is connected with the driving circuit unit through a pulse transformer;

when the second input end of the driving module is at a high level, the signal conversion circuit unit converts the input low-frequency driving signal and the input high-frequency square wave pulse signal into an alternating-current high-frequency pulse signal, and the pulse transformer outputs a driving voltage signal through the driving circuit unit after isolating and transforming the alternating-current high-frequency pulse signal; the number of the driving modules is at least two, the first input end of each driving module is respectively connected with the output end of the pulse square wave generator, and the second input end of each driving module is respectively used for inputting corresponding low-frequency driving signals;

the power module comprises a voltage conversion unit, an overvoltage protection unit and a power supply, wherein the input end of the voltage conversion unit is connected with the power supply to receive a first voltage provided by the power supply, and the output end of the voltage conversion unit is connected with the electronic element;

the power module comprises a voltage conversion unit, an overvoltage protection unit and a power supply, wherein the input end of the voltage conversion unit is connected with the power supply to receive a first voltage provided by the power supply, and the output end of the voltage conversion unit is connected with the electronic element;

the acquisition unit includes: the data acquisition module is used for acquiring and/or outputting data of the system to be measured; the slave logic control module is connected with the data acquisition module and is used for carrying out logic control on the data acquisition module; the slave logic control module and the master logic control module are used for controlling the master logic control module; an electrical isolation module for electrical isolation is connected between the slave logic control module and the master logic control module; the main logic control module is also connected with a bus bridge module, and the bus bridge module is used for realizing the communication of the main logic control module; the electrical isolation module includes: the power isolation module is respectively connected with the slave logic control module and the master logic control module and is used for power isolation; the signal isolation module is respectively connected with the slave logic control module and the master logic control module and is used for signal isolation; the slave logic control module comprises: the slave data packaging module is respectively connected with the data acquisition module and the electrical isolation module and is used for packaging the first data acquired by the data acquisition module and transmitting the first data to the master logic control module through the electrical isolation module; the main logic control module comprises: the main data decapsulation module is respectively connected with the electrical isolation module and the bus bridge module and is used for decapsulating the first data received by the electrical isolation module; and/or the slave logic control module further comprises: and the slave data decapsulation module is connected with the electrical isolation module and used for decapsulating the second data received by the electrical isolation module and outputting the decapsulated second data to the system side to be measured.

2. The fully intelligent power saver according to claim 1, wherein the connection point of the first relay and the second relay is connected with one end of the first inductor and the second inductor which are connected in series; the other end of the first inductor is connected with a first static contact of the first relay, and the other end of the second inductor is connected with a second static contact of the second relay; the movable contact of the first relay is connected with the acquisition unit, and the movable contact of the second relay is connected with the standard inductor.

3. The fully intelligent power saver according to claim 2, wherein the voltage conversion unit comprises: the device comprises a power supply circuit, an energy storage booster circuit, a positive voltage generating circuit, a negative voltage generating circuit and a reference voltage generating circuit; the energy storage booster circuit comprises a booster chip and an inductor;

the output end of the power supply circuit is respectively connected with the input end of the boosting chip and the first end of the inductor;

the second end of the inductor is respectively connected with the control end of the boosting chip, the input end of the positive voltage generating circuit, the input end of the negative voltage generating circuit and the input end of the reference voltage generating circuit;

the power supply circuit is used for providing a unipolar input voltage;

the boosting chip is used for controlling the voltage at two ends of the inductor and respectively providing the voltage at two ends of the inductor to the positive voltage generating circuit, the negative voltage generating circuit and the reference voltage generating circuit;

the positive voltage generating circuit is used for generating a positive voltage according to the voltage at two ends of the inductor;

the negative voltage generating circuit is used for generating a negative voltage according to the voltage at two ends of the inductor;

the reference voltage generating circuit is used for generating reference voltage according to the voltage at two ends of the inductor.

4. The fully intelligent power saver according to claim 3 wherein the positive voltage generating circuit is a first charge pump circuit, wherein the first charge pump circuit is configured to generate a positive voltage according to the voltage across the inductor, and the first charge pump circuit comprises an N-stage charge pump circuit, where N is a positive integer greater than or equal to 1.

5. The fully intelligent power saver according to claim 4 wherein the Nth stage charge pump circuit of the first charge pump circuit comprises a first capacitor, a first diode and a second diode; wherein,

the cathode of the first capacitor is connected with the second end of the inductor, and the anode of the first capacitor is respectively connected with the anode of the first diode and the cathode of the second diode; the anode of the second diode is connected with the cathode of the first diode in the N-1 st level charge pump circuit of the first charge pump circuit;

and the negative electrode of the first diode outputs the positive voltage according to the voltage at the two ends of the inductor and the voltage of the positive electrode of the first capacitor.

6. The fully intelligent power saver according to claim 5, wherein the overvoltage protection unit comprises first to fifth electronic switches, first to sixth resistors, and an eighth diode, a first terminal of the first electronic switch is connected to the output terminal of the voltage conversion unit through the first resistor and is grounded through the first two or more resistors, a second terminal of the first electronic switch is connected to the power supply through the first three resistors to receive the second voltage provided by the power supply, a first terminal of the first two or more electronic switches is connected to a second terminal of the first electronic switch, a second terminal of the first two or more electronic switches is connected to the power supply through the first four resistors to receive the second voltage, a first terminal of the first three or more electronic switches is connected to the power supply through the first five resistors to receive the second voltage, a second terminal of the first third electronic switch is connected to a cathode of the eighth diode, a third terminal of the first third electronic switch is connected to the power supply to receive the second voltage, the anode of the eighth diode is connected with the second end of the first two-electron switch, the first end of the first four-electron switch is connected with the cathode of the eighth diode, the second end of the first four electronic switch is connected with the first end of the first three electronic switch, the first end of the first five electronic switch is connected with the second end of the first four electronic switch, the second end of the first fifth electronic switch is connected with the power supply through the first sixth resistor to receive the second voltage and is connected with a power starting signal pin of the power supply, and the third ends of the first, second, fourth and fifth electronic switches are all grounded.

7. The fully intelligent power saver according to claim 6, wherein when the voltage output by the output terminal of the voltage conversion unit is equal to the operating voltage of the electronic component, the first electronic switch is turned off, the first two electronic switches are turned on, the eighth diode is turned off, the first four electronic switches are turned off, the first three electronic switches are turned off, the first five electronic switches are turned on, the second terminal of the first five electronic switches outputs a low-level signal to the power-on signal pin, and the power supply operates normally; when the voltage output by the output end of the voltage conversion unit is greater than the working voltage of the electronic element, the first electronic switch is turned on, the first two electronic switch is turned off, the eighth diode is turned on, the first four electronic switch is turned on, the first three electronic switch is turned on, the first five electronic switch is turned off, the second end of the first five electronic switch outputs a high-level signal to the power supply starting signal pin, and the power supply stops voltage output.

8. The fully intelligent power saver according to claim 7, wherein the negative voltage generating circuit is a second charge pump circuit, wherein the second charge pump circuit is configured to output the negative voltage according to the voltage across the inductor, and the second charge pump circuit comprises M stages of charge pump circuits, and M is a positive integer greater than or equal to 1.

9. The fully intelligent power saver according to claim 8 wherein each stage of the second charge pump circuit comprises a second capacitor, a third diode and a fourth diode.

10. The fully intelligent power saver according to claim 9, wherein the anode of the second capacitor is connected to the second end of the inductor, and the cathode of the second capacitor is connected to the anode of the third diode and the cathode of the fourth diode, respectively; the cathode of the third diode is connected with the anode of a third diode in the M-1 stage charge pump circuit of the second charge pump circuit;

and the anode of the fourth diode outputs the negative voltage according to the cathode voltage of the second capacitor.