Summary of the invention
Based on this, it is necessary to provide a kind of multi-energy data monitoring device and system, the accurate of multi-energy data monitoring can be improved
Property and real-time.
On the one hand, the present invention provides a kind of multi-energy data monitoring device comprising controller and CAN bus transmitting-receiving driving electricity
Road;
Controller includes CAN signal transmitting terminal and CAN signal receiving end;
CAN bus transmitting-receiving driving circuit includes CAN transceiver, the first isolation circuit and the second isolation circuit;
The CAN transceiver includes the bus pin that connect for the multi-energy data output end with node device to, signal
Transmitting terminal and signal receiving end;
The signal sending end of the CAN transceiver is connected to the input terminal of first isolation circuit, and signal receiving end connects
It is connected to the input terminal of second isolation circuit;The output end of first isolation circuit is connected to the CAN letter of the controller
Number transmitting terminal;The output end of second isolation circuit is connected to the CAN signal receiving end of the controller.
Compared with the prior art, multi-energy data monitoring device provided by the invention can receive and dispatch driving circuit by CAN bus
It realizes the data of more node devices while concurrently uploading without causing bus congestion, reduce the risk of data entanglement, improve energy
The accuracy and real-time of source data monitoring.
In a kind of optional embodiment, first isolation circuit includes the 8th resistance and the first high speed photo coupling core
Piece;The first high speed photo coupling chip includes cathode, anode, power input and open collector;First high speed photo coupling
The cathode of chip is connected to the first power supply by the 8th resistance, and anode is connected to the CAN signal transmitting terminal of the controller,
Open collector and power input are all connected to second source.
In a kind of optional embodiment, second isolation circuit includes the tenth resistance, the second high speed photo coupling chip
With eleventh resistor;The second high speed photo coupling chip includes cathode, anode, power input and open collector;Described
The cathode of two high speed photo coupling chips is connected to the second source by the tenth resistance, and anode is connected to the CAN transmitting-receiving
The signal receiving end of device, open collector are connected to the CAN signal receiving end of the controller, and open collector is connected to described
First power supply;The open collector of the second high speed photo coupling chip is also connected to first electricity by the eleventh resistor
Source.
In a kind of optional embodiment, the CAN bus transmitting-receiving driving circuit further includes the 7th resistance and the 9th electricity
Resistance;The bus pin is to including bus high level pin and bus low level pin;The bus high level pin passes through institute
The 7th resistance is stated to connect with the bus low level pin;The signal sending end of the CAN transceiver passes through the 9th resistance
It is connected to the second source.
In a kind of optional embodiment, the CAN bus transmitting-receiving driving circuit further includes that the TVS transient state inhibits two
Pole pipe;The bus high level pin is also connect by the TVS Transient Suppression Diode with the bus low level pin.
Wherein, the ground of CAN bus transmitting-receiving driving circuit connection is signal ground, mutually isolated with the power ground of system.
In a kind of optional embodiment, described device further includes capacitor charging discharging circuit;The capacitor charging discharging circuit packet
Include first diode, 3rd resistor, the 4th resistance, super capacitor and the second diode;The anode connection of the first diode
To power supply, cathode is connected to the anode of the super capacitor;The cathode of one end of the 3rd resistor and the first diode
Connection, the other end are connect with one end of the 4th resistance;The other end of 4th resistance is grounded;The super capacitor is born
Pole ground connection, anode are also connect with the anode of second diode;The controller further includes power input;Described 2nd 2
The cathode of pole pipe is connect with the power input of the controller.
In a kind of optional embodiment, the CAN bus transmitting-receiving driving circuit further includes power end, for accessing
State the first power supply and the second source;Electricity of the cathode of second diode also with CAN bus transmitting-receiving driving circuit
Source connection.
In a kind of optional embodiment, described device further includes wireless communication module;The wireless communication module is
One of 2G, 4G, LoRaWAN or NB-IoT communication module.
In a kind of optional embodiment, the first diode is Schottky diode;And/or the described 2nd 2
Pole pipe is Schottky diode.
On the other hand, the present invention also provides a kind of multi-energy datas to monitor system, and the system comprises such as any of the above-described implementations
Multi-energy data monitoring device and server described in example;The controller of the multi-energy data monitoring device includes that network communication connects
Mouthful;The multi-energy data monitoring device is communicated by the network communication interface and the server.
Compared with the prior art, multi-energy data provided by the invention monitors system, can receive and dispatch driving circuit by CAN bus
It realizes the data of more node devices while concurrently uploading without causing bus congestion, reduce the risk of data entanglement, improve energy
The accuracy and real-time of source data monitoring;The connection that controller and server are realized by network communication circuit, can enable this
Source data monitoring device is suitable for internet of things field, conducive to the intelligence for realizing multi-energy data monitoring.
Specific embodiment
Following will be combined with the drawings in the embodiments of the present invention, and technical solution in the embodiment of the present invention carries out clear, complete
Site preparation description, it is clear that described embodiments are only a part of the embodiments of the present invention, instead of all the embodiments.It is based on
Embodiment in the present invention, it is obtained by those of ordinary skill in the art without making creative efforts every other
Embodiment shall fall within the protection scope of the present invention.
It should be noted that when element by claim with another element " connection " when, it can directly with another element
It connects or there may also be elements placed in the middle.
Unless otherwise defined, all technical and scientific terms used herein and belong to technical field of the invention
The normally understood meaning of technical staff is identical.Term as used herein in the specification of the present invention is intended merely to description tool
The purpose of the embodiment of body, it is not intended that in the limitation present invention.
Referring to Fig. 1, it is the structural schematic diagram of the multi-energy data monitoring device in an embodiment of the present invention.Such as Fig. 1
Shown, multi-energy data monitoring device 3 provided in this embodiment includes that controller 11 and CAN bus receive and dispatch driving circuit 17.Control
Device 11 includes CAN signal transmitting terminal CAN_TXD and CAN signal receiving end CAN_RXD.CAN bus receives and dispatches driving circuit 17
CAN transceiver 171, the first isolation circuit 172 and the second isolation circuit 173.CAN transceiver 171 includes being used for and node device
The connection of multi-energy data output end bus pin to, signal sending end TXD and signal receiving end RXD.
The signal sending end TXD of CAN transceiver 171 is connected to the input terminal of the first isolation circuit 172, signal receiving end
RXD is connected to the input terminal of the second isolation circuit 173.The output end of first isolation circuit 172 is connected to the CAN letter of controller 11
Number transmitting terminal CAN_TXD.The output end of second isolation circuit 173 is connected to the CAN signal receiving end CAN_RXD of controller 11.
Wherein, the bus pin of CAN transceiver 171 is to including bus high level pin H and bus low level pin L.Its
In, bus high level pin H is used to be connected to the CAN_H line of bus, and bus low level pin L is used to be connected to the CAN_ of bus
L。
Multi-energy data includes one of information such as voltage, electric current, power, power factor (PF), time, phase angle or a variety of.
Multi-energy data monitoring device provided in this embodiment supports CAN bus communications protocol, application-layer data transmission to support
Two kinds of JSON, *** protocol buffer serializing modes, can be adapted to various Internet of Things application scenarios extensively.This
Device can be received and dispatched driving circuit by CAN bus and realize the data of more node devices while concurrently upload without causing bus to gather around
Plug reduces the risk of data entanglement, improves the accuracy and real-time of multi-energy data monitoring.
Referring to Fig. 2, it is the schematic diagram of the CAN bus transmitting-receiving driving circuit in an embodiment of the present invention.
First isolation circuit 172 includes the 8th resistance R8 and the first high speed photo coupling chip U5;First high speed photo coupling chip U5
Including cathode Anode, positive C athode, power input VCC, open collector OUT and ground terminal GND;First high speed photo coupling
The cathode Anode of chip U5 is connected to the first power supply VCC_1 by the 8th resistance R8, and positive C athode is connected to controller 11
CAN signal transmitting terminal CAN_TXD, open collector OUT and power input VCC be all connected to second source VCC_2.
Second isolation circuit includes the tenth resistance, the second high speed photo coupling chip U6 and eleventh resistor R11;Second high-speed light
Coupling chip U6 includes cathode Anode, positive C athode, power input VCC, open collector OUT and ground terminal GND.Second
The cathode Anode of high speed photo coupling chip U6 is connected to second source VCC_2 by the tenth resistance R10, and positive C athode is connected to
The signal receiving end RXD of CAN transceiver U7, open collector OUT are connected to the CAN signal receiving end CAN_RXD of controller 11,
Open collector OUT is connected to the first power supply VCC_1.The open collector OUT of second high speed photo coupling chip U6 also passes through the tenth
One resistance R11 is connected to the first power supply VCC_1.
The electrical isolation that each node of CAN bus is realized by high speed photo coupling chip, improves the reliability of CAN communication, in turn
Improve the accuracy of multi-energy data monitoring.In the present embodiment, the first high speed photo coupling chip and the second high speed photo coupling chip are all adopted
Use ELM611.
Further, device 3 further includes the isolation DC/DC power supply for the first power supply VCC_1 and second source VCC_2 to be isolated
Module.First power supply is isolated with second source by the module, and the electrical isolation of each node of CAN bus is further realized, and is improved
The reliability of CAN communication, and then improve the accuracy of multi-energy data monitoring.
It further includes the 7th resistance R7 and the 9th resistance R9 that CAN bus, which receives and dispatches driving circuit,.Bus high level pin CAN_H is logical
The 7th resistance R7 is crossed to connect with bus low level pin CAN_L.The signal sending end TXD of CAN transceiver passes through the 9th resistance R9
It is connected to second source VCC_2.
It further includes TVS Transient Suppression Diode ZD3 that CAN bus, which receives and dispatches driving circuit 17,.Bus high level pin CAN_H is also
It is connect by TVS Transient Suppression Diode ZD3 with bus low level pin CAN_L.Inhibit two pole ZD3 that can press down by TVS transient state
Transition interference processed, improves the stability and accuracy of device.
CAN transceiver 171 further includes power input VDD, ground terminal VSS, reference end REF and spare end RS.Wherein,
The ground terminal VSS of CAN transceiver 171 is grounded, and power input VDD is connected to second source VCC_2.CAN bus transmitting-receiving driving
Circuit further includes resistance R25.The spare end RS of CAN transceiver 171 is grounded by resistance R25.
Further, device 3 further includes capacitor charging discharging circuit, referring to Fig. 4, it is the capacitor in an embodiment of the present invention
The schematic diagram of charge-discharge circuit.As shown in figure 4, capacitor charging discharging circuit includes first diode D1,3rd resistor R3, the 4th resistance
R4, super capacitor C1 and the second diode D2.Super capacitor also known as electrochemical capacitor, double layer capacitor, gold capacitor, farad
Capacitor is a kind of electrochemical element by polarized electrolytic matter come energy storage.
The anode of first diode D1 is connected to power supply VCC_SYS, and cathode is connected to the anode of super capacitor C1.Third electricity
One end of resistance R3 is connect with the cathode of first diode D1, and the other end is connect with one end of the 4th resistance R4;4th resistance R4's
Other end ground connection;The cathode of super capacitor C1 is grounded, and anode is also connect with the anode of the second diode D2.Controller 11 further includes
Power input (not shown).The cathode of second diode D2 is connect with the power input of controller 11.Controller 11
Power input powered by power supply VCC_P.Capacitor charging discharging circuit further includes resistance R23.The anode of first diode D1 is logical
It crosses resistance R23 and is connected to power supply VCC_SYS.Optionally, resistance R23 can be formed by multiple resistor coupled in parallel.
In system worked well, power supply VCC_SYS charges to super capacitor C1, and the voltage of the anode of super capacitor C1 is
VBATT.When system is powered down, super capacitor C1 electric discharge, the late-class circuit for the second diode D2 provides power supply VCC_P.
It is then system by the charge and discharge of super capacitor since controller 11 is set to the late-class circuit of the second diode D2
Power supply in short-term is provided when power down, carries out data preservation convenient for controller, to improve the reliability of multi-energy data monitoring.
Further, CAN bus transmitting-receiving driving circuit further includes power end, for accessing the first power supply VCC_1 and the
Two power supply VCC_2.The cathode of second diode D2 is also connect with the power end of CAN bus transmitting-receiving driving circuit 17.
In the present embodiment, the specification of super capacitor is 4F, 5.5V.The super capacitor of the specification can maintain controller and
CAN bus receives and dispatches drive circuit works certain time.Since controller 11 and CAN bus transmitting-receiving driving circuit are set to the two or two
The late-class circuit of pole pipe D2 is controller and CAN bus transmitting-receiving driving when system is powered down then by the charge and discharge of super capacitor
Circuit provides power supply in short-term, receives and dispatches driving circuit reported data by CAN bus convenient for node device, and be convenient for controller
Data preservation is carried out, to improve the reliability of multi-energy data monitoring.
In a kind of optional embodiment, first diode D1 is Schottky diode.Second diode D2 is Xiao Te
Based diode.Power consumption can be reduced using Schottky diode, improved efficiency.In other embodiments, first diode D1 can
To be the diodes such as fast recovery diode, general-purpose diode.Second diode D2 can be fast recovery diode, general-purpose diode
Equal diodes.
Further, controller 11 further includes detection of power loss end;Power down of the other end of 3rd resistor R3 also with controller 11
Test side connection.
Further, device 3 further includes power isolation circuit;The cathode of second diode D2 by power isolation circuit with
CAN bus receives and dispatches the power end connection of driving circuit.
Specifically, power isolation circuit includes DCDC isolating chip, third capacitor and the 4th capacitor (not shown).
DCDC isolating chip includes upstream power end, grounded upstream end, downstream power end and downstream ground terminal.Second diode D2's is negative
The upstream power end of pole connection DCDC isolating chip.The power end that CAN bus receives and dispatches driving circuit 17 connects DCDC isolating chip
Downstream power end.The grounded upstream end of DCDC isolating chip also passes through the third capacitance connection to power ground;The DCDC
The downstream ground terminal of isolating chip also passes through the 4th capacitance connection to signal ground.Electrical isolation is carried out by power isolation circuit,
Electrical Interference is prevented, stability is improved.
Further, device 3 further includes voltage-stablizer.The downstream power end of the DCDC isolating chip passes through voltage-stablizer and CAN
Bus receives and dispatches the power end connection of driving circuit 17.
Preferably, voltage-stablizer includes enable end, input terminal and output end.The input terminal of voltage-stablizer and DCDC isolating chip
The connection of downstream power end, the power end of output end and CAN bus transmitting-receiving driving circuit 17.Controller 11 further includes the enabled letter of CAN
Number output end.The CAN enable signal output end of controller 11 and the enable end of voltage-stablizer connect.Controller 11 is specifically used for when inspection
When measuring power-off signal, first control signal is sent to the enable end of voltage-stablizer, so that the output end out-put supply of voltage-stablizer, and
Fault message is obtained to CAN bus transmitting-receiving driving circuit 17;Controller 11 is also used to after receiving fault message, to voltage-stablizer
Enable end sends second control signal, so that the output end of voltage-stablizer stops out-put supply.By being sent out to the enable end of voltage-stablizer
Control signal is sent, the power supply of CAN bus transmitting-receiving driving circuit can be disconnected after receiving fault message, to avoid CAN bus transmitting-receiving
Driving circuit continues to consume the electric energy of super capacitor, strives for that more times carry out storing data for controller, to guarantee energy number
According to being stored in time, the reliability of data storage is improved.
Specifically, multi-energy data monitoring device 3 further includes voltage signal sampling circuit, current signal sample circuit, three-phase
Metering chip, LCD display, memory, key, switching quantity detection circuit, detection circuit of uncapping, strong magnetic sensor circuit, RS485
Communicating circuit, network communication circuit, electric power management circuit, LED light indicating circuit, buzzer alert circuit etc..Further, network
Communicating circuit is wireless telecommunications mould group.Specifically, wireless telecommunications mould group can be the channel radios such as 2G, 4G, LoRaWAN, NB-IoT
Interrogate one of mould group.Preferably, wireless telecommunications mould group is NB-IoT communication module group.
Driving circuit and wireless telecommunications mould group are received and dispatched by CAN bus, convenient for controller when detecting that system is powered down, and
When the multi-energy data of node device reported into cloud, improve the real-time of multi-energy data monitoring.The present apparatus is supported in CAN bus
The data of sensor high concurrent upload, and realize the real-time active reporting of telemetering, remote signalling, remote regulating, remote-control data and alarm event
The inexpensive networking mode of equal innovations.
Further, detection circuit of uncapping includes infrared sensor.
Referring to Fig. 4, it is the structural schematic diagram of the multi-energy data monitoring device in a further embodiment of this invention.Such as figure
Shown in 4, multi-energy data monitoring device includes that controller 11 described in above-described embodiment and CAN bus receive and dispatch 17 (Fig. 5 of driving circuit
In be not shown), further include residual current detection circuit 12, temperature sensing circuit 14 and controllable switch 13.Controller 11 includes the
One signal acquisition terminal 110, second signal collection terminal 111 and control signal output 112.First signal acquisition of controller 11
End 110 is connect with the output end of residual current detection circuit 12;Second signal collection terminal 111 and the temperature detection electricity of controller 11
The output end on road 14 connects;Controllable switch 13 includes the first connecting pin 130 for connecting with power supply 15, be used for and load 16 connects
The second connection end 131 and controlled end 132 connect;The controlled end 132 of controllable switch 13 and the control signal output of controller 11
112 connections.
Residual current, also known as leakage current refer to each phase (containing the neutral conductor) current phasor in low-voltage distributing line and are not zero
Electric current.
Illustratively, controller 11 is used to send when detecting that temperature is more than preset temperature threshold to controllable switch 13
Third controls signal, so that controllable switch disconnects load and power supply;Controller 11, which is also used to work as, detects that residual current is more than pre-
If when current threshold, sending third to controllable switch 13 and controlling signal, so that controllable switch disconnects load and power supply.By to temperature
Degree and electric current monitor respectively, improve the response speed of Electrical Safety monitoring.
Illustratively, controller 11 is used for whether judging residual current when detecting that temperature is more than preset temperature threshold
More than predetermined current threshold, and when determining that residual current is more than predetermined current threshold, the 4th control is sent to controllable switch 13
Signal processed, so that controllable switch disconnects load and power supply.Controllable switch is controlled by combination temperature and residual current, is reduced and is missed
Sentence probability, improves reliability.
Multi-energy data monitoring device provided in this embodiment, can be real by residual current detection circuit and temperature sensing circuit
The parallel acquisition of existing residual current and temperature, conducive to the logical of controllable switch is controlled by controller combination residual current and temperature
It is disconnected, it will load and be disconnected with power supply, and to realize that multi-energy data monitors, improve the reliability of multi-energy data monitoring.By wireless
Communication module group can be realized and export control signal to controlled end 132 by cloud, realize long-range control, improves multi-energy data prison
The intelligence of survey.
Optionally, controllable switch includes relay.The moving contact of relay is connect with power supply 15, normally-closed contact and load
Connection.In other embodiments, the normally opened contact of relay and load connect.Illustratively, controllable switch further includes the 6th
The control signal output 112 of resistance and triode, controller 11 is connect with the base stage of triode by the 6th resistance.Triode
Emitter ground connection.The collector of triode is connected to the first coil pin of relay, and the second coil pin of relay connects
It is connected to working power.
Temperature sensing circuit 14 includes temperature sensor and second voltage signal amplification circuit.The output end of temperature sensor
It is connect with the input terminal of second voltage signal amplification circuit.The of the output end of second voltage signal amplification circuit and controller 11
Binary signal collection terminal 111 connects.
Further, temperature sensor is platinum resistance temperature sensor (PT100).
Referring to Fig. 5, it is the schematic diagram of the second voltage signal amplification circuit in an embodiment of the present invention.Such as Fig. 5
Shown, second voltage signal amplification circuit includes resistance R12~R22, capacitor C3, capacitor C4, the first operational amplifier U1 and
Two operational amplifier U2.One end of resistance R12 is grounded GND, and the other end is connect with one end of resistance R13.One end of resistance R13 is also
It is connect with one end of resistance R16.The other end of resistance R13 is connected to second voltage power supply VCC_T.The other end of resistance R16 with
The positive input terminal of first operational amplifier U1 connects.The positive input terminal of first operational amplifier U1 also passes through resistance R17 and is grounded
GND.One end of resistance R14 is connected to second voltage power supply VCC_T, and the other end is connect with one end of resistance R15.Resistance R15's
The other end is connect with the negative input end of the first operational amplifier U1.The negative input end of first operational amplifier U1 also passes through resistance
R22 is connect with the output end of the first operational amplifier U1.One end of resistance R15 also passes through capacitor C3 and is grounded.One end of resistance R15
It is also used to connect and (be not shown in Fig. 2) with the output end of temperature sensor.
The output end of first operational amplifier U1 is connect by resistance R19 with the positive input terminal of second operational amplifier U2.
The negative input end of second operational amplifier U2 is grounded by resistance R18.The negative input end of second operational amplifier U2 also passes through electricity
Resistance R20 is connected to the output end of second operational amplifier U2.The output end of second operational amplifier U2 and the second of controller 11
Signal acquisition terminal 111 connects.The output end of second operational amplifier U2 is connect by resistance R21 with one end of capacitor C4.Capacitor
The other end of C4 is grounded.
Second voltage signal amplification circuit further includes static suppressor ZD2.Resistance R14 also passes through static suppressor ZD2 and connects
Ground.
Sound-light alarm can be realized by LED light indicating circuit, buzzer alert circuit, improve the reliable of multi-energy data monitoring
Property.
Referring to Fig. 6, its be the schematic diagram of the residual current detection circuit in an embodiment of the present invention as shown in fig. 6,
Residual current detection circuit 12 includes residual current transformer 120, electric current turns potential circuit 121 and the amplification of first voltage signal is electric
Road 122;
The current line mode of connection of conventional junction component be bottom in and top out mode, miscellaneous function terminal shell two rows all
It is distributed, forceful electric power and light current do not do function distinguishing every there are dangerous and low efficiencys for, site operation the disadvantages of;And miscellaneous function end
Son is less, leads to afunction, is not adapted to plurality of application scenes.In the present embodiment, the structural member of multi-energy data monitoring device 3
(not shown) includes upper shell component, terminal assemblies, wiring board, residual current transformer, antenna and lower shell component, it is described on
Shell component, antenna and lower shell component connect composition hollow housing, the wiring board, terminal assemblies, residual current transformer mutual inductance
Device is arranged in hollow housing, and the terminal assemblies include earth-current line access terminal, pressure-wire access terminal and auxiliary function
Energy terminal, is separately connected wiring board and residual current transformer.
Present apparatus structural member uses new design mode, improves lower shell component and the terminal assemblies in structural member.It will be electric
Streamline access terminal Uniting is arranged under shell, and miscellaneous function terminal Uniting is arranged on shell, and increases auxiliary function
The quantity of energy terminal greatly enhances the extendable functions of the present apparatus to 15.The extendable functions include multi way temperature
With residual current acquisition, RS485 communication port, CAN bus communication port, multi-way switching values signal input, relay control output and
Accessory power supply power supply etc..
Residual current transformer 120 includes positive current output end and negative current output end;It includes that electric current, which turns potential circuit,
One resistance R1 and second resistance R2;The resistance value of first resistor R1 is equal with the resistance value of second resistance R2.One end of first resistor R1
It is connect with one end of second resistance R2;The other end of first resistor R1 and the positive current output end of residual current transformer 120 connect
It connects;The other end of second resistance R2 is connect with the negative current output end of residual current transformer 120;The other end of first resistor R1
Also it is connect with the input terminal of first voltage signal amplification circuit 122;The output end of first voltage signal amplification circuit 122 and control
First signal acquisition terminal 110 of device 11 connects.
Specifically, first voltage signal amplification circuit 122 includes resistance R7~R11, capacitor C2, capacitor C6, third operation
Amplifier U3 and four-operational amplifier U4.One end of resistance R7 is connect with one end of resistance R8.The other end of resistance R7 and
The positive input terminal of three operational amplifier U3 connects.The other end of resistance R8 and the negative current output end of residual current transformer 120
Connection.The negative input end of third operational amplifier U3 is connected to the output end of third operational amplifier U3 by resistance R9.Third
The output end of operational amplifier U3 is also connect with one end of resistance R10.The other end of resistance R10 passes through the fortune of resistance R11 and the 4th
Calculate the positive input terminal connection of amplifier U4.The positive input terminal of four-operational amplifier U4 also passes through capacitor C6 and is grounded.Resistance R10's
The other end also passes through the negative input end that capacitor C2 is connected to four-operational amplifier U4.The output end of four-operational amplifier U4 is also
It is connect with the negative input end of four-operational amplifier U4.The output end of four-operational amplifier U4 is also believed with the first of controller 11
Number collection terminal 110 connects.
Further, residual current detection circuit further includes static suppressor ZD1.One end of static suppressor ZD1 and residue
The positive current output end of current transformer 120 connects, and the other end is connect with the negative current output end of residual current transformer 120.
Further, residual current detection circuit further includes resistance R6.The positive input of resistance R6 and third operational amplifier U3
End connection.The resistance value of resistance R6 is 0 ohm.
Further, the Standard resistance range of first resistor R1 is less than 100 ohm.Preferably, the resistance value of first resistor R1 is 47
Ohm.
Further, the precision of first resistor R1 is less than or equal to 1%.The precision of the second resistance be less than or equal to
1%.Residual current detection precision is improved by precision resister, and then improves the reliability of multi-energy data monitoring.At other
In embodiment, the precision of first resistor R1 can be 1% or so.In another optional embodiment, the essence of second resistance R2
Degree can be 1% or so.
Multi-energy data monitoring device 3 further includes second voltage conversion circuit.The second voltage conversion circuit includes the 5th electricity
Resistance, transistor, low pressure difference linear voltage regulator.Further, low pressure difference linear voltage regulator includes power input, enable end, power supply
Output end.One end of 5th resistance and the enable end of low pressure difference linear voltage regulator connect, and the other end is connected to tertiary voltage power supply.
One end of 5th resistance is also connect with the collector of transistor.Controller 11 further includes enable signal control output end.Transistor
Emitter ground connection, base stage connect with the enable signal control output end of controller 11.The power supply of low pressure difference linear voltage regulator is defeated
Enter end and be connected to tertiary voltage power supply, power output end is for exporting the 4th voltage source.Temperature sensing circuit 14 further includes electricity
Source input terminal.The power input of temperature sensing circuit 14 is connected to the 4th voltage source.Residual current transformer 12 further includes
Power input.The power input of residual current transformer 12 is connected to the 4th voltage source.
Temperature sensing circuit and residual current detection circuit are realized by the enable end of low pressure difference linear voltage regulator
It is enabled, it can be applied to the scene for not needing temperature detection or residual current monitoring, thereby saving energy consumption.
Referring to Fig. 7, it is the structural schematic diagram of the multi-energy data monitoring system in an embodiment of the present invention.Such as Fig. 7
Shown, multi-energy data provided in this embodiment monitors system 2 comprising the multi-energy data monitoring as described in above-mentioned any embodiment
Device 3 and server 4;The controller 11 of multi-energy data monitoring device 3 includes network communication interface 113;Multi-energy data monitoring dress
3 are set to communicate by network communication interface 113 and server 4.
It should be noted that server 4 can be physical server, it is also possible to Cloud Server.
Compared with the prior art, multi-energy data provided in this embodiment monitors system, and driving electricity can be received and dispatched by CAN bus
Road is realized the data of more node devices while concurrently being uploaded without causing bus congestion, reduces the risk of data entanglement, improves
The accuracy and real-time of multi-energy data monitoring;The connection that controller and server are realized by network communication circuit, can make this
Multi-energy data monitoring device is suitable for internet of things field, and adaptation comprehensive energy is served by the Internet of Things of scene He " cloud " " pipe " " end "
Net solution.Such as: energy efficiency management, distribution O&M, safety monitoring scene, conducive to the intelligence for realizing multi-energy data monitoring.
Each technical characteristic of embodiment described above can be combined arbitrarily, for simplicity of description, not to above-mentioned reality
It applies all possible combination of each technical characteristic in example to be all described, as long as however, the combination of these technical characteristics is not deposited
In contradiction, all should be considered as described in this specification.
The embodiments described above only express several embodiments of the present invention, and the description thereof is more specific and detailed, but simultaneously
It cannot therefore be construed as limiting the scope of the patent.It should be pointed out that coming for those of ordinary skill in the art
It says, without departing from the inventive concept of the premise, various modifications and improvements can be made, these belong to protection of the invention
Range.Therefore, the scope of protection of the patent of the invention shall be subject to the appended claims.