CN212627137U - Fault arc protection device - Google Patents

Abstract

The utility model provides a fault arc protection device, including control electronic circuit board, control electronic circuit board includes: the device comprises a data acquisition amplifying circuit, an arc data analysis circuit, a data analysis program and a data instruction input and output circuit; the signal processing circuit processes the sampling signal to obtain a characteristic analog signal, and the characteristic analog signal is converted into a characteristic digital signal; acquiring the characteristic value signal, and judging whether a fault arc occurs in a load circuit based on the data analysis program; the electrical parameter acquisition sensor is a metal resistance sensor which is directly connected to the output load end of the main line to be measured in series; the metal resistance sensor comprises N series resistors, M parallel resistors and a resistor enabling controller, wherein the resistor enabling controller controls the M parallel resistors to be not communicated at the same moment, so that full-wave-band and full-frequency waveform data on the output load end of the tested main line are collected.

Description

Fault arc protection device

Technical Field

The utility model belongs to the technical field of electrical equipment, especially, relate to a fault arc protection device.

Background

At present, the existing fault arc protection device mainly uses a current transformer as an arc waveform acquisition element, and as the arc waveform data acquired by the current transformer is limited by the current magnitude, the current frequency, the ambient temperature, the volume, the structure and the like, the acquired waveform data cannot contain real-time data of all frequencies and all current magnitudes, so that some fault arc waveform data are inevitably omitted, and some fault arcs cannot be cut off for protection or electrical fire is caused, which is a great technical hidden danger. This indicates that the current transformer is used to collect the fault arc waveform data of the fault arc protection device, and people's life and property cannot be protected reliably.

In addition, similar fault arc protection products in the market at present are independent and isolated products, and have no program upgrading, so that novel arc waveform data generated by a subsequent novel electric appliance cannot be monitored and protected. The potential hidden danger of electrical fire is brought to people, and the life and property safety of people is threatened all the time.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a fault arc protection device, fault arc protection device includes the control electronic circuit board, the control electronic circuit board includes: the device comprises a data acquisition amplifying circuit, an arc data analysis circuit, a data analysis program and a data instruction input and output circuit; the acquired data amplifying circuit comprises an electrical parameter acquisition sensor, the electrical parameter acquisition sensor is connected with an output load end of a main line to be detected, the electrical parameter acquisition sensor is connected with a signal sampling circuit, and the signal sampling circuit samples signals in the main line to be detected based on the electrical parameter acquisition sensor; the signal sampling circuit is connected with a signal processing circuit, the signal processing circuit processes the sampling signal to obtain a characteristic analog signal, and the analog characteristic signal is input to the microprocessor MCU module; converting the characteristic analog signal into a characteristic digital signal through a digital-to-analog conversion (AD) processing unit of the microprocessor MCU; the arc data analysis circuit acquires the characteristic value signal and judges whether a fault arc occurs in a load circuit based on the data analysis program; and when the fault circuit is judged to occur, the data instruction input-output circuit outputs a corresponding signal instruction.

More specifically, as one of the contributions of the present invention to the prior art, in the present invention, the electrical parameter acquisition sensor is a metal resistance sensor directly connected in series to the output load terminal of the main line to be measured;

the metal resistance sensor can be used for collecting full-wave-band full-frequency waveform data on the output load end of the main line to be tested;

as a more specific key technical means for embodying the above-mentioned outstanding contribution, the metal resistance sensor includes N series resistors, M parallel resistors, and a resistance enable controller that controls the M parallel resistors to not be simultaneously connected at the same time.

The resistance enabling controller comprises a time sequence random number generator, the time sequence random number generator generates at least one random number of a positive integer value based on a sampling time sequence stored by the signal sampling circuit, and controls corresponding resistors in the M parallel resistors to be communicated based on the random number of the positive integer value, so that the acquisition of full-wave-band and full-frequency waveform data on the output load end of the tested main line is realized.

On the other hand, the normal working state of the fault arc protection device can be remotely monitored through a remote communication function, so that the safety of life and property of people can be ensured to be protected constantly by the fault arc protection device;

therefore, as a further contribution of the present invention, the fault arc protection device further includes a testing device and a testing button, so that a user can check whether the function of the fault arc protection device is intact through the testing button;

the test button independently forms a simulated fault arc current and a leakage current, a user only needs to operate the test button regularly, and if a protection reaction normally occurs, the fault arc protection device is in an effective working state; and a test instruction is sent through the wireless data communication module to check whether the function of the fault arc protection device is intact.

In addition, do not possess the defect that the produced novel electric arc waveform data of procedure just can not monitor and protect to subsequent novel electrical apparatus for prior art's upgrading, the technical scheme of the utility model can also carry out through wired data communication port the firmware of control electronic circuit board with the renewal and the upgrading of data analysis procedure.

Further advantages of the present invention will be presented in further detail in the detailed description section in conjunction with the drawings attached to the description.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is an overall frame diagram of a fault arc protection device according to an embodiment of the present invention;

FIG. 2 is a schematic view of the internal structure of the apparatus of FIG. 1;

FIG. 3 is a schematic diagram of a connection circuit for arc testing using the apparatus of FIG. 1;

fig. 4 is a diagram of further details of the circuit of fig. 3.

The reference numerals in the figures have the following meanings:

1. an operating handle; 2. an operating mechanism; 3. A test button; 4. a main contact; 5. an incoming line wiring terminal; 6. an overload protection device; 7. a short circuit protection device; 8. an arc extinguishing device; 9. an electric shock leakage detection device; 10. a load wiring terminal; 11. on-off state indication; 12. a functional indication; 13. a control electronic circuit board; 14. a data communication port; 15. metal (shunt) sensors; 16. a plastic housing; 17. a plastic housing.

Detailed Description

The following description of the present invention will be made with reference to the accompanying drawings.

As shown in fig. 1 and 2, a fault arc protection device includes: an operating handle 1; an operating mechanism 2; a test button 3; a main contact 4; an incoming wire connecting terminal 5; an overload protection device 6; a short-circuit protection device 7; an arc extinguishing device 8; an electric shock leakage detection device 9; a load terminal 10; on-off status indication 11; a functional indication 12; a control electronic circuit board 13; a data communication port 14; a metal (shunt) sensor 15; a plastic housing 16; a plastic housing 17.

The operating handle 1, the operating mechanism 2, the main contact 4 and the arc extinguishing device 8 form a switching mechanism of a main power line of the device, so that manual switching-on and switching-off can be realized, and the triggering and switching-off function of the mechanism can also be realized.

Referring to fig. 1-2, the arc protection device of the present embodiment includes an external plastic protection member, a control electronic circuit board, an electrical parameter acquisition sensor, a short circuit protection mechanism, a leakage detection and protection device, an overload protection device, an input/output wiring device, a main circuit on/off indication device, a test loop test device, and an operating mechanism trip free device.

The control electronics board includes: the device comprises a collected data amplifying circuit, an electric arc data analyzing circuit, a data analyzing program, a data instruction input and output circuit, a wired data communication port, a wireless data communication module and a working state indicating circuit.

The fault electric arc protection device comprises a short circuit protection device, an overload protection device and an electric shock and electric leakage detection device, wherein the short circuit protection device is used for carrying out short circuit safety protection, the overload protection device is used for carrying out overload safety protection, the control electronic circuit board is used for carrying out safety protection on fault electric arcs, and the electric shock and electric leakage detection device is used for carrying out safety protection on electric leakage and electric shock circuit abnormity.

Furthermore, a short-circuit protection mechanism, a leakage detection and protection device, an overload protection device, an input/output wiring device, a main circuit connection and disconnection indicating device, a test loop testing device, an operating mechanism free tripping device and the like form a mechanical system with the functions of short circuit, overload, electric shock, leakage, wiring, operation and the like.

Furthermore, a collected data amplifying circuit, an arc data analyzing circuit, a data analyzing program, a data instruction input/output circuit, a wired data communication port, a wireless data communication module, a working state indicating circuit and the like are integrated into the control electronic circuit board to form an electronic control system.

Further, the metal (shunt) sensor in the mechanical system, the collected arc waveform signal, is connected to the electronic control system to form an assembly, and the assembly is placed in the plastic protective shell to form the fault arc protection device described in the embodiment.

The fault arc protection device also comprises a testing device and a testing button, so that a user can check whether the function of the fault arc protection device is intact or not through the testing button;

the test button independently forms a simulated fault arc current and a leakage current, a user only needs to operate the test button regularly, and if a protection reaction normally occurs, the fault arc protection device is in an effective working state.

And sending a test instruction through the wireless data communication module to check whether the function of the fault arc protection device is intact.

Referring next to fig. 3, the collected data amplifying circuit includes an electrical parameter collecting sensor, the electrical parameter collecting sensor is connected to an output load end of the main line to be tested, the electrical parameter collecting sensor is connected to a signal sampling circuit, and the signal sampling circuit samples a signal in the main line to be tested based on the electrical parameter collecting sensor;

the signal sampling circuit is connected with a signal processing circuit, the signal processing circuit processes the sampling signal to obtain a characteristic analog signal, and the analog characteristic signal is input to the microprocessor MCU module;

converting the characteristic analog signal into a characteristic digital signal through a digital-to-analog conversion (AD) processing unit of the microprocessor MCU;

the arc data analysis circuit acquires the characteristic value signal and judges whether a fault arc occurs in a load circuit based on the data analysis program;

and when the fault circuit is judged to occur, the data instruction input-output circuit outputs a corresponding signal instruction.

The metal (shunt) sensor 15 samples the signal in the main line under test. And performing special processing on the sampling signal to obtain a characteristic analog signal, and converting the characteristic analog signal into a characteristic digital signal through a digital-to-analog conversion (AD) processing unit of the microprocessor MCU. The digital signal is used for judging whether a fault arc occurs in the load circuit through a complex algorithm between the microprocessor MCU and the arc detection module.

Such algorithms are well known in the art and will not be described in detail herein.

When a fault arc occurs, a corresponding signal is output. The control module provides an LED interface for LED output expression. Button interface, key control, for necessary operational control. GPIO [3:1] is an additional GPIO interface. Meanwhile, the module can provide an I2C interface and interfaces such as a Universal Asynchronous Receiver Transmitter (UART) and the like for communication, and can communicate with an external circuit or upload alarm information to monitoring equipment, so that the occurrence of fault arc fire is effectively prevented.

On the basis of fig. 3, further reference is made to fig. 4. In this embodiment, for the data acquisition mode of the arc, the slave circuit is directly connected in series in the main line to be tested through the metal resistor (shunt) for direct acquisition, instead of the inductive acquisition through the current transformer, so that the defects of the transformer, such as easy current saturation, inconsistent high and low frequency induction, large occupied space volume, easy stress influence and the like, are effectively avoided.

Specifically, the electrical parameter acquisition sensor is a metal resistance sensor directly connected in series to the output load end of the main line to be measured.

The metal resistance sensor comprises N series resistors, M parallel resistors and a resistor enabling controller, wherein the resistor enabling controller controls the corresponding enabling switches, so that the M parallel resistors are not communicated at the same time.

The resistance enabling controller comprises a time sequence random number generator, the time sequence random number generator generates at least one random number of a positive integer value based on a sampling time sequence stored by the signal sampling circuit, and the corresponding resistance in the M parallel resistors is controlled to be connected or disconnected based on the random number of the positive integer value.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (10)

1. A fault arc protection device comprising a control electronics board, characterized in that: the control electronic circuit board includes: the device comprises a data acquisition amplifying circuit, an arc data analysis circuit, a data analysis program and a data instruction input and output circuit;

the acquired data amplifying circuit comprises an electrical parameter acquisition sensor, the electrical parameter acquisition sensor is connected with an output load end of a main line to be detected, the electrical parameter acquisition sensor is connected with a signal sampling circuit, and the signal sampling circuit samples signals in the main line to be detected based on the electrical parameter acquisition sensor;

the signal sampling circuit is connected with the signal processing circuit, the signal processing circuit processes the sampling signal to obtain a characteristic analog signal, and the characteristic analog signal is input to the microprocessor MCU module;

converting the characteristic analog signal into a characteristic digital signal through a digital-to-analog conversion (AD) processing unit of the microprocessor MCU;

the arc data analysis circuit acquires the characteristic digital signal and judges whether a fault arc occurs in a load circuit based on the data analysis program;

and when the fault circuit is judged to occur, the data instruction input-output circuit outputs a corresponding signal instruction.

2. A fault arc protection device, as claimed in claim 1, wherein: the fault electric arc protection device comprises a short circuit protection device, an overload protection device and an electric shock and electric leakage detection device, wherein the short circuit protection device is used for carrying out short circuit safety protection, the overload protection device is used for carrying out overload safety protection, the control electronic circuit board is used for carrying out safety protection on fault electric arcs, and the electric shock and electric leakage detection device is used for carrying out safety protection on electric leakage and electric shock circuit abnormity.

3. A fault arc protection device, as claimed in claim 1, wherein: the signal sampling circuit samples signals in a main line to be tested based on the electrical parameter acquisition sensor, and specifically comprises:

the electrical parameter acquisition sensor is a metal resistance sensor which is directly connected in series to the output load end of the main line to be measured.

4. A fault arc protection device, as claimed in claim 3, wherein: and acquiring full-wave-band and full-frequency waveform data on the output load end of the main line to be tested by using the metal resistance sensor.

5. A fault arc protection device according to any of claims 1-4, wherein: the fault arc protection device also comprises an external plastic protection piece, an input/output wiring device, a main circuit connection and disconnection indicating device, a test loop testing device and an operating mechanism free tripping device;

the control electronic circuit board further comprises a collected data amplifying circuit, a wired data communication port, a wireless data communication module and a working state indicating circuit.

6. A fault arc protection device, as claimed in claim 5, wherein: and updating and upgrading the firmware of the control electronic circuit board and the data analysis program through the wired data communication port.

7. A fault arc protection device, as claimed in claim 5, wherein: the fault arc protection device also comprises a testing device and a testing button, so that a user can check whether the function of the fault arc protection device is intact or not through the testing button;

the test button independently forms a simulated fault arc current and a leakage current, a user only needs to operate the test button regularly, and if a protection reaction normally occurs, the fault arc protection device is in an effective working state.

8. A fault arc protection device, as claimed in claim 5, wherein: and sending a test instruction through the wireless data communication module to check whether the function of the fault arc protection device is intact.

9. A fault arc protection device, as claimed in claim 4, wherein: the metal resistance sensor comprises N series resistors, M parallel resistors and a resistor enabling controller, wherein the resistor enabling controller controls the M parallel resistors to be communicated at the same moment at different times.

10. A fault arc protection device, as claimed in claim 9, wherein: the resistance enabling controller comprises a time sequence random number generator, the time sequence random number generator generates at least one random number of a positive integer value based on a sampling time sequence stored by the signal sampling circuit, and the corresponding resistance in the M parallel resistors is controlled to be communicated based on the random number of the positive integer value.

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