CN216248157U - Protection outlet circuit on-line monitoring device - Google Patents

Abstract

A protection outlet loop online monitoring device comprises a first current limiting resistor, a second current limiting resistor, a power module, a power protection fuse, a first relay, a second relay and an electromagnetic isolation sampling module; the electromagnetic isolation sampling module is connected to the near trip contact end of the pressure plate in an electromagnetic isolation mode; when the pressure plate is reliably put into conduction, different paths are formed according to the polarity of the near-trip contact end potential of the pressure plate, so that the electromagnetic isolation sampling module respectively outputs different remote signaling signals; and obtaining an online monitoring result of the output protection outlet loop according to different remote signaling signals and external auxiliary state information. The utility model improves the action reliability of the relay protection equipment, reduces the protection failure probability caused by the abnormal outlet loop, and simultaneously provides relevant evidence information of the protection outlet condition for accident analysis, thereby improving the accident analysis capability and making the accident responsibility definition clearer.

Description

Protection outlet circuit on-line monitoring device

Technical Field

The utility model relates to the technical field of online monitoring of digital relay protection devices, in particular to an online monitoring device for a protection outlet loop.

Background

At present, a digital relay protection device is generally applied, and the perfect self-checking function of the digital relay protection device can reach the range of an outlet relay. However, a loop behind the outlet tripping/closing contact is a monitoring blind area, and information such as whether the loop is abnormal, whether the protection outlet contact acts normally, whether the pressing plate is reliably put into use and the like cannot be obtained, so that early warning and alarming cannot be performed in advance, the action reliability of the relay protection equipment is reduced, and the problems of protection failure and the like caused by abnormal outlet loop also occur.

In the prior art, a chinese invention patent (CN105097322) discloses a wire spring type protection outlet pressure plate on/off state recognition device, which cannot be applied to a digital relay protection device; chinese utility model patent (CN204761164U) discloses a device only suitable for use in the recognition of the entrance and exit of an outlet pressure plate with a conductive middle movable head; the Chinese invention patent (CN106841876) proposes that a signal capable of correctly reflecting the states of a tripping protection outlet pressure plate and a reclosing outlet pressure plate is finally output through the steps of acquisition, conversion, judgment and the like on the basis of input voltage signals of lower end connecting columns of the tripping protection outlet pressure plate and the reclosing outlet pressure plate, but the patent technology cannot be applied to monitoring the state of the pressure plate in a loop after an outlet tripping/closing contact point; the chinese invention patent (CN1078085162) proposes to install an external auxiliary contact on a protection outlet pressure plate, and convert the state of the protection outlet pressure plate into the state of the external auxiliary contact through the external auxiliary contact, however, the external auxiliary contact causes the potential fault hazard of the protection device to be increased, and increases the signal acquisition amount and the processing complexity.

Therefore, it is urgently needed to provide an online monitoring device for a protection outlet loop, which can realize effective online monitoring of the protection outlet loop and the state of a pressure plate under the condition that the normal operation of the protection outlet loop is not influenced.

SUMMERY OF THE UTILITY MODEL

In order to solve the defects in the prior art, the utility model aims to provide an online monitoring device for a protection outlet loop, which adopts an electromagnetic isolation technology to access a control loop, effectively monitors the loop behind a trip/closing contact of a protection outlet, and acquires the action state and the pressing plate input state of the protection outlet contact so as to realize early warning and alarm aiming at the abnormal state of the loop.

The utility model adopts the following technical scheme.

A protective outlet circuit on-line monitoring device comprising: the power supply comprises a first current limiting resistor, a second current limiting resistor, a power supply module, a power supply protection fuse, a first relay, a second relay and an electromagnetic isolation sampling module.

The first input end of the electromagnetic isolation sampling module is connected to the near tripping contact end of the pressing plate in an electromagnetic isolation mode.

Preferably, the second and third input terminals of the electromagnetic isolation sampling module are respectively connected with the first current-limiting resistor and the second current-limiting resistor to form a sampling branch.

The power protection fuse is connected with the power module in series to form a power branch.

The sampling branch circuit is connected in parallel with the power supply branch circuit and then connected in series between the positive power supply and the negative power supply of the control bus.

Preferably, the first output end of the electromagnetic isolation sampling module is connected with the input end of the first relay, and the second output end of the electromagnetic isolation sampling module is connected with the input end of the second relay.

Preferably, in the sampling branch, one end of the first current-limiting resistor is connected with the positive power supply of the control bus, and the other end of the first current-limiting resistor is connected with the second input end of the electromagnetic isolation sampling module; one end of the second current-limiting resistor is connected with the negative power supply of the control bus, and the other end of the second current-limiting resistor is connected with the third input end of the electromagnetic isolation sampling module; the shell of the electromagnetic isolation sampling module is provided with a shielding ground end which is directly grounded.

Preferably, in the power branch, one end of the power protection fuse is connected with the positive power supply of the control bus, and the other end of the power protection fuse is connected with one end of the power module; and the other end of the power supply module is connected with a negative power supply of the relay protection control bus.

Preferably, the electromagnetic isolation sampling module comprises: the magnetic sensor comprises a sampling component, a magnetic sensitive element, a first amplifying assembly and a second amplifying assembly.

The first input end of the sampling component is the first input end of the electromagnetic isolation sampling module, the second input end of the sampling component is the second input end of the electromagnetic isolation sampling module, and the third input end of the sampling component is the third input end of the electromagnetic isolation sampling module.

The sampling component is connected with the magnetic sensing element through electromagnetic induction.

The first output end of the magnetic sensing element is connected with the input end of the first amplifying assembly, and the second output end of the magnetic sensing element is connected with the input end of the second amplifying assembly.

The output end of the first amplifying assembly is a first output end of the electromagnetic isolation sampling module, and the output end of the second amplifying assembly is a second output end of the electromagnetic isolation sampling module.

Preferably, when direct currents in different directions pass through the sampling part, direct current magnetic fields generated in the sampling part act on the magnetic sensing element through electromagnetic induction; the magnetic sensing element respectively outputs two paths of signals according to different directions of direct current: the first path of signal is amplified through a first amplifying assembly, and the obtained first driving signal is used for driving a first relay; the second path of amplified signals are amplified through a second amplifying assembly, and the obtained second driving signals are used for driving a second relay.

Preferably, when the potential of the pressing plate near the trip contact end is not zero and is positive, the electromagnetic isolation sampling module sends a first driving signal to the first relay; when the potential of the pressing plate close to the tripping contact point end is not zero and is negative, the electromagnetic isolation sampling module sends a second driving signal to the second relay.

Preferably, the first relay outputs a first remote signaling signal, and the second relay outputs a second remote signaling signal;

according to the first remote signaling signal, the second remote signaling signal and the external auxiliary state information, under the current sampling period, the online monitoring device outputs online monitoring results of the pressing plate input state, the protection outlet loop state and the action behavior of the relay protection device.

Preferably, the external assistance state information includes: the circuit breaker opening and closing state, the manual observation result of the pressing plate state, the action message of the protection device, the remote signaling deflection time of the device and the circuit breaker opening time.

Compared with the prior art, the utility model has the advantages that the action reliability of the relay protection equipment is improved, the protection failure probability caused by the abnormal outlet loop is reduced, meanwhile, the relevant evidence information of the protection outlet condition can be provided for the accident analysis, the accident analysis capability is improved, and the accident responsibility definition can be clearer.

Drawings

FIG. 1 is an electrical schematic wiring diagram of the protection outlet loop on-line monitoring device of the present invention;

wherein the reference numerals are as follows:

+ KM: control bus positive power supply

-KM: control bus negative power supply

1 RD: fuse for controlling bus positive/negative power supply

HJ: reclosing relay outlet contact

LP-H: reclosing pressure plate

TBJ: jumping latching relay

SK: hand-operated control switch

DL 1: auxiliary contact 1 of circuit breaker

HC: closing coil

TWJ: trip position relay

DL 2: auxiliary contact 2 of circuit breaker

TQ: trip coil

HWJ: switching-on position relay

TJ: protection outlet trip contact

LP-T: tripping pressure plate

And (4) Fuse: power protection fuse.

R₁: a first current limiting resistor

R₂: second current limiting resistor

Core: electromagnetic isolation sampling module

Power: power supply module

J1: first relay

J2: second relay

S-group: monitoring device shielding ground

5V-Test: 5V test of monitoring device

D₁-D₁₂: no. 1 to No. 12 terminals in monitoring device

FIG. 2 is a schematic view of the electrical terminals of the on-line monitoring device for the protection outlet circuit of the present invention;

wherein the reference numerals are as follows:

D₁: protection contact end of contact outlet pressure plate

D₂: demarcation hollow terminal

D₃: positive power supply connected with control bus

D₄: connected in parallel to terminal No. 3 (open during test)

D₅: is connected with a negative power supply of the control bus

D₆: parallel to terminal No. 5 (open at test)

D₇: test terminal (for device detection)

D₈: ground of shielding connection

D₉: demarcation hollow terminal

D₁₀: output signal 1 (connecting protection remote signaling 1)

D₁₁: output signal common terminal

D₁₂: output signal 2 (connect protection remote signaling 2)

FIG. 3 is a schematic structural diagram of an electromagnetic isolation sampling module according to the present invention;

FIG. 4 is a flow chart of a method of on-line monitoring of a protection outlet circuit of the present invention;

FIG. 5 is an equivalent circuit diagram of the protection outlet loop on-line monitoring device of the present invention when the pressing plate is reliably put into conduction, the pressing plate rear-stage loop is intact, and the protection outlet loop is in a closing state;

fig. 6 is an equivalent circuit diagram of the protection outlet loop on-line monitoring device of the present invention when the pressure plate is reliably put into conduction and in the open state.

Detailed Description

The present application is further described below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and the protection scope of the present application is not limited thereby.

As shown in the dashed box in fig. 1, an on-line monitoring device for a protection outlet loop is connected in series between a positive power supply + KM and a negative power supply-KM of a control bus, and includes: first current limiting resistor R₁A second current limiting resistor R₂The Power supply comprises a Power module Power, a Power protection Fuse, a first relay J1 and a second relay J2.

The online monitoring device also comprises an electromagnetic isolation sampling module Core; no. 1 terminal D in first input termination detection device of electromagnetic isolation sampling module Core₁The electromagnetic isolation mode is adopted to be connected to the end, close to the tripping contact, of the tripping pressure plate LP-T.

Specifically, the second and third input terminals of the electromagnetic isolation sampling module are respectively connected with the first current-limiting resistor and the second current-limiting resistor to form a sampling branch.

The Power protection Fuse is connected with the Power module Power in series to form a Power branch.

The sampling branch is connected with the power supply branch in parallel and then is connected between a positive power supply + KM and a negative power supply-KM of the control bus in series.

In a preferred embodiment of the utility model, the protection outlet loop online monitoring device can be used for monitoring the state of a protection outlet joint post-stage loop, and the loop state can be represented by the potential condition of a near tripping joint end of the pressure plate LP-T, so that the protection outlet loop online monitoring device is connected to the end point, and various online monitoring results such as the pressure plate switching state, the pressure plate post-stage loop state, the action behavior of the relay protection device and the like can be obtained by monitoring the potential condition of the point and adding external auxiliary state information. In addition, the online monitoring device is connected into the relay protection control circuit in an electromagnetic isolation mode, so that the influence of the self fault of the online monitoring device on the control circuit or the misoperation and the operation rejection caused by the self fault of the online monitoring device can be effectively blocked.

The technical personnel in the field can design the on-line monitoring devices with different circuit structures to be accessed to other arbitrary joints of the protection outlet loop, collect the required signals and obtain various on-line monitoring results including the state of the protection outlet loop through numerical calculation, and it is noted that the utility model concepts that the on-line monitoring devices adopt an electromagnetic isolation mode to realize the access to the arbitrary joints of the protection outlet loop all fall into the protection scope of the utility model.

In the preferred embodiment of the utility model, the first current limiting resistor R₁And a second current limiting resistor R₂The current limiting resistors are high-resistance current limiting resistors, and the resistance values of the current limiting resistors are all larger than 1 MOmega, so that the current flowing through the online monitoring device of the protection outlet loop is smaller than 220 muA, and the normal operation of the control loop cannot be influenced when the online monitoring device of the protection outlet loop is connected into the relay protection control loop.

It should be noted that the first current limiting resistor R can be selected by those skilled in the art according to the engineering application₁And a second current limiting resistor R₂To avoid the generation of normal operation of the on-line monitoring device after the on-line monitoring device is connected into the control loopAdversely, the resistance of the resistor in the preferred embodiment of the utility model is a non-limiting preferred choice.

In particular, in the sampling branch, a first current limiting resistor R₁Is connected to the No. 4 terminal D₄The other end of the control bus is connected with a positive power supply + KM of the control bus, and the second input end of the Core of the electromagnetic isolation sampling module; second current limiting resistor R₂Is connected with the No. 6 terminal D₆The control bus negative power supply-KM is connected, and the other end of the control bus negative power supply-KM is connected with a third Core input end of the electromagnetic isolation sampling module; the shell of the electromagnetic isolation sampling module Core is provided with a shielding ground end which is directly grounded through a No. 7 terminal D₇The leading-out monitoring device is connected with a grounding copper bar of the protection screen cabinet.

In the power branch, one end of the power protection Fuse passes through the No. 3 terminal D₃The leading-out is connected with a positive Power supply + KM of the control bus, and the other end is connected with one end of a Power module Power; the other end of the power supply module is connected with the No. 5 terminal D₅The lead-out is connected with a relay protection control bus negative power supply-KM.

The Power module Power provides a working Power supply for the protection outlet loop on-line monitoring device, and the normal operation of the on-line monitoring device is ensured.

As shown in FIG. 2, the connection of the sampling branch with the power branch and the positive power supply + KM of the control bus is realized through a No. 4 terminal D₄And terminal No. 3D₃The sampling branch is connected with a power branch and a control bus negative power supply-KM through a No. 6 terminal D₆And terminal No. 5D₅The short circuit is realized by adopting the short circuit mode, so that the on-line monitoring device provided by the utility model can realize the electrical connection and disconnection between the sampling branch and the power supply branch when the insulation and voltage resistance test is carried out, and the short circuit mode adopted in the preferred embodiment of the utility model is a non-limiting preferred choice.

As shown in fig. 3, the electromagnetically isolated sampling module Core includes: the magnetic sensor comprises a sampling component, a magnetic sensitive element, a first amplifying assembly and a second amplifying assembly.

The first input end of the sampling component is the first input end of the electromagnetic isolation sampling module, the second input end of the sampling component is the second input end of the electromagnetic isolation sampling module, and the third input end of the sampling component is the third input end of the electromagnetic isolation sampling module.

The sampling component is connected with the magnetic sensing element by electromagnetic induction.

The first output end of the magnetic sensing element is connected with the input end of the first amplifying assembly, and the second output end of the magnetic sensing element is connected with the input end of the second amplifying assembly.

The output end of the first amplifying assembly is a first output end of the electromagnetic isolation sampling module, and the output end of the second amplifying assembly is a second output end of the electromagnetic isolation sampling module.

When direct currents in different directions pass through the sampling component, a direct current magnetic field generated in the sampling component acts on the magnetic sensing element through electromagnetic induction; the magnetic sensing element respectively outputs two paths of signals according to different directions of direct current: the first path of signal is amplified through a first amplifying assembly, and the obtained first driving signal is used for driving a first relay J1; the second path of amplified signal is subjected to signal amplification by a second amplifying assembly, and the obtained second driving signal is used for driving the second relay J2.

Specifically, when the potential of the pressing plate near the tripping contact point end is not zero and is positive, the electromagnetic isolation sampling module sends a first driving signal to the first relay; when the potential of the pressing plate close to the tripping contact point end is not zero and is negative, the electromagnetic isolation sampling module sends a second driving signal to the second relay.

Specifically, the first relay J1 outputs a first telecommand signal, and the second relay J2 outputs a second telecommand signal.

Referring to fig. 4, the steps of an online monitoring method for a protection outlet loop are as follows:

step 1, acquiring the potential and potential polarity of a near tripping contact end of a pressure plate in an electromagnetic isolation mode in a current sampling period; collecting external auxiliary state information; the potential and the potential polarity of the pressure plate near the trip contact end are acquired by an electromagnetic isolation sampling module.

In the preferred embodiment, the external auxiliary status information is obtained by manual observation, presentation of an integrated automation system, and the like.

Specifically, in step 1, external auxiliary status information is obtained by an in-field observation or monitoring system, the external auxiliary status information including: the circuit breaker opening and closing state, the pressing plate state manual observation result and the action message of the relay protection device.

Step 2, when the potential of the near tripping contact end of the pressing plate is not zero, the electromagnetic isolation sampling module respectively sends driving signals to the first relay and the second relay according to the potential polarity of the near tripping contact end of the pressing plate; according to the driving signal, the first relay outputs a first remote signaling signal, and the second relay outputs a second remote signaling signal.

Specifically, step 2 comprises:

when the potential of the pressure plate near the tripping contact point end is not zero and is positive, the electromagnetic isolation sampling module sends a first driving signal to the first relay;

when the potential of the pressing plate close to the tripping contact point end is not zero and is negative, the electromagnetic isolation sampling module sends a second driving signal to the second relay.

In the preferred embodiment, when the voltage of the pressing plate near the trip contact is not zero and has a negative polarity, and the circuit breaker is in a closing state, as shown in fig. 5, the equivalent circuit sequentially includes, in a current direction: positive power supply + KM of control bus and first current limiting resistor R₁The electromagnetic isolation sampling module Core, a pressure plate LP-T, an anti-tripping relay coil TBJ, a normally open auxiliary contact DL of a breaker, a tripping coil TQ and a relay protection control bus negative power supply-KM;

wherein, terminal D₄And terminal D₃The positive power supply + KM of the control bus and the negative power supply-KM of the relay protection control bus are respectively connected with resistors in series.

In the preferred embodiment, when the voltage of the pressing plate near the trip contact is not zero and is positive and the circuit breaker is in the open state, as shown in the equivalent circuit shown in fig. 6, the equivalent circuit sequentially includes, in the current direction: positive power supply + KM of control bus, switching-on position relay coil HWJ, pressure plate LP-T, electromagnetic isolation sampling module Core and second current-limiting resistor R₂And a control bus negative power supply-KM;

wherein, terminal D₆And terminal D₅The positive power supply + KM of the control bus and the negative power supply-KM of the control bus are respectively connected with resistors in series.

And 3, according to the first remote signaling signal, the second remote signaling signal and the external auxiliary state information, under the current sampling period, obtaining the online monitoring results of the pressing plate input state, the protection outlet loop state and the action behavior of the relay protection device.

Specifically, in step 3, when the potential of the pressing plate near the trip contact is not zero, in the current sampling period, the online monitoring results of the pressing plate input state, the protection outlet loop state and the action behavior of the relay protection device are as follows:

(1) when the first remote signaling signal is 1, the second remote signaling signal is 0 and the circuit breaker is in a closing state, the pressing plate is judged to be in a reliable switching-on state, and the protection outlet loop is in a normal state;

(2) when the first remote signaling signal is 0, the second remote signaling signal is 1 and the circuit breaker is in a brake-off state, the pressing plate is judged to be in a reliable switching-on state, and the protection outlet loop is in a normal state;

(3) when the first remote signaling signal is 0 and the second remote signaling signal is 1, and the circuit breaker is in a closing state, and the manual observation result of the pressing plate state is reliable, judging that the pressing plate rear-stage outlet loop is abnormal; (4) when the first remote signaling signal is changed from 1 to 0 and the second remote signaling signal is changed from 0 to 1, the circuit breaker is changed from a closing state to an opening state, and the protection device has an action message, the remote signaling deflection time of the monitoring device is earlier than the opening time of the circuit breaker, the pressing plate is judged to be reliably put in, the protection outlet loop is intact, and the action behavior of the protection device is normal;

(4) when the first remote signaling signal is changed from 1 to 0 and the second remote signaling signal is changed from 0 to 1, the breaker is changed from a closing state to an opening state, and the protection device has no action message, the remote signaling deflection time of the monitoring device is later than the tripping time of the breaker, so that the situation that the pressing plate is reliably put into the breaker can be judged, the protection outlet loop is intact, the breaker body and/or the related loop of the breaker have problems to cause the false tripping of the breaker, but the action behavior of the protection device is normal;

(5) when the first remote signaling signal is changed from 1 to 0 and the second remote signaling signal is changed from 0 to 1, the breaker is changed from a closing state to an opening state, and the protection device has no action outlet message, the remote signaling deflection time of the monitoring device is earlier than the tripping time of the breaker, so that the situation that the pressing plate is reliably put into the breaker can be judged, the protection outlet loop is intact, the breaker is driven by the protection device to open the brake, but the action behavior of the protection device is abnormal;

(6) when the first remote signaling signal is changed from 1 to 0 and the second remote signaling signal is changed from 0 to 1, and the circuit breaker does not act to trip and the protection device has an action message, the pressing plate can be judged to be reliably put into use, the action behavior of the protection device is normal, and the circuit breaker fails to act due to the fact that a problem exists in a subsequent outlet loop and/or a circuit breaker body of the pressing plate.

Specifically, in step 3, the potential of the near-trip contact end of the pressing plate is zero, and in the current sampling period, when the first telecommand signal and the second telecommand signal are both 0 and the circuit breaker is in a closing state, an operation instruction of the pressing plate is obtained, and the online monitoring results of the pressing plate input state, the protection outlet loop state and the action behavior of the relay protection device are as follows:

(1) when the pressing plate operation instruction is required to be put into operation, judging that the pressing plate is in an unreliable put-in conduction state and/or an abnormal state exists in a rear-stage outlet loop of the pressing plate;

(2) and when the operation instruction of the pressure plate is that the operation needs to be quitted, judging that the pressure plate is in a normal quitting opening state.

In particular, the amount of the solvent to be used,

step 3 also includes: and (3) representing the online monitoring result of the state of the protection outlet loop by using the signal lamp state and the color:

(1) when the first remote signaling signal and the second remote signaling signal are both 0, the signal lamp is turned off;

(2) when the first remote signaling signal is 1 and the second remote signaling signal is 0, the signal lamp is lightened and is red, and the circuit breaker is in a closing state;

(3) when the first remote signaling signal is 0 and the second remote signaling signal is 1, the signal lamp is lightened and is green, and the circuit breaker is in an opening state;

(4) when the first remote signaling signal is changed from 1 to 0 and the second remote signaling signal is changed from 0 to 1, the signal lamp is changed from red to green, and the circuit breaker is changed from a closing state to an opening state.

In the preferred embodiment, when the relay protection control circuit operates normally, the on-off state of the outlet pressure plate and whether the outlet circuit is abnormal or not are monitored by the on-line monitoring device for the protection outlet circuit. The online monitoring device can effectively discover the state that the pressing plate is not put into or reliably contacts the pressing plate. If the situation happens, the loop normal indicator lamp of the online monitoring device is in an off state. After the pressing plate is reliably put into use, the indicating lamp of the 'loop normal' is long and bright. When the circuit breaker is in a closing state, the indicator light is red; the indicator light is green when the circuit breaker is in the separating brake state.

The protection outlet loop online monitoring device can display the pressing plate input state on site and can feed back the outlet pressing plate state to the protection device through a protection remote signal. By the definition of the comprehensive system, the state of the pressing plate can be accurately presented on the background monitoring system. The operating personnel can remotely monitor the on-off state of the pressing plate in real time, and the on-off state of the pressing plate can be observed by naked eyes without needing to be in front of a protection screen in the past.

The protection outlet loop online monitoring device can feed the protection action outlet condition back to the protection device through remote signaling, and according to remote signaling deflection, the conditions of tripping of the protection device and/or driving of a tripping coil of an outlet of a non-protection device action and driving of a closing coil of a reclosing outlet can be accurately recorded in the protection device and a monitoring system, so that accident analysis is well documented.

Compared with the prior art, the utility model has the advantages that the action reliability of the relay protection equipment is improved, the protection failure probability caused by the abnormal outlet loop is reduced, meanwhile, the relevant evidence information of the protection outlet condition can be provided for the accident analysis, the accident analysis capability is improved, and the accident responsibility definition can be clearer.

The present applicant has described and illustrated embodiments of the present invention in detail with reference to the accompanying drawings, but it should be understood by those skilled in the art that the above embodiments are merely preferred embodiments of the present invention, and the detailed description is only for the purpose of helping the reader to better understand the spirit of the present invention, and not for limiting the scope of the present invention, and on the contrary, any improvement or modification made based on the spirit of the present invention should fall within the scope of the present invention.

Claims (10)

1. An on-line monitoring device for a protection outlet loop is characterized in that,

the online monitoring device comprises: the power supply comprises a first current limiting resistor, a second current limiting resistor, a power supply module, a power supply protection fuse, a first relay, a second relay and an electromagnetic isolation sampling module;

the first input end of the electromagnetic isolation sampling module is connected to the near tripping contact end of the pressing plate in an electromagnetic isolation mode.

2. The on-line monitoring device for protection outlet loop of claim 1,

the second and third input ends of the electromagnetic isolation sampling module are respectively connected with the first current-limiting resistor and the second current-limiting resistor to form a sampling branch;

the power protection fuse is connected with the power module in series to form a power branch;

the sampling branch circuit is connected in parallel with the power supply branch circuit and then connected in series between the positive power supply and the negative power supply of the control bus.

3. The on-line monitoring device for protection outlet loop of claim 1,

the first output end of the electromagnetic isolation sampling module is connected with the input end of the first relay, and the second output end of the electromagnetic isolation sampling module is connected with the input end of the second relay.

4. The on-line monitoring device for protection outlet loop of claim 2,

in the sampling branch, one end of a first current-limiting resistor is connected with a positive power supply of a control bus, and the other end of the first current-limiting resistor is connected with a second input end of the electromagnetic isolation sampling module; one end of the second current-limiting resistor is connected with the negative power supply of the control bus, and the other end of the second current-limiting resistor is connected with the third input end of the electromagnetic isolation sampling module; the shell of the electromagnetic isolation sampling module is provided with a shielding ground end which is directly grounded.

5. The on-line monitoring device for protection outlet loop of claim 2,

in the power supply branch, one end of a power supply protection fuse is connected with a positive power supply of a control bus, and the other end of the power supply protection fuse is connected with one end of a power supply module; and the other end of the power supply module is connected with a negative power supply of the relay protection control bus.

6. A protection outlet circuit on-line monitoring device according to any one of claims 1 to 5,

the electromagnetic isolation sampling module comprises: the magnetic sensor comprises a sampling component, a magnetic sensitive element, a first amplifying assembly and a second amplifying assembly;

the first input end of the sampling component is the first input end of the electromagnetic isolation sampling module, the second input end of the sampling component is the second input end of the electromagnetic isolation sampling module, and the third input end of the sampling component is the third input end of the electromagnetic isolation sampling module;

the sampling component is connected with the magnetic sensing element through electromagnetic induction;

the first output end of the magnetic sensing element is connected with the input end of the first amplification component, and the second output end of the magnetic sensing element is connected with the input end of the second amplification component;

the output end of the first amplifying assembly is a first output end of the electromagnetic isolation sampling module, and the output end of the second amplifying assembly is a second output end of the electromagnetic isolation sampling module.

7. The on-line monitoring device for protection outlet circuit of claim 6,

when direct currents in different directions pass through the sampling component, a direct current magnetic field generated in the sampling component acts on the magnetic sensing element through electromagnetic induction; the magnetic sensing element respectively outputs two paths of signals according to different directions of direct current: the first path of signal is amplified through a first amplifying assembly, and the obtained first driving signal is used for driving a first relay; the second path of amplified signals are amplified through a second amplifying assembly, and the obtained second driving signals are used for driving a second relay.

8. The on-line monitoring device for protection outlet circuit of claim 7,

when the potential of the pressure plate near the tripping contact point end is not zero and is positive, the electromagnetic isolation sampling module sends a first driving signal to the first relay;

when the potential of the pressing plate close to the tripping contact point end is not zero and is negative, the electromagnetic isolation sampling module sends a second driving signal to the second relay.

9. The on-line monitoring device for protection outlet circuit of claim 7,

the first relay outputs a first remote signaling signal, and the second relay outputs a second remote signaling signal;

according to the first remote signaling signal, the second remote signaling signal and the external auxiliary state information, under the current sampling period, the online monitoring device outputs online monitoring results of the pressing plate input state, the protection outlet loop state and the action behavior of the relay protection device.

10. The on-line monitoring device for protection outlet circuit of claim 9,

the external assistance state information includes: the circuit breaker opening and closing state, the manual observation result of the pressing plate state, the action message of the protection device, the remote signaling deflection time of the device and the circuit breaker opening time.

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