CN216981192U - Switch board of intelligent operation - Google Patents

Abstract

The utility model discloses an intelligently operated power distribution cabinet which comprises a cabinet body, a bus bar, a switch assembly and a heat dissipation assembly, wherein the switch assembly is arranged in the cabinet body, the top of the cabinet body is provided with a vent, the heat dissipation assembly is arranged above the vent, the bus bar penetrates through the left side and the right side of the cabinet body, the switch assembly comprises a touch display screen, a circuit breaker and a current transformer, the touch display screen and the circuit breaker are vertically arranged on the cabinet body, the bus bar is connected with the circuit breaker, the current transformer is used for detecting the current value of the output end of the circuit breaker, and a secondary circuit of the circuit breaker and the current transformer are electrically connected with the touch display screen. The touch display screen is arranged on the outer side of the cabinet body, the opening and closing states of the breaker and the current conditions of the bus bars are displayed in real time, and intelligent operation is achieved.

Description

Switch board of intelligent operation

Technical Field

The utility model relates to the field of power distribution equipment, in particular to an intelligently operated power distribution cabinet.

Background

Along with the development of distribution technology, intelligent power distribution cabinet's application is also more and more extensive, is often used for occasions such as building, market and transformer substation, is convenient for acquire the electric power condition in real time, realizes intelligent protection and measurement etc. of distribution circuit. However, in the existing intelligent power distribution cabinet, devices such as a detection element need to be arranged in the cabinet body, and the requirements of electrical clearance and creepage distance need to be met, so that the cabinet body is oversize, the manufacturing cost is high, and the intelligent power distribution cabinet is difficult to be applied to occasions with limited installation space.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an intelligently operated power distribution cabinet to solve one or more technical problems in the background technology.

In order to achieve the purpose, the utility model adopts the following technical scheme:

the utility model provides a switch board of intelligent operation, includes the cabinet body, generating line row, switch module and radiator unit, switch module establishes the cabinet is internal, the vent has been seted up at the top of the cabinet body, radiator unit establishes the top of vent, the generating line row passes the left and right sides of the cabinet body, switch module includes touch display screen, circuit breaker and current transformer, touch display screen with the circuit breaker sets up from top to bottom on the cabinet body, the generating line row with the circuit breaker is connected, current transformer is used for detecting the current value of circuit breaker output, the secondary circuit of circuit breaker with current transformer all with the touch display screen electricity is connected.

Preferably, radiator unit includes radiator box, radiator fan and temperature sensor, the radiator box is established the top of the cabinet body, radiator fan establishes in the radiator box, temperature sensor establishes vent department, radiator fan's speed governing end with temperature sensor all with touch display screen electricity is connected.

Preferably, the heat dissipation assembly further comprises a movable bottom plate, a box door is hinged to the front side of the heat dissipation box body, the heat dissipation fan is arranged on the movable bottom plate, and the movable bottom plate is in sliding fit with the inner side of the heat dissipation box body.

Preferably, the air-conditioning cabinet further comprises an air inlet grid and an air outlet grid, the air inlet grid is arranged at the bottom of the front side of the cabinet body, and the air outlet is provided with the air outlet grid.

Preferably, still include the dehumidification subassembly, the dehumidification subassembly includes humidity transducer and dehumidifier, the inlet end of dehumidifier with the inboard intercommunication of grid admits air, the exhaust end of dehumidifier is established it is internal that the cabinet, humidity transducer establishes the below of circuit breaker.

Preferably, the breaker further comprises a first sub copper bar group and a second sub copper bar group, wherein one end of the first sub copper bar group is connected with one end of the bus bar, and the other end of the first sub copper bar group is connected with the input end of the breaker; one end of the second sub copper bar group is connected with the other end of the bus bar, and the other end of the second sub copper bar group is connected with one end of the circuit breaker.

Preferably, the current transformer is sleeved outside the second sub-copper bar group.

Preferably, the cabinet body further comprises an insulator, and the first sub-copper bar group and the second sub-copper bar group are respectively connected with the cabinet body through the insulator.

The beneficial effects of the utility model are as follows: the intelligent cabinet is provided with the touch display screen on the outer side of the cabinet body, the opening and closing states of the circuit breaker and the current conditions of the bus bars are displayed in real time, and intelligent operation is achieved. Simultaneously, the setting is established radiator unit in the top of the cabinet body, and radiator unit discharges the internal hot-air of cabinet through establishing the vent in cabinet body top to play radiating effect, avoid the internal local temperature of cabinet to overheat and lead to influencing generating line row and switch module's normal work.

Drawings

The drawings are further illustrative of the utility model and the content of the drawings does not constitute any limitation of the utility model.

FIG. 1 is a schematic overall structure of one embodiment of the present invention;

fig. 2 is a schematic diagram of the internal structure of one embodiment of the present invention.

Wherein: the cabinet body 1, the bus bar 2, the vent 11, the heat dissipation assembly 4, the touch display screen 31, the circuit breaker 32, the current transformer 33, the heat dissipation box body 41, the heat dissipation fan 42, the temperature sensor 43, the movable bottom plate 44, the box door 45, the air inlet grid 12, the exhaust screen 13, the humidity sensor 51, the dehumidifier 52, the first sub-copper bar group 61, the second sub-copper bar group 62 and the insulator 63.

Detailed Description

The technical scheme of the utility model is further explained by the specific implementation mode in combination with the attached drawings.

The switch board of intelligent operation of this embodiment, refer to figures 1 and 2, including the cabinet body 1, 2 are arranged to the generating line, switch module and radiator unit 4, switch module establishes at cabinet body 1, vent 11 has been seted up at cabinet body 1's top, radiator unit 4 establishes the top at vent 11, 2 left and right sides that pass the cabinet body 1 are arranged to the generating line, switch module includes touch display screen 31, circuit breaker 32 and current transformer 33, touch display screen 31 and circuit breaker 32 set up on cabinet body 1 from top to bottom, 2 are arranged with circuit breaker 32 to the generating line, current transformer 33 is used for detecting the current value of circuit breaker 32 output, the secondary circuit and the current transformer 33 of circuit breaker 32 all are connected with touch display screen 31 electricity.

This embodiment is provided with touch display screen 31 in the outside of the cabinet body 1, the cabinet body 1 of this embodiment is the low-voltage incoming line cabinet, through the collection of current value between current transformer 33 to circuit breaker 32 output to bus bar 2, thereby show the real-time value of bus current value and voltage value on touch display screen 31, combine circuit breaker 32's operating condition, can show circuit breaker 32 separating brake combined state and bus bar 2's current situation on touch display screen 31 in real time from this, when the cabinet door of the cabinet body 1 is opened, through the travel switch that cabinet door department set up, touch display screen 31 still can show that the cabinet body 1 is the maintenance state at present, the intelligent operation of low-voltage distribution cabinet incoming line has been realized. Simultaneously, the setting is established radiator unit 4 in the top of the cabinet body 1, and radiator unit 4 is discharged the hot-air in the cabinet body 1 through establishing vent 11 in cabinet body 1 top to play radiating effect, avoid the interior overheat normal work that leads to influencing generating line row 2 and switch module of local temperature of the cabinet body 1. Heat dissipation assembly 4 establishes in the top of the cabinet body 1 for heat dissipation assembly 4 and generating line arrange 2 between alternate certain distance, thereby satisfied the requirement of electric clearance and creepage distance.

Preferably, the heat dissipation assembly 4 includes a heat dissipation case 41, a heat dissipation fan 42 and a temperature sensor 43, the heat dissipation case 41 is disposed at the top of the cabinet 1, the heat dissipation fan 42 is disposed in the heat dissipation case 41, the temperature sensor 43 is disposed at the ventilation opening 11, and both the speed regulation end of the heat dissipation fan 42 and the temperature sensor 43 are electrically connected to the touch display screen 31. The heating of the incoming line cabinet is mainly caused by the bus bar 2, so that the ventilation opening 11 is arranged above the bus bar 2 to timely exhaust heat generated by the bus bar 2, the temperature sensor 43 is arranged at the ventilation opening 11 to obtain the heat productivity of the bus bar 2, the real-time temperature is displayed through the touch display screen 31, and the intelligent operation of the low-voltage incoming line power distribution cabinet is realized; the rotation speed of the heat dissipation fan 42 can also be adjusted by the real-time temperature, thereby improving the heat dissipation efficiency.

Preferably, the heat dissipation assembly 4 further includes a movable bottom plate 44, a door 45 is hinged to the front side of the heat dissipation box 41, the heat dissipation fan 42 is disposed on the movable bottom plate 44, and the movable bottom plate 44 is in sliding fit with the inner side of the heat dissipation box 41. The door 45 is hinged to the front side of the heat dissipation box 41, so that the heat dissipation fan 42 can be conveniently taken out through the movable bottom plate 44 during maintenance, the heat dissipation fan 42 is cleaned, and the problem that the heat dissipation efficiency of the heat dissipation fan 42 is reduced due to the accumulation of more dust is avoided.

Preferably, the air-conditioning cabinet also comprises an air inlet grid 12 and an air outlet grid 13, wherein the air inlet grid 12 is arranged at the bottom of the front side of the cabinet body 1, and the air outlet grid 13 is arranged at the air vent 11. The air inlet grid 12 is arranged at the bottom of the cabinet body 1, so that cold air enters, hot air flowing is facilitated, and air circulation is accelerated. The vent 11 is provided with an exhaust screen 13 to prevent impurities from falling off and damaging the bus bar 2 when the heat dissipation fan 42 is maintained.

Preferably, the air conditioner further comprises a dehumidifying assembly, wherein the dehumidifying assembly comprises a humidity sensor 51 and a dehumidifier 52, an air inlet end of the dehumidifier 52 is communicated with the inner side of the air inlet grid 12, an air outlet end of the dehumidifier 52 is arranged in the cabinet body 1, the humidity sensor 51 is arranged below the circuit breaker 32 to acquire the humidity in cold air entering from the air inlet grid 12 at the bottom of the cabinet body 1, and if the humidity exceeds a set value, the dehumidifier 52 is controlled to start to work. The dehumidifier 52 of the present embodiment employs a condensation dehumidifier 52 to dry the air in the cabinet 1. The humidity value obtained by the humidity sensor 51 can be displayed on the touch display screen 31 in real time, so that the intelligent operation of the power distribution cabinet is realized.

Preferably, the power supply further comprises a first sub-copper bar group 61 and a second sub-copper bar group 62, wherein one end of the first sub-copper bar group 61 is connected with one end of the bus bar 2, and the other end of the first sub-copper bar group 61 is connected with the input end of the circuit breaker 32; one end of the second sub copper bar group 62 is connected with the other end of the bus bar 2, and the other end of the second sub copper bar group 62 is connected with one end of the circuit breaker 32. Thus, the first sub-copper bar group 61 and the second sub-copper bar group 62 are respectively used for realizing the connection of the bus bar 2 with the input end and the output end of the circuit breaker 32.

Preferably, the current transformer 33 is sleeved outside the second copper busbar set 62. Therefore, real-time detection of the current value at the output end of the circuit breaker 32 is realized.

Preferably, the cabinet further comprises an insulator 63, and the first sub-copper row group 61 and the second sub-copper row group 62 are respectively connected with the cabinet 1 through the insulator 63. The first sub copper row group 61 and the second sub copper row group 62 are fixed.

The technical principle of the present invention is described above in connection with specific embodiments. The description is made for the purpose of illustrating the principles of the utility model and should not be construed in any way as limiting the scope of the utility model. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive effort, which would fall within the scope of the present invention.

Claims (8)

1. The utility model provides a switch board of intelligent operation, its characterized in that, includes the cabinet body, generating line row, switch module and radiator unit, switch module establishes the cabinet is internal, the vent has been seted up at the top of the cabinet body, radiator unit establishes the top of vent, the generating line row passes the left and right sides of the cabinet body, switch module includes touch display screen, circuit breaker and current transformer, touch display screen with the circuit breaker sets up from top to bottom on the cabinet body, the generating line row with the circuit breaker is connected, current transformer is used for detecting the current value of circuit breaker output, the secondary circuit of circuit breaker with current transformer all with the touch display screen electricity is connected.

2. The intelligently operated power distribution cabinet according to claim 1, wherein the heat dissipation assembly comprises a heat dissipation box body, a heat dissipation fan and a temperature sensor, the heat dissipation box body is arranged at the top of the cabinet body, the heat dissipation fan is arranged in the heat dissipation box body, the temperature sensor is arranged at the vent, and the speed regulation end of the heat dissipation fan and the temperature sensor are electrically connected with the touch display screen.

3. The intelligently operated power distribution cabinet according to claim 2, wherein the heat dissipation assembly further comprises a movable bottom plate, a cabinet door is hinged to the front side of the heat dissipation cabinet body, the heat dissipation fan is arranged on the movable bottom plate, and the movable bottom plate is in sliding fit with the inner side of the heat dissipation cabinet body.

4. The intelligently operated power distribution cabinet according to claim 1, further comprising an air inlet grid and an air outlet grid, wherein the air inlet grid is arranged at the bottom of the front side of the cabinet body, and the air outlet is provided with the air outlet grid.

5. The intelligently operated power distribution cabinet according to claim 4, further comprising a dehumidification assembly, wherein the dehumidification assembly comprises a humidity sensor and a dehumidifier, an air inlet end of the dehumidifier is communicated with an inner side of the air inlet grid, an air outlet end of the dehumidifier is arranged in the cabinet body, and the humidity sensor is arranged below the circuit breaker.

6. The intelligently operated power distribution cabinet according to claim 1, further comprising a first sub-copper bar group and a second sub-copper bar group, wherein one end of the first sub-copper bar group is connected with one end of the bus bar, and the other end of the first sub-copper bar group is connected with an input end of the circuit breaker; one end of the second sub copper bar group is connected with the other end of the bus bar, and the other end of the second sub copper bar group is connected with one end of the circuit breaker.

7. The intelligently operated power distribution cabinet according to claim 6, wherein the current transformer is sleeved outside the second copper busbar set.

8. The intelligently operated power distribution cabinet according to claim 6, further comprising an insulator, wherein the first sub copper row group and the second sub copper row group are respectively connected with the cabinet body through the insulator.

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