CN219041468U - Synchronous switch controller based on new energy special line is sent out - Google Patents

Abstract

A synchronous switch controller based on new energy special line is sent out, its characterized in that: the high-voltage power supply 1 is connected with the vacuum isolation switch 2, and comprises a driving motor 3 connected with the vacuum switch M1, a voltage transformer 4 connected with the vacuum switch M1, a motor driving control bus 5, a current sensor 6 connected with the vacuum switch M1, a current parameter output bus 7 connected with the vacuum switch M1, a high-voltage output end 8 connected with the vacuum isolation switch M1, a lightning protection component 36 connected with the high-voltage output end 8 connected with the vacuum isolation switch M1, and a TFT display screen 38 for displaying data; the power network optical fiber communication port (40) and the power network communication indicator lamp (48) are connected with the novel power network system communication port and act on the communication of synchronous on-off and scheduling management of power transmission and distribution of the novel power network system and energy conservation of a power utilization station area; the H1 infrared detector (42), the H2 infrared detector (43), the H3 infrared detector (44) and the H4 infrared detector (45) are used for remotely monitoring and transmitting the temperature of the power component.

Description

Synchronous switch controller based on new energy special line is sent out

Technical Field

The utility model relates to the field of a synchronous switch controller based on new energy dedicated line delivery, which is one of the technical schemes for changing the energy saving of new energy dedicated line delivery and is suitable for the novel energy saving management of a power grid system network and is high in efficiency.

Background

At present, the existing and commercial isolating switch and controller are single-body manual or automatic isolating switch and controller, and the defects are that: the power distribution system is not suitable for a novel power grid multi-loop and flexible direct current power supply system synchronous closed and separated power distribution system.

Disclosure of Invention

In order to overcome the defects, the utility model provides a synchronous switch controller based on the transmission of a new energy dedicated line. The technology of synchronous closing and separating power distribution of the digital novel power network multi-loop power transmission and distribution and the flexible direct current power supply system is used as a core, and the system is suitable for energy-saving network management of power transmission and distribution and power utilization station areas of the novel power network system.

A synchronous switch controller based on new energy special line is sent out, its characterized in that: the high-voltage power supply is connected with the vacuum isolation switch and comprises a vacuum switch driving motor, a voltage transformer, a motor driving control bus, a current sensor, a current parameter output bus, a high-voltage output end, a low-voltage output power supply, a low-voltage current transformation and driving assembly and an MCM processor, wherein the MCM processor sends an instruction to close and separate the vacuum isolation switch; the motor drive control bus, the current parameter output bus, the low-voltage conversion and drive assembly are connected with the MCM processor, and the motor drive control bus, the current parameter output bus, the low-voltage conversion and drive assembly comprise a high-voltage power supply, a vacuum isolation switch, a vacuum switch drive motor, a voltage transformer, a current sensor, a high-voltage output end and a low-voltage output power supply, and the MCM processor sends instructions to close and separate the vacuum isolation switch; the motor drive control bus, the current parameter output bus and the low-voltage converting and driving assembly are connected with the MCM processor, and the motor drive control bus, the current parameter output bus and the low-voltage converting and driving assembly comprise a high-voltage power supply, a vacuum isolating switch, a vacuum switch driving motor, a voltage transformer, a current sensor, a high-voltage output end and a low-voltage output power supply, and the MCM processor sends an instruction to close and separate the vacuum isolating switch; the motor drive control bus, the current parameter output bus and the low-voltage converting and driving assembly are connected with the MCM processor, and the motor drive control bus, the current parameter output bus and the low-voltage converting and driving assembly comprise a high-voltage power supply, a vacuum isolating switch, a vacuum switch driving motor, a voltage transformer, a current sensor, a high-voltage output end and a low-voltage output power supply, and the MCM processor sends an instruction to close and separate the vacuum isolating switch; the high-voltage output end is connected with the lightning protection component and comprises four paths of high-voltage output ends which are connected with the lightning protection component and act on high-voltage delivery and lightning protection.

The MCM processor is connected with the button switch and the automatic/manual change-over switch, and comprises a TFT display screen, a storage battery pack, a power network optical fiber communication port, an intranet communication port, an H1 infrared detector, an H2 infrared detector, an H3 infrared detector, an H4 infrared detector, a high-voltage output double-color working state indication screen, a power network communication indication lamp and an intranet communication indication lamp; the four-way vacuum isolating switch is used for automatically closing and separating the vacuum isolating switch synchronously or manually; the TFT display screen displays data, and the storage battery pack is an uninterrupted working power supply; the power network optical fiber communication port and the power network communication indicator lamp are connected with the novel power network system communication port, act on the synchronous switching on and switching off of the novel power network system transmission and distribution and energy saving of a power utilization station area and the communication of scheduling management, and the intranet communication port and the intranet communication indicator lamp are connected with the intelligent micro-grid and are used for the communication of power supply scheduling and management; the temperature of the power component is remotely monitored and transmitted by the H1 infrared detector, the H2 infrared detector, the H3 infrared detector and the H4 infrared detector; the device also comprises a high-voltage sending out double-color working state indicating screen, wherein green indicates normal working and red indicates faults.

The utility model provides a synchronous switch controller host computer rack based on new forms of energy private line is sent, includes H1 infrared detector socket, H2 infrared detector socket, H3 infrared detector socket, H4 infrared detector socket, still includes wired network cable connection socket, all installs in the bottom of a synchronous switch controller host computer rack based on new forms of energy private line is sent for insert H1 infrared detector, H2 infrared detector, H3 infrared detector, H4 infrared detector, still include automatic/manual change over switch, embed in automatic/manual switch change over pull rod.

The wired network remote controller shell panel is characterized in that a wired network cable outlet pipe is connected with a wired network cable connection socket of a synchronous switch controller host machine cabinet based on the transmission of a new energy dedicated line; the high-voltage dual-color working state indicating screen, the TFT display screen, the power grid communication indicating lamp, the button switch of the intranet communication indicating lamp and the storage battery are respectively arranged in a mounting hole of the high-voltage dual-color working state indicating screen, a mounting hole of the TFT display screen, a mounting hole of the power grid communication indicating lamp, a mounting hole of the intranet communication indicating lamp, a mounting hole of the button switch and a mounting window of the storage battery.

The synchronous switch controller based on new energy special line delivery has the beneficial effects that: the system is suitable for synchronous closing and separating distribution of new energy sources of a digital novel power grid multi-loop and flexible direct current power supply system, and is suitable for energy-saving network management of power transmission and distribution and station utilization areas of the novel power grid system.

Drawings

The utility model will be further described with reference to the drawings and examples.

Fig. 1 is an electrical schematic of the present utility model.

Fig. 2 is a host cabinet based on a synchronous switch controller sent out by a new energy dedicated line.

Fig. 3 is a wired network remote control housing panel of the present utility model.

And a No. 1.1 high-voltage power supply in the drawing. And 2.1 a vacuum isolating switch. And 3, driving a motor by an M1 vacuum switch. And 4.1. A voltage transformer. 5. A motor drive control bus. 6.1 current sensor. 7. And a current parameter output bus. And the No. 1 high-voltage output end. And 9.1 a low-voltage output power supply. 10. Low voltage variable flow and drive assembly. Mcm processor. 12.2 high voltage power supply. 13.2 vacuum isolating switch. And (3) driving a motor by an M2 vacuum switch. 15.2. A current sensor No. 16.2. 17.2 high voltage output terminal. And 18.2 a low-voltage output power supply. 19.3 high voltage power supply. And a vacuum isolating switch No. 20.3. And 3. M3 vacuum switch driving motor. 22.3 voltage transformer. 23.3 current sensor. 24.3 high voltage output terminal. 25.3 low voltage output power supply. 26.4 high voltage power supply. And a No. 27.4 vacuum isolation switch. An m4 vacuum switch drive motor. 29.4. 30.4 current sensor. And a No. 31.4 high voltage output end. 32.4 low voltage output power supply. 33.4 lightning protection component. 34.3 lightning protection component. And a No. 2 lightning protection component. And a No. 36.1 lightning protection component. K1, K2, K3, K4 push button switch. Tft display screen. 39. And a storage battery. 40. And an optical fiber communication port of the power network. 41. And an intranet communication port. H1 infrared detector. An h2 infrared detector. An h3 infrared detector. An h4 infrared detector. 46. And high-pressure sending out a double-color working state indicating screen. K5 automatic/manual transfer switch. 48. The power network communication indicator lamp. 49. An intranet communication indicator lamp. 50. A synchronous switch controller host machine cabinet based on new energy special line sending. H1 infrared detector 42 receptacle. H2 infrared detector 43 socket. H3 infrared detector 44 receptacle. An h4 infrared detector 45 socket. K5 automatic/manual switch 47 switches the pull rod. 56. The cable network cable connection socket. 57. A wired network remote control housing panel. 58. The high pressure is sent out of the mounting hole of the two-color operation state indicating screen 46. Tft display screen 38 mounting holes. 60. And the power network communication indicator lamp 48 is arranged in the hole. 61. And an intranet communication indicator lamp 49 is arranged in the mounting hole. K1, K2, K3, K4 button switch 37 mounting holes. 63. The battery pack 39 mounts a window. 64. And a cable outlet pipe of the wired network.

Detailed Description

In the drawing, a No. 1 high-voltage power supply 1 is connected with a No. 1 vacuum isolation switch 2, and comprises a connection M1 vacuum switch driving motor 3, a No. 1 voltage transformer 4, a motor driving control bus 5, a No. 1 current sensor 6, a current parameter output bus 7, a No. 1 high-voltage output end 8, a connection No. 1 low-voltage output power supply 9, a low-voltage current-transformation and driving assembly 10 and an MCM processor 11, wherein the MCM processor 11 sends an instruction, and the No. 1 vacuum isolation switch 2 is closed and separated; the motor drive control bus 5, the current parameter output bus 7, the low-voltage conversion and drive assembly 10 are connected with the MCM processor 11, and comprise a No. 2 high-voltage power supply 12 connected with a No. 2 vacuum isolation switch 13, and also comprise a No. 2 vacuum switch drive motor 14, a No. 2 voltage transformer 15, a No. 2 current sensor 16, a No. 2 high-voltage output end 17 and a No. 2 low-voltage output power supply 18 which are connected, wherein the MCM processor 11 sends instructions to close and separate the No. 2 vacuum isolation switch 13; the motor drive control bus 5, the current parameter output bus 7 and the low-voltage conversion and drive assembly 10 are connected with the MCM processor 11, and comprise a No. 3 high-voltage power supply 19, a No. 3 vacuum isolation switch 20, an M3 vacuum switch drive motor 21, a No. 3 voltage transformer 22, a No. 3 current sensor 23, a No. 3 high-voltage output end 24 and a No. 3 low-voltage output power supply 25, wherein the MCM processor 11 sends instructions to close and separate the No. 3 vacuum isolation switch 20; the motor drive control bus 5, the current parameter output bus 7 and the low-voltage conversion and drive assembly 10 are connected with the MCM processor 11, and comprise a No. 4 high-voltage power supply 26, a No. 4 vacuum isolation switch 27, an M4 vacuum switch drive motor 28, a No. 4 voltage transformer 29, a No. 4 current sensor 30, a No. 4 high-voltage output end 31 and a No. 4 low-voltage output power supply 32, wherein the MCM processor 11 sends instructions to close and separate the No. 4 vacuum isolation switch 27.

In the drawing, a No. 4 high-voltage output end 31 is connected with a No. 4 lightning protection assembly 33, a No. 3 high-voltage output end 24 is connected with a No. 3 lightning protection assembly 34, a No. 2 high-voltage output end 17 is connected with a No. 2 lightning protection assembly 35, a No. 1 high-voltage output end 8 is connected with a No. 1 lightning protection assembly 36, and the high-voltage output and lightning protection assembly is acted.

In the drawing, an MCM processor 11 is connected to a K1, K2, K3, K4 button switch 37 and a K5 automatic/manual change-over switch 47, and includes a TFT display 38, a battery pack 39, a power network optical fiber communication port 40, an intranet communication port 41, an H1 infrared detector 42, an H2 infrared detector 43, an H3 infrared detector 44, an H4 infrared detector 45, a high-voltage output two-color operating state indicator 46, a power network communication indicator 48 and an intranet communication indicator 49; the K1, K2, K3, K4 button switches 37 and the K5 automatic/manual change-over switch 47 are used for automatically closing and separating the NO. 1 vacuum isolation switch 2, the NO. 2 vacuum isolation switch 13, the NO. 3 vacuum isolation switch 20 and the NO. 4 vacuum isolation switch 27 synchronously or manually; the TFT display screen 38 displays data, and the storage battery pack 39 is an uninterrupted working power supply; the power network optical fiber communication port 40 and the power network communication indicator lamp 48 are connected with the novel power network system communication port and used for the communication of synchronous on-off and scheduling management of power transmission and distribution of the novel power network system and energy conservation of a power utilization station area, and the intranet communication port 41 and the intranet communication indicator lamp 49 are connected with the intelligent micro-grid and used for the communication of power supply scheduling and management; the H1 infrared detector 42, the H2 infrared detector 43, the H3 infrared detector 44 and the H4 infrared detector 45 are used for remotely monitoring and transmitting the temperature of the power components; the high voltage is sent out of the two-color operating condition indicating screen 46, green indicating normal operation and red indicating failure.

In the drawings, an H1 infrared detector 42 socket 51, an H2 infrared detector 43 socket 52, an H3 infrared detector 44 socket 53 and an H4 infrared detector 45 socket 54 comprise a wired network cable connection socket 56 which are all arranged at the bottom of a synchronous switch controller host machine cabinet 50 sent out based on a new energy special line and used for inserting the H1 infrared detector 42, the H2 infrared detector 43, the H3 infrared detector 44 and the H4 infrared detector 45, and further comprise a K5 automatic/manual change-over switch 47 and are embedded in a K5 automatic/manual switch change-over pull rod 55.

A wired network remote controller housing panel 57 in the drawing, wherein a wired network cable outlet pipe 64 is connected with a wired network cable connection socket 56 of a synchronous switch controller host cabinet 50 based on the transmission of new energy dedicated lines, and is used for data setting and function operation; the high-voltage output double-color operation state indication screen 46, the TFT display screen 38, the power grid communication indication lamp 48, the intranet communication indication lamps 49, the K1, the K2, the K3, the K4 button switches 37 and the storage battery 39 are respectively arranged in a high-voltage output double-color operation state indication screen mounting hole 58, a TFT display screen mounting hole 59, a power grid communication indication lamp mounting hole 60, an intranet communication indication lamp mounting hole 61, the K1, the K2, the K3, the K4 button switch mounting hole 62 and a storage battery mounting window 63 of the wired network remote controller housing panel 57.

Claims (4)

1. A synchronous switch controller based on new energy special line is sent out, its characterized in that: the high-voltage power supply 1 is connected with the vacuum isolation switch 2, and comprises a driving motor 3 for connecting the vacuum switch 3, a voltage transformer 4, a motor driving control bus 5, a current sensor 6, a current parameter output bus 7 and a high-voltage output end 8, and also comprises a low-voltage output power supply 9, a low-voltage converting and driving assembly 10 and an MCM processor 11, wherein the MCM processor 11 sends instructions to close and separate the vacuum isolation switch 2; the motor drive control bus (5), the current parameter output bus (7), the low-voltage conversion and drive assembly (10) are connected with the MCM processor (11), and the motor drive control bus comprises a No. 2 high-voltage power supply (12) connected with a No. 2 vacuum isolation switch (13), and also comprises a drive motor (14) connected with the M2 vacuum switch, a No. 2 voltage transformer (15), a No. 2 current sensor (16), a No. 2 high-voltage output end (17) and a No. 2 low-voltage output power supply (18), wherein the MCM processor (11) sends an instruction, and the No. 2 vacuum isolation switch (13) is closed and separated; the motor drive control bus (5), the current parameter output bus (7), the low-voltage conversion and drive assembly (10) are connected with the MCM processor (11), and comprise a No. 3 high-voltage power supply (19) connected with a No. 3 vacuum isolating switch (20), an M3 vacuum switch drive motor (21), a No. 3 voltage transformer (22), a No. 3 current sensor (23), a No. 3 high-voltage output end (24) and a No. 3 low-voltage output power supply (25), and the MCM processor (11) sends instructions to close and separate the No. 3 vacuum isolating switch (20); the motor drive control bus (5), the current parameter output bus (7), the low-voltage conversion and drive assembly (10) are connected with the MCM processor (11), and comprise a No. 4 high-voltage power supply (26) and a No. 4 vacuum isolating switch (27), an M4 vacuum switch drive motor (28), a No. 4 voltage transformer (29), a No. 4 current sensor (30), a No. 4 high-voltage output end (31) and a No. 4 low-voltage output power supply (32), wherein the MCM processor (11) sends an instruction, and the No. 4 vacuum isolating switch (27) is closed and separated; the lightning protection device is characterized in that the No. 4 high-voltage output end (31) is connected with the No. 4 lightning protection component (33), the No. 3 high-voltage output end (24) is connected with the No. 3 lightning protection component (34), the No. 2 high-voltage output end (17) is connected with the No. 2 lightning protection component (35), the No. 1 high-voltage output end (8) is connected with the No. 1 lightning protection component (36), and the lightning protection device acts on high-voltage output and lightning protection.

2. The synchronous switch controller based on new energy special line sending out according to claim 1, wherein the MCM processor (11) is connected with the K1, K2, K3 and K4 button switches (37) and the K5 automatic/manual change-over switch (47) and comprises a TFT display screen (38), a storage battery pack (39), a power grid optical fiber communication port (40), an intranet communication port (41), an H1 infrared detector (42), an H2 infrared detector (43), an H3 infrared detector (44), an H4 infrared detector (45), a high-voltage sending-out double-color working state indication screen (46), a power grid communication indication lamp (48) and an intranet communication indication lamp (49); the K1, K2, K3 and K4 button switches (37) and the K5 automatic/manual change-over switch (47) act on automatically closing or manually closing and separating a No. 1 vacuum isolating switch (2), a No. 2 vacuum isolating switch (13), a No. 3 vacuum isolating switch (20) and a No. 4 vacuum isolating switch (27), a TFT display screen (38) displays data, a storage battery pack (39) is an uninterrupted working power supply, a power network optical fiber communication port (40) and a power network communication indicating lamp (48) are connected with a novel power network system communication port, act on the connection of a synchronous switch, a switch and scheduling management of the novel power network system power transmission and distribution and a radio station area energy conservation, and an intranet communication port (41) and an intranet communication indicating lamp (49) are connected with an intelligent micro-grid for connection of power supply scheduling and management; the device comprises an H1 infrared detector (42), an H2 infrared detector (43), an H3 infrared detector (44) and an H4 infrared detector (45) which are used for remotely monitoring and transmitting the temperature of a power component, and further comprises a high-voltage sending double-color working state indicating screen (46), wherein the green indicates normal work and the red indicates faults.

3. The synchronous switch controller based on new energy special line delivery according to claim 1 or 2, wherein the H1 infrared detector socket (51), the H2 infrared detector socket (52), the H3 infrared detector socket (53) and the H4 infrared detector socket (54) comprise wired network cable connection sockets (56) which are all installed at the bottom of a host machine cabinet (50) of the synchronous switch controller based on new energy special line delivery and act on the inserted H1 infrared detector (42), the H2 infrared detector (43), the H3 infrared detector (44) and the H4 infrared detector (45), and further comprise a K5 automatic/manual switch (47) and are embedded in a K5 automatic/manual switch pull rod (55).

4. A new energy line out-based synchronous switch controller according to claim 1 or 3, wherein the wired network remote controller housing panel (57) comprises a wired network cable outlet pipe (64) connected with a wired network cable connection socket (56) of a new energy line out-based synchronous switch controller host machine cabinet (50) for data setting and functional operation; the high-voltage dual-color operating state indicating screen (46), the TFT display screen (38), the power network communication indicating lamp (48), the intranet communication indicating lamp (49), the K1, K2, K3, K4 button switch (37) and the storage battery (39) are respectively arranged in a high-voltage dual-color operating state indicating screen mounting hole (58), a TFT display screen mounting hole (59), a power network communication indicating lamp mounting hole (60), an intranet communication indicating lamp mounting hole (61), the K1, K2, K3, K4 button switch mounting hole (62) and a storage battery mounting window (63) of a wired network remote controller shell panel (57).

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