CN116706719A

CN116706719A - Full-automatic electromechanical integrated power distribution cabinet

Info

Publication number: CN116706719A
Application number: CN202310979200.5A
Authority: CN
Inventors: 李静; 张明; 武斐; 刘涛; 董小婷
Original assignee: Xinxiang Vocational and Technical College
Current assignee: Xinxiang Vocational and Technical College
Priority date: 2023-08-05
Filing date: 2023-08-05
Publication date: 2023-09-05
Anticipated expiration: 2043-08-05
Also published as: CN116706719B

Abstract

The utility model discloses a full-automatic electromechanical integrated power distribution cabinet, and belongs to the technical field of power supply equipment; the door plate is arranged on the shell through a hinge, and three overload protection mechanisms, three power supply mechanisms and a power-off mechanism are arranged on the shell; the power supply mechanism comprises a socket, wherein the socket is provided with a jack, and when power supply is needed, a plug of electric equipment is inserted into the jack; the overload protection mechanism is connected with the socket, and is started when the current on the socket is excessive; the power-off mechanism is connected with the door plate, and when the door plate is opened from the shell, the power-off mechanism breaks the circuit. The utility model automatically realizes the power supply and power-off protection of the electric equipment through the overload protection mechanism, the power supply mechanism and the power-off mechanism, and has simple structure and convenient operation.

Description

Full-automatic electromechanical integrated power distribution cabinet

Technical Field

The utility model belongs to the technical field of power supply equipment, and particularly relates to a full-automatic electromechanical integrated power distribution cabinet.

Background

In modern industrial and commercial fields, power distribution systems are one of the key elements to ensure safe and stable operation of power supplies. The traditional switch board is usually by manual operation, is circular telegram promptly and outage, owing to be manual operation, so when trouble such as electric leakage, short circuit appear, can not in time cut off the power supply to the consumer, can cause the harm to the consumer, endanger staff's life safety even.

The Chinese patent with the bulletin number of CN215771979U discloses an electromechanical integrated power distribution cabinet, which comprises an electromechanical power distribution cabinet, a heat dissipation groove and a jogging groove, wherein the top of the jogging groove is provided with a calibration groove, the heat dissipation groove is positioned on the left side and the right side of the electromechanical power distribution cabinet and is arranged at equal intervals, a jogging plate is movably arranged in the jogging groove, and a calibration arm is welded on the jogging plate. Although the waterproof electric device can be waterproof in the use process, the electric device cannot be independently powered, and the circuit cannot be timely powered off when the circuit fails, so that protection is realized. Aiming at the problems, the utility model provides a full-automatic electromechanical integrated power distribution cabinet.

Disclosure of Invention

Aiming at the technical problems, the utility model adopts the following technical scheme: a full-automatic electromechanical integrated power distribution cabinet comprises a shell, wherein a door plate is arranged on the shell through a hinge, and three overload protection mechanisms, three power supply mechanisms and a power failure mechanism are arranged on the shell.

The power supply mechanism comprises a socket, wherein a jack is arranged on the socket, and when power is required to be supplied, a plug of electric equipment is inserted into the jack.

The overload protection mechanism is connected with the socket, and is started when the current on the socket is overlarge.

The power-off mechanism is connected with the door plate, and when the door plate is opened from the shell, the power-off mechanism breaks the circuit.

Further, power supply mechanism still include the mounting bracket, mounting bracket fixed mounting on the shell, socket and mounting bracket fixed connection, the socket on be provided with the rectangular channel, the socket on slidable mounting have the slide bar, the upper end of slide bar passes the rectangular channel and stretches into in the socket, the lower extreme of slide bar pass the shell and with shell sliding fit, slide bar and socket between be provided with reset spring, the lower extreme of slide bar and the cooperation of a meshing of gear, a gear rotate and install in the inside of shell, and a meshing cooperation of gear and rack, a slidable mounting of rack in the inside of shell, a fixed mounting have T type platform on the rack, T type bench fixed mounting have a coupler one, the inside coaxial heart of coupler one install the wire.

Further, the overload protection mechanism comprises an electric wire, the upper end of the electric wire is connected with the socket, the lower end of the electric wire penetrates through the shell and is fixedly installed in the shell, the coupler five is installed at the lower end of the electric wire, and a lead is installed at the inner ring of the coupler five.

Further, overload protection mechanism still include two symmetrical arrangement's ampere meter frame, ampere meter frame fixed mounting be connected with the connecting rod on the electric wire between two ampere meter frames, the connecting rod on rotate the one end of installing the bull stick, the other end and rack two sliding fit of bull stick, rack two and horizontal pole sliding fit, horizontal pole fixed mounting on the mounting bracket, rack two lower extreme pass the shell, and with shell sliding fit, rack two's lower extreme and gear two meshing cooperation, gear two rotate and install the inside at the shell, gear two and crane meshing cooperation, crane sliding mounting be provided with the coupler three in the inside of shell, and the one end that keeps away from gear two on the crane, the inside of coupler three be provided with the wire.

Further, the lifting frame is located above the T-shaped table, and when the lifting frame slides downwards along the shell, the lifting frame can push the T-shaped table downwards.

Further, two symmetrically arranged bosses are arranged on the second rack, and one end, far away from the connecting rod, of the rotating rod is located between the two bosses.

Further, the outage mechanism include two connecting rods one, one end of connecting rod one rotate and install on the door plant, the other end and the connecting rod two of two connecting rods one rotate and be connected, connecting rod two slidable mounting at the inner wall of shell, connecting rod two on be the linear three coupler two of arranging, the inner circle of coupler two be provided with the wire.

Further, the shell on install the power transmission line, power transmission line one end be located the outside of shell, the other end of power transmission line is located the inside of shell, and the part that is located the inside of shell on the power transmission line installs three and is the coupler IV that linear arrangement, the inner circle of coupler IV install the wire, just five tops of coupler arrange the electric brake panel, electric brake panel fixed mounting in the inside of shell.

Compared with the prior art, the utility model has the beneficial effects that: (1) The overload protection mechanism, the power supply mechanism and the power-off mechanism automatically realize power supply and power-off protection of electric equipment, and the overload protection mechanism is simple in structure and convenient to operate; (2) The three power supply mechanisms work independently, so that the requirements of electric equipment with different numbers can be met, interference is avoided, and the practicability is high; (3) When the circuit is at risk or the door plate is opened, the whole circuit can be automatically powered off, so that the safety of electric equipment and the safety of staff are protected.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic view of another angle structure of fig. 1.

Fig. 3 is a schematic view of the rest of the structure of fig. 1 with the housing omitted.

Fig. 4 is a schematic view of another angle structure of fig. 3.

Fig. 5 is a schematic view of a partial enlarged structure at B in fig. 4.

Fig. 6 is a schematic view of a partial enlarged structure at C in fig. 4.

Fig. 7 is a partial sectional view of a part of the structure of the power supply mechanism.

Fig. 8 is a schematic view of a partial enlarged structure at a in fig. 7.

Fig. 9 is a schematic diagram of a first configuration of a wire and coupler.

FIG. 10 is a schematic view of a portion of the structure of the present utility model.

Reference numerals: 1-a housing; 2-a door panel; 3-a socket; 4-mounting frames; 5-a sliding rod; 6-gear one; 7-rack one; an 8-T shaped table; 9-conducting wires; 10-a first coupler; 11-a return spring; 12-electric wires; 13-connecting rods; 14-rotating rod; 15-a second rack; 16-boss; 17-horizontal bars; 18-gear two; 19-lifting frames; 20-an electric brake panel; 21-transmission lines; 22-first connecting rod; 23-a second connecting rod; 24-rectangular grooves; 25-ammeter rack; 26-a second coupler; 27-a third coupler; 28-coupler four.

Detailed Description

The technical scheme of the utility model is further described below by the specific embodiments with reference to the accompanying drawings.

For the purpose of better illustrating embodiments of the present utility model, certain elements of the drawings may be omitted, enlarged or reduced in size, and not to represent the actual product size, as it would be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

Examples: the full-automatic electromechanical integrated power distribution cabinet shown in fig. 1-10 comprises a shell 1, wherein a door plate 2 is arranged on the shell 1 through a hinge, and three overload protection mechanisms, three power supply mechanisms and a power-off mechanism are arranged on the shell 1.

The power supply mechanism comprises a socket 3, a jack is arranged on the socket 3, and when power supply is needed, a plug of electric equipment is inserted into the jack.

The overload protection mechanism is connected with the socket 3, and is started when the current on the socket 3 is overlarge.

The power-off mechanism is connected with the door plate 2, and when the door plate 2 is opened from the shell 1, the power-off mechanism breaks the circuit.

The power supply mechanism further comprises a mounting frame 4, the mounting frame 4 is fixedly mounted on the shell 1, the socket 3 is fixedly connected with the mounting frame 4, a rectangular groove 24 is formed in the socket 3, a sliding rod 5 is slidably mounted on the socket 3, the upper end of the sliding rod 5 penetrates through the rectangular groove 24 and stretches into the socket 3, the lower end of the sliding rod 5 penetrates through the shell 1 and is slidably matched with the shell 1, a reset spring 11 is arranged between the sliding rod 5 and the socket 3, the lower end of the sliding rod 5 is meshed and matched with a gear I6, the gear I6 is rotatably mounted in the shell 1, the gear I6 is meshed and matched with a rack I7, the rack I7 is slidably mounted in the shell 1, a coupler I10 is fixedly mounted on a T-shaped table 8,T-shaped table 8, and a lead 9 is coaxially mounted in the coupler I10.

The overload protection mechanism comprises an electric wire 12, the upper end of the electric wire 12 is connected with the socket 3, the lower end of the electric wire 12 penetrates through the shell 1 and is fixedly installed in the shell 1, a coupler five is installed at the lower end of the electric wire 12, and a lead 9 is installed at the inner ring of the coupler five.

The overload protection mechanism further comprises two symmetrically arranged ammeter frames 25, the ammeter frames 25 are fixedly arranged on the electric wire 12, a connecting rod 13 is connected between the two ammeter frames 25, one end of a rotating rod 14 is rotatably arranged on the connecting rod 13, the other end of the rotating rod 14 is in sliding fit with a second rack 15, the second rack 15 is in sliding fit with a horizontal rod 17, the horizontal rod 17 is fixedly arranged on the mounting frame 4, the lower end of the second rack 15 penetrates through the shell 1 and is in sliding fit with the shell 1, the lower end of the second rack 15 is in meshing fit with a second gear 18, the second gear 18 is rotatably arranged in the shell 1, the second gear 18 is in meshing fit with a lifting frame 19, the lifting frame 19 is slidably arranged in the shell 1, one end, far away from the second gear 18, of the lifting frame 19 is provided with a third coupler 27, and the inside of the third coupler 27 is provided with a lead 9.

The lifting frame 19 is located above the T-shaped table 8, and when the lifting frame 19 slides down along the housing 1, the lifting frame 19 pushes the T-shaped table 8 down.

Two symmetrically arranged bosses 16 are arranged on the second rack 15, and one end, far away from the connecting rod 13, of the rotating rod 14 is positioned between the two bosses 16.

The power-off mechanism comprises two first connecting rods 22, one ends of the first connecting rods 22 are rotatably arranged on the door plate 2, the other ends of the first connecting rods 22 are rotatably connected with second connecting rods 23, the second connecting rods 23 are slidably arranged on the inner wall of the shell 1, three second couplers 26 are linearly arranged on the second connecting rods 23, and the inner rings of the second couplers 26 are provided with wires 9.

The electric switch is characterized in that a power transmission line 21 is arranged on the shell 1, one end of the power transmission line 21 is located on the outer side of the shell 1, the other end of the power transmission line 21 is located in the shell 1, three couplers four 28 which are linearly arranged are arranged on the power transmission line 21, wires 9 are arranged on the inner ring of the couplers four 28, a switch panel 20 is arranged above the couplers five, and the switch panel 20 is fixedly arranged in the shell 1.

Working principle: the three power supply mechanisms are included in the utility model, and the working principle of one power supply mechanism is explained in the embodiment because the three power supply mechanisms have the same structure.

When the power transmission line 21 is connected to the power transmission equipment and power is required to be supplied to the power utilization equipment, a plug of the power utilization equipment is inserted into a jack on the socket 3, after the plug is inserted into the jack, the sliding rod 5 is pushed to extend into the portion of the socket 3, namely, the sliding rod 5 slides downwards along the rectangular groove 24 under the pushing of the plug, in the process, the reset spring 11 is compressed, and the reset spring 11 is used for assisting the reset of the sliding rod 5.

During the sliding of the sliding rod 5 along the rectangular slot 24, the sliding rod 5 also slides downwards along the housing 1, so that the gear one 6 engaged under the sliding rod 5 rotates, and the gear one 6 is engaged with the rack one 7, so that the rotating gear one 6 slides the rack one 7 along the housing 1, that is, the rack one 7 moves upwards, so that the T-shaped table 8 fixedly mounted on the rack one 7 also moves upwards, so that the wire 9 on the T-shaped table 8 and the coupler one 10 move upwards, and when the coupler one 10 moves to coincide with the central axes of the coupler two 26 and the coupler three 27, the plug is just plugged into the bottom. At this time, central axes of the first coupler 10, the second coupler 26, the third coupler 27, the fourth coupler 28 and the fifth coupler coincide, so that power is transmitted through the door panel 2, and thus non-contact power transmission is realized through the first coupler 10, the second coupler 26, the third coupler 27, the fourth coupler 28, the fifth coupler and the lead 9, and thus current is transmitted into the socket 3 through the electric wire 12, so that power is supplied to the electric equipment. The three power supply mechanisms are independent, and if only one socket 3 is plugged into a plug, the other two power supply mechanisms cannot be electrified, so that the power utilization safety is ensured.

When the current in the electric wire 12 is overlarge and the electric power consumption risk exists, the increased current in the electric wire 12 can enable the rotating rod 14 rotatably arranged on the connecting rod 13 to rotate, the rotating rod 14 can be in contact with the boss 16 positioned above the second rack 15, so that the second rack 15 is pushed upwards in the rotating process of the rotating rod 14, the second rack 15 slides upwards along the horizontal rod 17, the gear II 18 engaged and matched below the second rack 15 can rotate, the gear II 18 is engaged and matched with the lifting frame 19, so that the lifting frame 19 can slide downwards along the shell 1, the lower part of the lifting frame 19 is contacted with the upper part of the T-shaped table 8, the lifting frame 19 pushes the T-shaped table 8 to move downwards together, the central axes of the first coupler 10, the second coupler 26, the third coupler 27, the fourth coupler 28 and the fifth coupler are not overlapped, power supply is blocked, no more current in the electric wire 12 and the socket 3 is prevented, and the T-shaped table 8 moving downwards can push the electric power consumption equipment out of the electric wire through the first lifting frame 7 and the lifting frame 19 to protect the electric wire plug 5.

When the door plate 2 needs to be opened in the power supply process, the bolt at the joint of the door plate 2 and the shell 1 is opened, so that the door plate 2 rotates around a hinge at the joint of the door plate 2 and the shell 1, the first connecting rod 22 rotationally connected with the door plate 2 is pulled along with the rotation of the door plate 2, the first connecting rod 22 is rotationally connected with the second connecting rod 23, so that the second connecting rod 23 slides along the shell 1 under the pulling of the first connecting rod 22, the second coupler 26 connected with the second connecting rod 23 moves downwards, the second coupler 26 is not overlapped with the central axes of the first coupler 10, the third coupler 27, the fourth coupler 28 and the fifth coupler, power failure is completed, and then workers can overhaul electric devices in the shell 1.

Claims

1. The utility model provides a full-automatic electromechanical integration switch board, includes shell (1), shell (1) on install door plant (2), its characterized in that through the hinge: three overload protection mechanisms, three power supply mechanisms and a power-off mechanism are arranged on the shell (1);

the power supply mechanism comprises a socket (3), wherein the socket (3) is provided with a jack, and when power supply is needed, a plug of electric equipment is inserted into the jack;

the overload protection mechanism is connected with the socket (3), and is started when the current on the socket (3) is overlarge;

the power-off mechanism is connected with the door plate (2), and when the door plate (2) is opened from the shell (1), the power-off mechanism breaks the circuit.

2. A fully automated mechatronic power distribution cabinet according to claim 1, characterized in that: the utility model provides a power supply mechanism still include mounting bracket (4), mounting bracket (4) fixed mounting on shell (1), socket (3) and mounting bracket (4) fixed connection, socket (3) on be provided with rectangular channel (24), socket (3) on slidable mounting have slide bar (5), slide bar (5) upper end pass rectangular channel (24) and stretch into in socket (3), slide bar (5) lower extreme pass shell (1) and with shell (1) sliding fit, slide bar (5) and socket (3) between be provided with reset spring (11), slide bar (5) lower extreme and first gear (6) meshing cooperation, first gear (6) rotate and install the inside at shell (1), and first gear (6) meshing cooperation with first rack (7), first rack (7) slidable mounting in the inside of shell (1), first rack (7) on fixed mounting have T type platform (8), first gear (8) on first gear (6) meshing cooperation with first gear (6), first gear (6) rotation is installed in the inside coupler (10).

3. A fully automated mechatronic power distribution cabinet according to claim 2, characterized in that: the overload protection mechanism comprises an electric wire (12), the upper end of the electric wire (12) is connected with the socket (3), the lower end of the electric wire (12) penetrates through the shell (1) and is fixedly installed in the shell (1), a coupler V is installed at the lower end of the electric wire (12), and a lead (9) is installed at the inner ring of the coupler V.

4. A fully automated mechatronic power distribution cabinet according to claim 3, characterized in that: the overload protection mechanism also comprises two symmetrically arranged ammeter frames (25), wherein the ammeter frames (25) are fixedly arranged on the electric wire (12), a connecting rod (13) is connected between the two ammeter frames (25), one end of a rotating rod (14) is rotatably arranged on the connecting rod (13), the other end of the rotating rod (14) is in sliding fit with a rack II (15), the rack II (15) is in sliding fit with a horizontal rod (17), the horizontal rod (17) is fixedly arranged on the mounting frame (4), the lower end of the rack II (15) penetrates through the shell (1) and is in sliding fit with the shell (1), the lower end of the rack II (15) is in meshing fit with a gear II (18), the gear II (18) is rotatably arranged in the shell (1), the gear II (18) is in meshing fit with a lifting frame (19), the lifting frame (19) is in sliding fit with the rack II (15), one end of the lifting frame (19) is far away from the interior of the shell (1), and a three coupler (27) is arranged in the shell (9).

5. The fully-automatic mechatronic power distribution cabinet of claim 4, wherein: the lifting frame (19) is positioned above the T-shaped table (8), and when the lifting frame (19) slides downwards along the shell (1), the lifting frame (19) can push the T-shaped table (8) downwards.

6. The fully-automatic mechatronic power distribution cabinet of claim 5, wherein: two symmetrically arranged bosses (16) are arranged on the second rack (15), and one end, far away from the connecting rod (13), of the rotating rod (14) is located between the two bosses (16).

7. The fully-automatic mechatronic power distribution cabinet of claim 6, wherein: the power-off mechanism comprises two first connecting rods (22), one ends of the first connecting rods (22) are rotatably mounted on the door plate (2), the other ends of the first connecting rods (22) are rotatably connected with second connecting rods (23), the second connecting rods (23) are slidably mounted on the inner wall of the shell (1), three second couplers (26) are linearly arranged on the second connecting rods (23), and the inner rings of the second couplers (26) are provided with wires (9).

8. The fully-automatic mechatronic power distribution cabinet of claim 7, wherein: the utility model discloses a motor drive circuit, including shell (1), electric transmission line (21) are installed on shell (1), electric transmission line (21) one end be located the outside of shell (1), the other end of electric transmission line (21) is located the inside of shell (1), and be located the inside part of shell (1) on electric transmission line (21), install three coupler four (28) that are linear arrangement, the inner circle of coupler four (28) install wire (9), just five tops of coupler arrange electric brake panel (20), electric brake panel (20) fixed mounting in the inside of shell (1).