CN215764232U - Visual monitoring device of BIM low pressure distribution project - Google Patents

Abstract

The utility model discloses a visual monitoring device for a BIM low-voltage power distribution project, which is characterized in that: the gear rack comprises a bottom mounting plate, a plurality of uniformly distributed mounting holes are formed in the front side face relative position of the bottom mounting plate, the mounting holes longitudinally penetrate through the bottom mounting plate, a vertically distributed gear rack is fixedly arranged in the front side face relative position of the bottom mounting plate, a gear rack groove is arranged in the right side face position, a guide rail which is vertically and downwardly arranged is arranged in the right side face relative position of the gear rack, the guide rail is fixedly connected to the right side face of the bottom mounting plate, a first sliding block is arranged on the front side face of the guide rail, a plurality of uniformly distributed first connecting holes are formed in the front side face of the first sliding block, a second sliding block is arranged in the bottom relative position of the first sliding block, a plurality of uniformly distributed second connecting holes are formed in the front side face of the second sliding block, and the first sliding block and the second sliding block are connected to the front side face relative position of the guide rail in a matching mode. The movable type safety helmet can be flexibly moved, the use efficiency and the safety are improved, and the practicability is good.

Description

Visual monitoring device of BIM low pressure distribution project

Technical Field

The utility model belongs to the technical field of power distribution monitoring devices, and particularly relates to a visual monitoring device for a BIM (building information modeling) low-voltage power distribution project.

Background

The low-voltage distribution system is composed of a distribution substation, a high-voltage distribution line, a distribution transformer, a low-voltage distribution line and corresponding control protection equipment, is mainly used for distributing electric energy for use by downstream residents, factories and the like, the traditional detection in the daily operation and maintenance of the low-voltage distribution project is realized by opening and checking the equipment one by one through electric workers to ensure that the equipment can normally run, but because the distribution system is mostly remote in position, the patrol efficiency of the electric workers is very low, and frequent manual patrol can cause potential safety hazards to the workers and cause inestimable loss, and the other mode is to install a camera and a smoke-sensing and temperature-sensing alarm around the distribution cabinet, which can achieve the early warning effect, but the problems in a single cabinet can not obtain data and states at the first time, has low practicability and combines the problems existing in practical application, therefore, the BIM low-voltage power distribution project visual monitoring device is developed, stable, safe and reliable transmission can be achieved, automatic and regular inspection can be performed under unmanned control, and the monitoring effect is good.

SUMMERY OF THE UTILITY MODEL

The utility model provides a visual monitoring device for a BIM low-voltage power distribution project, which has the advantages of stable transmission, low cost, easy realization and good monitoring effect in actual use.

In order to solve the technical problems, the utility model adopts the following technical scheme:

a visual monitoring device for a BIM low-voltage distribution project comprises a bottom mounting plate, wherein a plurality of uniformly distributed mounting and fixing holes are formed in the front side face of the bottom mounting plate in a relative position, the mounting and fixing holes longitudinally penetrate through the bottom mounting plate, a vertically distributed gear rack is fixedly arranged in the front side face of the bottom mounting plate in a relative position, a gear rack groove is arranged in the right side face of the bottom mounting plate, a vertically downward distributed guide rail is arranged in the right side face of the gear rack in a relative position, the guide rail is fixedly connected to the right side face of the bottom mounting plate, a first sliding block is arranged on the front side face of the guide rail, a plurality of uniformly distributed first connecting holes are formed in the front side face of the first sliding block, a second sliding block is arranged in a relative position at the bottom of the first sliding block, a plurality of uniformly distributed second connecting holes are formed in the front side face of the second sliding block, the first sliding block and the second sliding block are connected in a relative position at the front side face of the guide rail in a matched manner, a monitoring device box is connected to the front side faces of the first sliding block and the second sliding block, the monitoring device case rear side face is connected with a transmission motor which is transversely arranged, a transmission gear is connected to the shaft end of the rear portion of the transmission motor and is connected with a gear strip in a matched mode, a power source interface is arranged at the relative position of the right side face of the monitoring device case, heat dissipation holes are formed in the bottom position of the power source interface, a monitoring camera is arranged at the top position of the front side face of the monitoring device case, an infrared thermal sensing device is arranged at the relative position of the bottom of the monitoring camera, an operation display screen is arranged at the relative position of the bottom of the infrared thermal sensing device, and the monitoring camera, the infrared thermal sensing device and the operation display screen are connected to the front side face of the monitoring device case in a matched mode.

Further, the transmission motor drives the transmission gear to rotate, and the transmission gear rotates up and down through the gear strip.

Further, the shape and size of the first slider are the same as those of the second slider.

Further, the monitoring device box is connected with the first connecting hole in the front side face of the first sliding block and the second connecting hole in the front side face of the second sliding block through bolts, and the first sliding block and the second sliding block synchronously act and are consistent in direction.

Further, the transmission motor is fixedly connected to the rear side face of the monitoring device box.

Compared with the prior art, the utility model has the beneficial effects that:

(1) through installing the bottom plate at the cabinet door inboard, equipment gets some modes and passes through the inside power supply of switch board, and inside not installing the group battery has improved the security, and visual effectual can look over the interior condition of cabinet and detect the interior temperature of cabinet in real time through the internet communication.

(2) The traditional manual single inspection mode of baituo is operated through the cooperation of a transmission motor and a transmission device, the upper part and the lower part of the cabinet are all visible, an internal operation screen is used for setting daily inspection time, and functions such as local historical event query improve fault repair efficiency and reduce accident occurrence rate.

Drawings

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

FIG. 2 is a schematic view of the bottom drive rail and gear rack connection;

fig. 3 is a schematic view of the overall structure of the monitoring device.

Description of the drawings: 1. the monitoring device comprises a transmission gear, 2 parts of a monitoring camera, 3 parts of a monitoring device box, 4 parts of an infrared thermal sensing device, 5 parts of an operation display screen, 6 parts of a guide rail, 7 parts of a gear strip, 8 parts of a mounting fixing hole, 9 parts of a bottom mounting plate, 10 parts of a first sliding block, 11 parts of a first connecting hole, 12 parts of a transmission motor, 13 parts of a second sliding block, 14 parts of a second connecting hole, 15 parts of a power interface and 16 parts of a heat dissipation hole.

Detailed Description

As shown in fig. 1 to 3, a visual monitoring device for BIM low-voltage distribution engineering comprises a bottom mounting plate 9, a plurality of mounting holes 8 uniformly arranged are formed in the front side surface of the bottom mounting plate 9, the mounting holes 8 longitudinally penetrate through the bottom mounting plate 9, a vertically arranged gear rack 7 is fixedly arranged in the front side surface of the bottom mounting plate 9, a tooth space of the gear rack 7 is arranged in the right side surface position, a guide rail 6 vertically arranged downwards is arranged in the right side surface position of the gear rack 7, the guide rail 6 is fixedly connected to the right side surface of the bottom mounting plate 9, a first slider 10 is arranged on the front side surface of the guide rail 6, a plurality of first connecting holes 11 uniformly arranged are formed in the front side surface of the first slider 10, a second slider 13 is arranged in the bottom relative position of the first slider 10, a plurality of second connecting holes 14 uniformly arranged are formed in the front side surface of the second slider 13, the first slider 10 and the second slider 13 are connected in the front side surface relative position of the guide rail 6 in a matching manner, the monitoring device box 3 is connected to the front side of the first slider 10 and the second slider 13, the transmission motor 12 transversely arranged is connected to the rear side of the monitoring device box 3, the transmission gear 1 is connected to the rear shaft end of the transmission motor 12, the transmission gear 1 is connected with the gear strip 7 in a matched mode, the power interface 15 is arranged at the right side relative position of the monitoring device box 3, the heat dissipation holes 16 are formed in the bottom of the power interface 15, the monitoring camera 2 is arranged at the top of the front side of the monitoring device box 3, the infrared thermal sensing device 4 is arranged at the bottom relative position of the monitoring camera 2, the operation display screen 5 is arranged at the bottom relative position of the infrared thermal sensing device 4, the monitoring camera 2, the infrared thermal sensing device 4 and the operation display screen 5 are connected to the front side of the monitoring device box 3 in a matched mode.

The transmission motor 12 drives the transmission gear 1 to rotate, and the transmission gear 1 rotates up and down through the gear rack 7.

The shape and size of the first slider 10 are the same as those of the second slider 13.

The monitoring device box 3 is connected with the first connecting hole 11 on the front side surface of the first sliding block 10 and the second connecting hole 14 on the front side surface of the second sliding block 13 through bolts, and the first sliding block 10 and the second sliding block 13 synchronously act and have consistent directions.

The transmission motor 12 is fixedly connected to the rear side surface of the monitoring device box 3.

The working process is as follows: the bottom mounting plate 9 is arranged on the inner side of a cabinet door and fixedly connected with the bottom mounting plate through a bolt penetrating through a mounting fixing hole 8, a path of power supply access power supply 15 position is obtained from the inside of the equipment, at the moment, the equipment is electrified, when in operation, a transmission motor 12 at the bottom of a monitoring device box 3 acts, the transmission motor 12 operates to drive a transmission gear 1 at the shaft end to rotate, the transmission gear 1 is in matched connection with a gear strip 7, the transmission gear 1 realizes the up-and-down operation through the gear strip 7, the monitoring device box 3 is fixedly connected with the front side positions of a first sliding block 10 and a second sliding block 13, the monitoring device box 3 synchronously operates up and down through the rotation of the transmission gear 1, the daily inspection time, the speed and the alarm temperature are set through an operation display screen 5 on the front side surface of the monitoring device box 3, the monitoring camera 2 is used for monitoring the equipment condition in the cabinet, and the infrared thermal sensing device 4 is used for monitoring the equipment in the cabinet and the retrograde temperature, when equipment breaks down in the cabinet, the networking module arranged inside the monitoring device box 3 sends alarm information to the central control room, so that the staff can acquire equipment information at the first time, and timely maintain and protect measures are taken.

Claims (5)

1. The utility model provides a visual monitoring device of BIM low pressure distribution project which characterized in that: comprises a bottom mounting plate (9), a plurality of uniformly arranged mounting and fixing holes (8) are arranged at the relative position of the front side surface of the bottom mounting plate (9), the mounting and fixing holes (8) longitudinally penetrate through the bottom mounting plate (9), a vertically arranged gear strip (7) is fixedly arranged at the relative position of the front side surface of the bottom mounting plate (9), the tooth socket of the gear strip (7) is arranged at the position of the right side surface, a guide rail (6) vertically arranged downwards is arranged at the relative position of the right side surface of the gear strip (7), the guide rail (6) is fixedly connected to the right side surface of the bottom mounting plate (9), a first sliding block (10) is arranged at the front side surface of the guide rail (6), a plurality of uniformly arranged first connecting holes (11) are arranged at the front side surface of the first sliding block (10), a second sliding block (13) is arranged at the relative position of the bottom of the first sliding block (10), a plurality of uniformly arranged second connecting holes (14) are arranged at the front side surface of the second sliding block (13), the first sliding block (10) and the second sliding block (13) are connected at the relative positions of the front side surface of the guide rail (6) in a matching way, the front side surfaces of the first sliding block (10) and the second sliding block (13) are connected with a monitoring device box (3), the rear side surface of the monitoring device box (3) is connected with a transversely arranged transmission motor (12), the rear shaft end of the transmission motor (12) is connected with a transmission gear (1), the transmission gear (1) is connected with a gear rack (7) in a matching way, the relative position of the right side surface of the monitoring device box (3) is provided with a power interface (15), the bottom position of the power interface (15) is provided with a heat dissipation hole (16), the top position of the front side surface of the monitoring device box (3) is provided with a monitoring camera (2), the relative position of the bottom of the monitoring camera (2) is provided with an infrared thermal sensing device (4), the relative position of the bottom of the infrared thermal sensing device (4) is provided with an operation display screen (5), the monitoring camera (2), the infrared thermal sensing device (4) and the operation display screen (5) are connected to the front side face of the monitoring device box (3) in a matching mode.

2. The visual monitoring device of BIM low voltage distribution project of claim 1, characterized in that: the transmission motor (12) drives the transmission gear (1) to rotate, and the transmission gear (1) rotates up and down through the gear rack (7).

3. The visual monitoring device of BIM low voltage distribution project of claim 1, characterized in that: the shape and size of the first slider (10) are the same as those of the second slider (13).

4. The visual monitoring device of BIM low voltage distribution project of claim 1, characterized in that: monitoring device case (3) pass through first connecting hole (11) of bolted connection first slider (10) front flank and second slider (13) front flank second connecting hole (14), and first slider (10) and second slider (13) synchronous motion and direction are unanimous.

5. The visual monitoring device of BIM low voltage distribution project of claim 1, characterized in that: the transmission motor (12) is fixedly connected with the rear side surface of the monitoring device box (3).

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