LU502187B1 - IoT POWER DISTRIBUTION CABINET - Google Patents

Abstract

The present invention discloses an Internet of Things (IoT) power distribution cabinet, which comprises a cabinet body, a cabinet door and a partition plate, wherein the cabinet door is hinged with the cabinet body, the cabinet body is provided with inserting grooves, the partition plate is inserted into the inserting grooves and provided with a plurality of uniformly distributed heat- dissipation slots, a wire-clamping structure is arranged on the inside of the cabinet body, a heat- dissipation opening is formed on a side wall of the cabinet body and provided with a protective casing, a heat-dissipation mesh plate is in the center of the protective casing, an upper side wall and a lower side wall of the protective casing are guiding slopes, and the guiding slopes, from top to bottom, gradually incline away from the cabinet body.

Description

DESCRIPTION 10908187 IoT POWER DISTRIBUTION CABINET

TECHNICAL FIELD The present invention belongs to the technical field of power distribution cabinets, and in particular relates to an IoT power distribution cabinet.

BACKGROUND IoT, namely "the Internet to which everyday objects are connected", is an extended and expanded network on the basis of the Internet. Various information sensing devices are connected to the Internet to form a huge network so that interconnections between people, machines and things are achieved at any time and any place. Terminals of IoT devices are generally required to be placed in power distribution cabinets. There are some deficiencies in the existing power distribution cabinets. The [oT devices constantly running in them will produce a large amount of heat. However, the heat-dissipation performance of the conventional power distribution cabinets 1s poor. Besides, as the existing IoT power distribution cabinets are generally used outside a building, rainwater often causes damage to the devices in them in thundery weather.

SUMMARY The technical problem to be solved by the present invention is to provide an IoT power distribution cabinet that favors the heat dissipation for IoT devices and guides rainwater to prevent it from getting into the cabinet body and thus causing damage to the devices. In order to solve the above technical problem, the present invention adopts the following technical scheme: an IoT power distribution cabinet, comprising a cabinet body, a cabinet door and a partition plate, wherein the cabinet door is hinged with the cabinet body, the cabinet body is provided with inserting grooves, the partition plate is inserted into the inserting grooves and provided with a plurality of uniformly distributed heat-dissipation slots, a wire-clamping structure is arranged on the inside of the cabinet body, and a heat-dissipation opening is formed on a side wall of the cabinet body and provided with a protective casing, favoring heat dissipation for IoT devices;

. . . . . . . LU502187 the wire-clamping structure comprises a connecting rod and a plurality of wire-clamping blocks, each of the wire-clamping blocks is provided with a threading hole, the connecting rod is passed through the plurality of wire-clamping blocks, two ends of the connecting rod are fixed to the cabinet body, each of the wire-clamping blocks 1s provided with a threaded hole, screws are threadedly connected to the threaded holes and tightly abutted against the connecting rod so that the wire-clamping blocks are fixed to the connecting rod, a rear side wall of the cabinet body 1s provided with a through hole, wires are passed through the threading holes of the wire-clamping blocks, the wire-clamping blocks are fixed to the connecting rod by turning screws; the wires in the cabinet body are fixed, favoring repair in the future; a heat-dissipation mesh plate is in the center of the protective casing, an upper side wall and a lower side wall of the protective casing are guiding slopes, and the guiding slopes, from top to bottom, gradually incline away from the cabinet body, so that rainwater is guided and prevented from getting into the cabinet body and thus causing damage to the devices.

Further, a side wall of the cabinet body is provided with grooves, walls on the left and right side of the protective casing extend outward to form bars, and the bars are attached to the grooves, thereby favoring detachment and cleaning of the protective casing and ensuring ventilation performance of the heat-dissipation mesh plate.

Further, an upper side wall of the protective casing extends outward to form a connecting bar, and screws are passed through the connecting bar and fixed to the cabinet body.

Further, a waterproof board is mounted above the cabinet body and connected to the cabinet body by support rods.

Further, the waterproof board consists of two obliquely arranged guiding plates, with an included angle between each guiding plate and the horizontal plane of 30-60°. Further, a plurality of heat-dissipation holes are formed in a top surface of the cabinet body.

The present invention has at least the following beneficial effects: the partition plate of the present invention is provided with a plurality of uniformly distributed heat-dissipation slots, and a heat-dissipation opening is formed on a side wall of the cabinet body and provided with a protective casing, thereby favoring heat dissipation for IoT devices; an

. . . . , .-_LU502187 upper side wall and a lower side wall of the protective casing are guiding slopes, and the guiding slopes, from top to bottom, gradually incline away from the cabinet body, so that rainwater is guided and prevented from getting into the cabinet body and thus causing damage to the devices; the wire-clamping structure of the present invention comprises a connecting rod and a plurality of wire-clamping blocks, each of the wire-clamping blocks is provided with a threading hole, the connecting rod is passed through the plurality of wire-clamping blocks, wires are passed through the threading holes of the wire-clamping blocks, the wire-clamping blocks are fixed to the connecting rod by turning screws; the wires in the cabinet body are fixed, favoring repair in the future; a side wall of the cabinet body of the present invention is provided with grooves, and walls on the left and right side of the protective casing extend outward to form bars, thereby favoring detachment and cleaning of the protective casing and ensuring ventilation performance of the heat-dissipation mesh plate.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic structural diagram of the present invention; FIG. 2 is a schematic structural diagram of a wire-clamping structure of the present invention; FIG. 3 is a schematic structural diagram of a cabinet body of the present invention; and FIG. 4 is a schematic structural diagram of a protective casing of the present invention. The reference numerals of the components in the drawings are as follows:

1. cabinet body; 11. inserting groove; 12. heat-dissipation opening; 13. through hole; 14. groove;

15. heat-dissipation hole; 2. cabinet door; 3. partition plate; 31. heat-dissipation slot; 4. wire- clamping structure; 41. connecting rod; 42. wire-clamping block; 421. threading hole; 43. screw;

5. protective casing; 51. heat-dissipation mesh plate; 52. guiding slope; 53. bar; 54. connecting bar; 6. waterproof board; 61. support rod.

DETAILED DESCRIPTION A preferred embodiment of the present invention will be described in detail below with reference to the drawings, so that the advantages and features of the present invention can be easily understood by those skilled in the art, and thus the protection scope of the present invention is LU502187 more clearly and explicitly defined.

Embodiment: an IoT power distribution cabinet as shown in FIGs 1 and 2 comprises a cabinet body 1, a cabinet door 2 and a partition plate 3, wherein the cabinet door 2 is hinged with the cabinet body 1, the cabinet body 1 is provided with inserting grooves 11, the partition plate 3 is inserted into the inserting grooves 11 and provided with a plurality of uniformly distributed heat- dissipation slots 31, a wire-clamping structure 4 is arranged on the inside of the cabinet body 1, and a heat-dissipation opening 12 is formed on a side wall of the cabinet body 1 and provided with a protective casing 5; as shown in FIG. 2, the wire-clamping structure 4 comprises a connecting rod 41 and a plurality of wire-clamping blocks 42, each of the wire-clamping blocks 42 is provided with a threading hole 421, the connecting rod 41 is passed through the plurality of wire-clamping blocks 42, two ends of the connecting rod 41 are fixed to the cabinet body 1, each of the wire-clamping blocks 42 is provided with a threaded hole, screws 43 are threadedly connected to the threaded holes and tightly abutted against the connecting rod 41 so that the wire-clamping blocks 42 are fixed to the connecting rod 41, and a rear side wall of the cabinet body 1 is provided with a through hole 13; as shown in FIG. 4, a heat-dissipation mesh plate 51 is in the center of the protective casing 5, an upper side wall and a lower side wall of the protective casing 5 are guiding slopes 52, and the guiding slopes 52, from top to bottom, gradually incline away from the cabinet body 1. A side wall of the cabinet body 1 is provided with grooves 14, walls on the left and right side of the protective casing 5 extend outward to form bars 53, and the bars 53 are attached to the grooves 14. An upper side wall of the protective casing 5 extends outward to form a connecting bar 54, and screws are passed through the connecting bar 54 and fixed to the cabinet body 1. A waterproof board 6 is mounted above the cabinet body 1 and connected to the cabinet body 1 by support rods 61.

. . , . . | 95021 87 The waterproof board 6 consists of two obliquely arranged guiding plates, with an included angle between each guiding plate and the horizontal plane of 30—60°. À plurality of heat-dissipation holes 15 are formed in a top surface of the cabinet body 1. The present invention works on the principle as follows: an IoT device is placed on the partition plate, wires of the device are passed through the threading holes of the wire-clamping blocks, and the wire-clamping blocks are fixed to the connecting rod by turning screws; the heat produced by the IoT device is dissipated through the heat-dissipation slots of the partition plate, the heat-dissipation holes and the heat-dissipation opening to ensure the service life of the device.

The above description is only the embodiment of the present invention, and is not intended to limit the patent scope of the present invention.

Equivalent structural alterations that utilize the content of the specification and the attached drawings of the present invention, or the cases where the content of the specification and the attached drawings is directly or indirectly applied in other related relevant technical fields, shall all fall within the patent protection scope of the present invention.

Claims (6)

CLAIMS LU502187

1. An IoT power distribution cabinet, comprising a cabinet body (1), a cabinet door (2) and a partition plate (3), wherein the cabinet door is hinged with the cabinet body, the cabinet body is provided with inserting grooves (11), the partition plate 1s inserted into the inserting grooves and provided with a plurality of uniformly distributed heat-dissipation slots (31), a wire-clamping structure (4) is arranged on the inside of the cabinet body, and a heat-dissipation opening (12) 1s formed on a side wall of the cabinet body and provided with a protective casing (5); the wire-clamping structure comprises a connecting rod (41) and a plurality of wire-clamping blocks (42), each of the wire-clamping blocks 1s provided with a threading hole (421), the connecting rod is passed through the plurality of wire-clamping blocks, two ends of the connecting rod are fixed to the cabinet body, each of the wire-clamping blocks is provided with a threaded hole, screws (43) are threadedly connected to the threaded holes and tightly abutted against the connecting rod so that the wire-clamping blocks are fixed to the connecting rod, and a rear side wall of the cabinet body is provided with a through hole (13); a heat-dissipation mesh plate (51) is in the center of the protective casing, an upper side wall and a lower side wall of the protective casing are guiding slopes (52), and the guiding slopes, from top to bottom, gradually incline away from the cabinet body.

2. The IoT power distribution cabinet according to claim 1, wherein a side wall of the cabinet body is provided with grooves (14), walls on the left and right side of the protective casing extend outward to form bars (53), and the bars are attached to the grooves.

3. The IoT power distribution cabinet according to claim 2, wherein an upper side wall of the protective casing extends outward to form a connecting bar (54), and screws are passed through the connecting bar and fixed to the cabinet body.

4. The IoT power distribution cabinet according to claim 1, wherein a waterproof board (6) is mounted above the cabinet body and connected to the cabinet body by support rods (61).

5. The IoT power distribution cabinet according to claim 4, wherein the waterproof board consists of two obliquely arranged guiding plates, with an included angle between each guiding plate and the horizontal plane of 30-60°.

6. The IoT power distribution cabinet according to claim 1, wherein a plurality of heat-dissipation holes (15) are formed in a top surface of the cabinet body.

LU502187