CN221236638U - Grid door and intelligent cabinet - Google Patents

Abstract

The utility model belongs to the technical field of doors and windows, and particularly relates to a grid door and an intelligent cabinet, which comprise a door body, wherein a first groove and a second groove are formed in the door body; the outer peripheral surface of the door body comprises a first surface and a second surface which are adjacent and form a preset included angle, the first groove is formed in the first surface, and the second groove is formed in the second surface; wherein the preset angle is not 0; the inner side surface and/or the outer side surface of the door body are/is provided with a reinforcing structure, and the reinforcing structure is used for reinforcing the strength of the door body. According to the grid gate provided by the embodiment of the utility model, the first groove and the second groove are arranged on the edge of the grid gate, and the core strip is manufactured according to the first groove and the second groove when the core is pulled, so that the length of the core strip is shorter, and the grid gate has the advantages of convenience in processing and reduction in the size of a die.

Description

Grid door and intelligent cabinet

Technical Field

The utility model belongs to the technical field of storage, and particularly relates to a grid door and an intelligent cabinet.

Background

The intelligent express cabinet belongs to a kind of cabinet, generally sets up in public place, can supply the self-service equipment of delivery and extraction express mail. The express delivery cabinet generally comprises a cabinet body, wherein a plurality of grid openings are formed in the cabinet body, the opening of each grid opening faces the front face of the cabinet body, and a grid opening door is installed on each grid opening.

The growth of the service life of the metal grid door increases the conditions of rusting and aging of the cabinet, so that the cabinet door needs to be maintained and replaced more and more, and the operation and maintenance cost is higher and higher.

To solve the above technical problem, at present, some of the grid doors are made of plastic materials, and four edges of the grid doors are generally provided with cavities, and the cavities penetrate along the length direction of the edges of the grid doors. However, the cavity of the existing grid gate is too long, so that the length of the loose core needle in the injection molding process is too long, the size of the injection mold is large, and the mold cost is high.

Disclosure of utility model

The technical problems to be solved by the utility model are as follows: the cavity of the existing grid gate is overlong in length, so that the length of a loose core needle in the injection molding process is overlong, the size of an injection mold is large, and the mold cost is high, and the grid gate is provided.

In order to solve the technical problems, an embodiment of the present utility model provides a grid door, including a door body, wherein a first groove and a second groove are formed on the door body; the outer peripheral surface of the door body comprises a first surface and a second surface which are adjacent and form a preset included angle, the first groove is formed in the first surface, and the second groove is formed in the second surface; wherein the preset included angle is not 0;

the inner side surface and/or the outer side surface of the door body are/is provided with a reinforcing structure, and the reinforcing structure is used for reinforcing the strength of the door body.

Optionally, the reinforcing structure of the door body comprises a concave cavity formed by concave inner side surfaces and/or concave outer side surfaces, and a hollowed-out plate formed in the concave cavity; the inner side of the door body is the surface of the grid door facing the grid opening, and the outer side of the door body is the surface of the grid door facing the grid opening.

Optionally, the door body comprises a first side plate and a third side plate which are oppositely arranged along the length direction, and a second side plate and a fourth side plate which are oppositely arranged along the height direction;

The first surface is the surface of the second side plate far away from the fourth side plate and/or the first surface is the surface of the fourth side plate far away from the second side plate;

The second surface is one of a surface of the first side plate away from the third side plate and/or the second surface is a surface of the third side plate away from the first side plate;

The peripheral edges of the hollowed-out plates are respectively connected with the first side plate, the second side plate, the third side plate and the fourth side plate;

The length of the edge of the hollowed-out plate is smaller than or equal to the length of the first side plate, the second side plate, the third side plate and the fourth side plate which are correspondingly connected with the hollowed-out plate;

The hollowed-out plate is provided with a plurality of through holes, and the depth direction of the through holes is the thickness direction of the door body;

The cross section of the through hole is one of polygon, circular and ellipse.

Optionally, two corners of the diagonal corner of the concave cavity are respectively formed with a latch mounting area for mounting the latch and a hinge mounting area for mounting the rotating shaft sleeve.

Optionally, one of the second side plate and the fourth side plate is provided with a first shaft hole, the other of the second side plate and the fourth side plate is provided with a second shaft hole, the first shaft hole and the second shaft hole are coaxial, and the axis of the first shaft hole is parallel to the height direction of the door body.

Optionally, the first shaft hole is arranged on the second side plate, and the second shaft hole is arranged on the fourth side plate;

A plurality of reinforcing protrusions are arranged around the first shaft hole, and the reinforcing protrusions are arranged on the surface, close to the concave cavity, of the second side plate; and/or the number of the groups of groups,

A plurality of reinforcing protrusions are arranged around the second shaft hole, and the reinforcing protrusions are arranged on the surface, close to the concave cavity, of the fourth side plate.

Optionally, the grid door further comprises a waterproof piece formed at the top end of the inner side surface of the door body, a water guide groove is defined by the waterproof piece and the door body in a matched mode, two ends of the water guide groove are provided with openings, and the bottom wall of the water guide groove gradually inclines downwards from the middle to the openings at the two ends.

Optionally, a drainage part is arranged on the waterproof piece, the drainage part is positioned at the openings at two ends of the water guide groove, and the inner surface of the bottom wall of the drainage part is lower than the inner surface of the bottom wall of the water guide groove.

Optionally, the grid gate is one of a plastic grid gate and a carbon fiber grid gate; the grid door is an integrally formed grid door.

According to the grid door provided by the embodiment of the utility model, the first groove and the second groove are arranged on the edge of the grid door, and the openings of the first groove and the second groove are different, so that the weight reduction effect is ensured, and the strength of the edge of the grid door is ensured. The length of the core strip is respectively manufactured according to the first groove and the second groove during core pulling, and the length of the core strip is shorter, so that the method has the advantages of convenience in processing and reduction in size of a die.

On the other hand, the utility model also provides an intelligent cabinet, which comprises a cabinet body and the grid door, wherein the cabinet body is provided with a grid, an opening is formed in the outer side of the grid, and the grid door is arranged on the cabinet body and can open or close the opening.

Drawings

FIG. 1 is an outside schematic view of a first embodiment of the present utility model for a port door;

FIG. 2 is a schematic view of the inside of a port door provided by a first embodiment of the present utility model;

FIG. 3 is a schematic top view of a first embodiment of the present utility model;

FIG. 4 is a schematic partial cross-sectional view of a first embodiment of the present utility model providing a port door;

Fig. 5 is an enlarged schematic view of portion a of fig. 4.

Reference numerals in the specification are as follows:

1. Rectangular door panels; 11. a first plate; 12. a second plate; 21. a first shaft hole; 22. a second shaft hole; 23. reinforcing the protrusion; 24. a first side plate; 25. a second side plate; 26. a third side plate; 27. a fourth side plate; 3. a first groove; 31. a first opening; 32. reinforcing ribs; 4. a second groove; 41. a second opening; 51. a first waterproof board; 52. a second waterproof board; 53. a water guide groove; 54. a drainage part; 6. a hollowed-out plate; 61. a through hole; 63. a hinge mounting area; 64. a latch installation area; 7. a bracket; 8. and a water flow hole.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects solved by the utility model more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

The height direction of the grid gate is vertical to the length direction of the grid gate, the height direction is the up-down direction in fig. 1, the length direction is the left-right direction in fig. 1, the outer side surface of the grid gate is the surface which is away from the grid opening in the use state, and the inner side surface of the grid gate is the surface which faces the grid opening in the use state.

First embodiment

As shown in fig. 1 to 3, the first embodiment of the present utility model provides a gate door, which includes a gate body, wherein an outer peripheral surface of the gate body includes a first surface and a second surface, the first surface and the second surface are adjacent and form a preset included angle, the first surface is provided with a first groove 3, the second surface is provided with a second groove 4, and the first groove 3 and the second groove 4 are both on an upper side of the gate body and are adjacent to each other; the first groove 3 and the second groove 4 are unidirectional openings, the first groove 3 is provided with only the first opening 31, the second groove 4 is provided with only the second opening 41, and the included angle between the orientation of the first opening 31 and the orientation of the second opening 41 is equal to a preset included angle, and the preset included angle is not zero. In this embodiment, the door body is rectangular, and the first surface and the second surface are disposed vertically. The first opening 31 is oriented upward, and the second opening 41 is oriented in the longitudinal direction of the cell door. Compared with the prior art, the arrangement of the first groove 3 and the second groove 4 in the embodiment reduces the weight, and simultaneously ensures the strength of the edge of the grid door as much as possible, and reduces the probability of cracks around the grid door caused by closing the door with great force.

In the prior art, only one first groove 3 is arranged on the upper side of the grid door, and if the openings of the first groove 3 are all upward, the thickness of the side wall around the opening is thinner, and the strength is weaker. Or only one second groove 4 is arranged on the side wall of the gate, and if the second openings 41 all face to the same side of the gate, the core strip length of the core pulling core is longer when the mold is ejected from the front and back of the mold, so that the mold is particularly large, and the production process is complex. The core strip is manufactured according to the first groove and the second groove during core pulling, has a short length, and has the advantages of being convenient to process and reducing the volume of a die.

The door body in this embodiment includes a rectangular door panel 1, a first side plate 24 and a third side plate 26 disposed opposite to each other in the longitudinal direction, and a second side plate 25 and a fourth side plate 27 disposed opposite to each other in the height direction. In the present embodiment, the second side plate 25 is disposed at the top of the rectangular door panel 1, the fourth side plate 27 is disposed at the bottom of the rectangular door panel 1, the first side plate 24 is disposed at a side close to the rotation axis of the door body, and the third side plate 26 is disposed at a side away from the rotation axis of the door body.

The first surface is the surface of the second side plate 25 remote from the fourth side plate 27 and/or the first surface is the surface of the fourth side plate 27 remote from the second side plate 25. The second surface is the surface of the first side plate 24 remote from the third side plate 26 and/or the second surface is one of the surfaces of the third side plate 26 remote from the first side plate 24. The present embodiment is explained in the following arrangement, the first surface is the surface of the second side plate 25 away from the fourth side plate 27; the second surface is the surface of the third side plate 26 remote from the first side plate 24.

Furthermore, in this embodiment, the inner surface of the door body is further provided with a reinforcing structure, which is not only used for reinforcing the strength of the door body, but also for reducing the weight of the door body. In other embodiments, the reinforcing structure may also be provided on the outer surface of the door body.

Referring to fig. 2, the reinforcing structure of the door body includes a cavity formed by concave inner and/or outer sides, and a hollowed-out plate formed in the cavity. In this embodiment, the cavity is enclosed by the rectangular door panel 1, the first side panel 24, the second side panel 25, the third side panel 26 and the fourth side panel 27. The periphery of the hollowed-out plate 6 is respectively connected with a first side plate 24, a second side plate 25, a third side plate 26 and a fourth side plate 27. The length of the edge of the hollowed-out plate 6 is smaller than or equal to the length of the first side plate 24, the second side plate 25, the third side plate 26 and the fourth side plate 27 which are correspondingly connected with the hollowed-out plate, so that each edge of the hollowed-out plate 6 can be partially or completely connected with the door body. The hollowed-out plate 6 in this embodiment is provided with a plurality of through holes 61 along the thickness direction thereof, the depth direction of the through holes 61 is the inside and outside direction of the door body, and the plurality of through holes 61 form a hollowed-out structure.

In the present embodiment, the cross section of the through hole 61 is one of polygonal, circular, and elliptical. The cross section of the polygon may be pentagonal, triangular, quadrilateral, etc. Preferably, the cross section of the through holes 61 in this embodiment is hexagonal, and the adjacent through holes share a side wall, that is, the hollowed-out plate 6 is a honeycomb-shaped plate. Further, the honeycomb plate in this embodiment also needs to be cut according to actual needs, so not every through hole is strictly necessary to be hexagonal, and the through hole 61 on the edge of the hollowed-out plate 6 is not necessarily a complete hexagonal hole.

The hollowed-out plate 6 in this embodiment can also be cut according to actual needs, but in this embodiment, one pair of diagonal angles of the hollowed-out plate 6 is cut, the hollowed-out plate 6 and the concave cavity form two cut-out spaces, and the two cut-out spaces are respectively used for installing the lock catch and the rotating shaft sleeve, and of course, in other embodiments, any position of the hollowed-out plate 6 can be cut.

Referring to fig. 1 and 3, the first grooves 3 are provided in plurality, specifically, the number of the first grooves 3 is two, and the two first grooves 3 are disposed side by side in the first direction. The inner chamber of first recess 3 is the cuboid form, is provided with a plurality of strengthening ribs 32 in the first recess 3, and the lateral wall and the diapire of first recess 3 are connected respectively to the both sides of strengthening rib 32, and a plurality of strengthening ribs 32 divide into two at the opposite both sides of first direction and are listed as, that is, two are listed as strengthening ribs 32 arrange along the direction of arranging of two first recesses 3. The reinforcing ribs 32 can support the side walls of the first grooves 3, and strengthen the overall strength of the first grooves 3.

In other embodiments, the shape of the first groove 3 may be square, circular, etc., and the number of the reinforcing ribs 32 may be set as required, specifically, as follows, when the side wall of the first groove 3 is thin, so that the strength of the side wall of the first groove 3 does not meet the design requirement, and therefore the reinforcing ribs are disposed between the bottom wall and the side wall of the first groove 3. And the thickness of the side walls of the first recess 3 need not be the same. Similarly, the second groove can be provided with reinforcing ribs according to the method.

In the present embodiment, the thicknesses of the first side plate 24, the second side plate 25, the third side plate 26 and the fourth side plate 27 in the present embodiment are not uniform, wherein the thickness of the second side plate 25 is larger than the thicknesses of the other three, so as to facilitate injection molding of the first groove 3 and the second groove 4 on the second side plate 25. In other embodiments, the thicknesses of the four may be uniform.

Referring to fig. 1, in the present embodiment, a rectangular door panel 1 includes a first plate 11 and a second plate 12, the second plate 12 is formed by bending the first plate 11 toward the inside, and the vertical distance of the outer side surface of the second plate 12 from the outer side surface of the first plate 11 gradually increases in a direction away from the first plate. The second side plate 25 is provided with a first shaft hole 21, the fourth side plate 27 is provided with a second shaft hole 22, the first shaft hole 21 and the second shaft hole 22 are coaxial, and the first shaft hole 21 is provided on one side of the second side plate 25 close to the second plate 12.

In this embodiment, the second plate 12 is formed by deflecting the first plate 11 toward the inner side of the lattice door, and the first shaft hole 21 and the second shaft hole 22 can be used to realize a rotary connection with the rotary shaft on the cabinet. Because the second plate 12 is inclined inward relative to the first plate 11, the rotating shaft of the recombined door body is arranged at one side close to the second plate 12, compared with the flat rectangular door plate 1, the rotating angle of the grid door of the embodiment is larger, and the personnel can conveniently take out stored articles from the grid.

Further, in this embodiment, the diameters of the first shaft hole 21 and the second shaft hole 22 are the same as the outer diameter of the shaft sleeve, so that the shaft sleeve is installed, and the shaft sleeve is connected with the rotating shaft on the cabinet body, so that the rotating shaft is replaced by the shaft sleeve and the rotating shaft to directly connect the grid door, friction between the rotating shaft and the grid door is reduced, and in the door opening and closing test, the door opening and closing times are expected to be no less than 8 ten thousand times.

Referring to fig. 2, 4 and 5, in the present embodiment, since the first shaft hole 21 is the through hole 61 and is disposed on the side of the second side plate 25 near the second plate, so that the strength of the position where the first shaft hole 21 is located is weakened, a plurality of reinforcing protrusions 23 are disposed on the second side plate 25, the reinforcing protrusions 23 and the second side plate 25 are integrally formed in the present embodiment, and the position where the reinforcing protrusions 23 are located makes the thickness of the position thicker than other positions of the second side plate 25, thereby playing a role in reinforcing the structural strength of the position. The reinforcing protrusion 23 is provided around the first shaft hole 21, and the reinforcing protrusion 23 is provided on the bottom surface of the second side plate 25. Of course, in other embodiments, the reinforcing protrusion 23 may be provided on the top surface of the fourth side plate 27.

In this embodiment, a buffer structure is disposed in the latch mounting area 64, the buffer structure includes a bracket 7 for mounting a buffer pad, the bracket 7 is fixedly connected with the third side plate 26, the buffer pad is fixedly or detachably connected to the bracket 7, and the buffer pad protrudes from the inner surface of the third side plate 26 in a direction away from the rectangular door panel 1. The bracket 7 in this embodiment is formed by joining three plates, two of which are perpendicular to the first plate 11, as a supporting structure. The other plate is parallel to the first plate 11 and is connected to the third side plate 26, and the plate parallel to the first plate 11 is provided with a hole in which the cushion is mounted. When the user closes the grid door, the cushion pad has elasticity, plays the effect of buffering, reduces the collision between grid door and the cabinet body.

Referring to fig. 3, in this embodiment, the design of waterproofing and water guiding is also performed on the lattice door, and a waterproof piece is formed at the top end of the inner side of the door body, and the waterproof piece and the door body cooperate to define a water guiding groove, and two ends of the water guiding groove are opened, so that the following concrete steps are: the waterproof member includes a first waterproof plate 51 and a second waterproof plate 52, the first waterproof plate 51 and the second waterproof plate 52 extending in a first direction, the first waterproof plate 51 and the second waterproof plate 52 being provided at the top end of the rectangular door panel 1. The second waterproof board 52 and the rectangular door board 1 are arranged at intervals, one side of the first waterproof board 51 is connected with the bottom end of the second waterproof board 52, the opposite side of the first waterproof board 51 is connected with the side wall of the first groove 3, the second waterproof board 52, the first waterproof board 51 and the side wall of the first groove 3 form a water guide groove 53, and two ends of the water guide groove 53 in the length direction are respectively provided with openings.

In this embodiment, the side wall of the first groove 3, the first waterproof board 51 and the second waterproof board 52 form a water guiding groove 53, and when a user takes out an express delivery in a rainy day, rainwater enters the water guiding groove 53 and flows out downwards from two ends of the water guiding groove 53, so that the probability that the rainwater collides with the inner side of the rectangular door plate 1 and enters the grid is reduced. In the closed state, when rainwater obliquely enters the top end of the grid door and the inside of the cabinet, at most, the rainwater flows into the water guide groove 53 and flows out from both ends of the water guide groove 53.

The waterproof piece is provided with a drainage portion 54, the drainage portion 54 is located at openings at two ends of the water guiding groove 53, the inner surface of the bottom wall of the drainage portion 54 is lower than the inner surface of the bottom wall of the water guiding groove 53, that is, two ends of the first waterproof board 51 in the length direction are provided with drainage portions 54, and the bottom surface of the drainage portion 54 is lower than the top surface of the first waterproof board 51. When the drainage portion 54 is in operation, rainwater flows to both end portions of the drainage groove 53, and is drained from the drainage portion 54.

In this embodiment, the bottom wall of the water guiding groove gradually slopes downward from the middle to the openings at the two ends, that is, the top surface of the first waterproof plate 51 is arranged from the middle to the two ends, the middle of the first waterproof plate 51 is the highest point, the two ends of the first waterproof plate 51 are the lowest points, and the bottom surface of the drainage portion 54 is lower than the bottom surface of the end of the water guiding groove 53. Once the rainwater flows into the water guide 53, the rainwater flows out toward both ends of the water guide 53 due to the influence of gravity and the influence of the inclined bottom surface of the water guide 53.

Referring to fig. 2 and 3, in the present embodiment, the fourth side plate 27 is provided with a plurality of water flow holes 8 along its length direction, the plurality of water flow holes 8 penetrate in the thickness direction of the fourth side plate 27, and the water flow holes 8 communicate with the recessed cavity. When the rain water inlet amount is larger than the water outlet amount of the water guide groove 53 in the case of facing the heavy rain, the rainwater can enter the concave cavity along the outer wall of the water guide groove 53, and at the moment, the rainwater in the concave cavity is discharged through the water flowing holes 8.

Most importantly, the door body in the embodiment is processed by adopting an integral injection molding process, and in the embodiment, due to the adoption of integral molding, the strength of the cabinet door can be adjusted to meet the requirements of users in the aspects of the composition of raw materials and the structure of the door body, and meanwhile, the fire-retardant material is added into the raw materials of the door body to meet the requirements of fire-retardant grades. The integral injection molding is more attractive because no welding trace exists because the integral injection molding does not need welding; and the outer side surface of the door body is frosted, so that the problem of feeding the periodical adhesive residue can be reduced. The first groove, the second groove and the reinforcing structure in the embodiment all have the effect of reinforcing the strength of the door body. Especially, the hollowed-out plate is best honeycomb-shaped, so that the problem of insufficient strength of light material doors such as plastics, polycarbonate, carbon fibers and the like is solved.

And replace traditional metal door with plastic material or polycarbonate material or the check door of light material such as carbon fiber material, avoided metal to rust, metal wear paint surface scheduling problem, increase of service life greatly, in the UV test, expect to satisfy following UV test standard: on the premise of not less than 800 hours, the color difference value delta E is not more than 4.

In addition, compared with a galvanized sheet iron door, under the same structure, the door body in the embodiment lightens the weight of the intelligent cabinet door by 50-80%, further reduces the spring door force requirement on the spring opening of the intelligent cabinet door by the electric control lock due to the weight reduction effect, and also reduces the friction loss between the rotating shaft and the shaft sleeve.

Second embodiment

The second embodiment of the present utility model differs from the first embodiment in that the port door is a one-piece sheet material and the first and second grooves are provided on any edge of the port door.

Third embodiment

The third embodiment of the present utility model differs from the first embodiment in that the port door is rectangular and has a first groove and a second groove on each side edge.

Fourth embodiment

The fourth embodiment of the present utility model differs from the first embodiment in that the door body has two first surfaces, one of which is provided on the surface of the second side plate 25 remote from the fourth side plate 27 and the other of which is provided on the surface of the fourth side plate 27 remote from the second side plate 25, and similarly, the door body has two second surfaces, one of which is provided on the surface of the third side plate 26 remote from the first side plate 24 and the other of which is provided on the surface of the first side plate 24 remote from the third side plate 26.

Fifth embodiment

The fifth embodiment of the utility model also provides an intelligent cabinet, which comprises a hinge structure, an electric control lock, a cabinet body and the grid door of any embodiment, wherein the cabinet body is provided with a grid, the outer side of the grid is provided with an opening, and the grid door is arranged on the cabinet body and can open or close the opening.

The electric control lock comprises a lock body and a lock catch matched with the lock body, the lock catch is assembled on the lock catch installation area, and the lock body is installed on the cabinet body. The hinge structure comprises a shaft sleeve and a rotating shaft, the shaft sleeve is arranged on the first shaft hole and the second shaft hole, the rotating shaft is arranged on the cabinet body, and the rotary connection between the cabinet body and the cabinet door is realized.

The intelligent cabinet of this embodiment still sets up the blotter on buffer structure, and the blotter has elasticity to play the collision of reduction check door and the cabinet body when closing the door between.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. The grid door is characterized by comprising a door body, wherein a first groove and a second groove are formed in the door body; the outer peripheral surface of the door body comprises a first surface and a second surface which are adjacent and form a preset included angle, the first groove is formed in the first surface, and the second groove is formed in the second surface; wherein the preset included angle is not 0;

the inner side surface and/or the outer side surface of the door body are/is provided with a reinforcing structure, and the reinforcing structure is used for reinforcing the strength of the door body.

2. The cell door of claim 1, wherein the reinforcement structure of the door body comprises a cavity formed by the inner side surface and/or the outer side surface being concave inwards, and a hollowed-out plate formed in the cavity; the inner side of the door body is the surface of the grid door facing the grid opening, and the outer side of the door body is the surface of the grid door facing the grid opening.

3. The cell door of claim 2, wherein the door body includes first and third side panels disposed opposite in a length direction, and second and fourth side panels disposed opposite in a height direction thereof;

The first surface is the surface of the second side plate far away from the fourth side plate and/or the first surface is the surface of the fourth side plate far away from the second side plate;

The second surface is one of a surface of the first side plate away from the third side plate and/or the second surface is a surface of the third side plate away from the first side plate;

The peripheral edges of the hollowed-out plates are respectively connected with the first side plate, the second side plate, the third side plate and the fourth side plate;

The length of the edge of the hollowed-out plate is smaller than or equal to the length of the first side plate, the second side plate, the third side plate and the fourth side plate which are correspondingly connected with the hollowed-out plate;

The hollowed-out plate is provided with a plurality of through holes, and the depth direction of the through holes is the thickness direction of the door body;

The cross section of the through hole is one of polygon, circular and ellipse.

4. A latticework door according to claim 3, wherein both corners of the diagonally opposite corners of the cavity are formed with a latch mounting area for mounting a latch and a hinge mounting area for mounting a rotation boss, respectively.

5. The cell door of claim 4, wherein one of the second side plate and the fourth side plate is provided with a first shaft hole, the other of the second side plate and the fourth side plate is provided with a second shaft hole, the first shaft hole and the second shaft hole are coaxial, and an axis of the first shaft hole is parallel to a height direction of the door body.

6. The cell door of claim 5, wherein the first axle aperture is disposed on the second side plate and the second axle aperture is disposed on the fourth side plate;

A plurality of reinforcing protrusions are arranged around the first shaft hole, and the reinforcing protrusions are arranged on the surface, close to the concave cavity, of the second side plate; and/or the number of the groups of groups,

A plurality of reinforcing protrusions are arranged around the second shaft hole, and the reinforcing protrusions are arranged on the surface, close to the concave cavity, of the fourth side plate.

7. The cell door of claim 1, further comprising a waterproof member formed at a top end of an inner side of the door body, the waterproof member and the door body cooperatively defining a water guide groove, both ends of the water guide groove being opened, a bottom wall of the water guide groove being gradually inclined downward from a middle toward both ends.

8. The cell door according to claim 7, wherein the waterproof member is provided with a drainage portion, the drainage portion is located at openings at both ends of the water guide groove, and an inner surface of a bottom wall of the drainage portion is lower than an inner surface of a bottom wall of the water guide groove.

9. The cell gate of any of claims 1-8, wherein the cell gate is one of a plastic cell gate, a carbon fiber cell gate; the grid door is an integrally formed grid door.

10. An intelligent cabinet which is characterized by comprising a cabinet body and the grid door of any one of claims 1-9, wherein a grid opening is arranged on the cabinet body, an opening is arranged on the outer side of the grid opening, and the grid door is arranged on the cabinet body and can open or close the opening.