CN115075513B - Wallboard built-in cabinet based on real-time monitoring technology and construction method thereof - Google Patents

Abstract

The utility model relates to a wallboard built-in cabinet and construction method based on real-time supervision technique, including camera and built-in cabinet, built-in cabinet is used for installing in the holding tank that the wallboard was seted up, built-in cabinet includes cabinet body and door plant, the camera is used for installing on the wallboard and carrying out real-time supervision to the construction of built-in cabinet on the wallboard, still includes the board that holds, it is internal or on the cabinet body to accept the board along the depth direction sliding connection of holding tank, the door plant is keeping away from the one end of holding tank diapire at the board that holds along the sliding direction sliding connection of perpendicular to accepts the board, when the door plant is closed, the door plant is located the holding tank completely with accepting the board, when the door plant is opened, the door plant is located the holding tank outside and staggers with the holding tank notch. When the door plate is opened by an operator, the door plate is moved out of the accommodating groove, and then the door plate is pulled, so that the door plate is staggered with the notch of the accommodating groove, and the influence of the door plate on the cabinet body on the built-in cabinet is reduced by changing the opening mode of the door plate.

Description

Wallboard built-in cabinet based on real-time monitoring technology and construction method thereof

Technical Field

The application relates to the field of built-in cabinets of wallboards, in particular to a built-in cabinet of wallboards based on a real-time monitoring technology and a construction method of the built-in cabinet.

Background

In recent years, the application of the real-time monitoring technology in life is more and more widespread, and particularly in a construction site, the real-time monitoring technology can monitor the construction progress in real time.

The related art built-in wall panel cabinet is shown in fig. 1, and includes a door panel 21 and a cabinet body 22, wherein the door panel 21 is hinged to the cabinet body 22. When in installation, the wallboard 1 is provided with the accommodating groove 11 for accommodating the door plate 21 and the cabinet body 22, then the door plate 21 of the built-in cabinet 2 faces one side of the opening of the accommodating groove 11, the cabinet body 22 is fixed in the accommodating groove 11, and the built-in cabinet 2 is completely positioned in the accommodating groove 11 under the state that the door plate 21 is closed. Install camera 5 on wallboard 1 of job site, the camera 5 can carry out real-time supervision to the construction of built-in cabinet 2.

The related technical scheme has the following defects: when the door plant was opened to the user, the door plant was opened at most and is 90, and the degree that the door plant was opened is limited, and the door plant can influence the user and take the internal article of cabinet, if external light source is located the door plant and keeps away from the one side of cabinet body simultaneously, the door plant can shelter from the light source, leads to the internal light of cabinet darker, inconvenient article in the cabinet body of taking.

Disclosure of Invention

In order to reduce the influence of the door plate on the built-in cabinet on the cabinet body, the application provides a wallboard built-in cabinet based on a real-time monitoring technology and a construction method thereof.

The application provides a wallboard built-in cabinet based on real-time supervision technique adopts following technical scheme:

the utility model provides a wallboard built-in cabinet and construction method based on real-time supervision technique, includes camera and built-in cabinet, built-in cabinet is used for installing in the holding tank that the wallboard was seted up, built-in cabinet includes cabinet body and door plant, the camera is used for installing on the wallboard and carrying out real-time supervision to the construction of built-in cabinet on the wallboard, still includes the board that holds, it is at holding tank or cabinet body along holding tank's depth direction sliding connection to accept the board, the door plant is along the direction of sliding connection who holds the board perpendicular to keeping away from holding tank diapire one end at accepting board, when the door plant is closed, the door plant is located the holding tank completely with accepting the board, when the door plant is opened, the door plant is located the holding tank outside and staggers with the holding tank notch.

Through adopting above-mentioned technical scheme, when operating personnel opens the door plant, earlier with the door plant and accept the board and keep away from holding tank bottom wall one side and pull out, make the door plant shift out the holding tank, then pull the door plant again, make door plant and holding tank notch stagger, through the mode of opening that changes the door plant, reduce the influence of door plant on the built-in cabinet to the cabinet body.

Preferably, the door panel further comprises a first driving part, an electromagnet and a control switch, wherein the electromagnet is positioned at the outer side of the accommodating groove and is rotationally connected in the wallboard, the first driving part drives the electromagnet to rotate, the rotating direction of the electromagnet is from one side close to the accommodating groove to one side far away from the accommodating groove, and the control switch is arranged on the door panel and is used for controlling the working state of the electromagnet;

the door plate is characterized in that a first magnetic block and a second magnetic block are arranged at different positions on the door plate, when the door plate is closed, the electromagnet rotates towards one side of the accommodating groove to be opposite to the first magnetic block, the electromagnet adsorbs the first magnetic block, when the door plate is opened, the electromagnet rotates towards one side far away from the bottom wall of the accommodating groove to be opposite to the second magnetic block, and the electromagnet adsorbs the second magnetic block.

Through adopting above-mentioned technical scheme, because the door plant is opened and the place difference when closing the state, through using driving piece one drive electromagnet to rotate, can carry out spacingly to the door plant under the different states, reduce the condition that the door plant removed.

Preferably, the first driving piece includes drive belt, first pivot, first gear and rack, it is located one side of the cabinet body to accept the board, the rack sets up on accepting the board and along being on a parallel with the slip direction sliding connection who accepts the board in the wallboard, first gear rotates to be connected in the wallboard, rack meshing is connected on first gear, first pivot coaxial fastening is on first gear, be equipped with the second pivot on the electro-magnet, first pivot and second pivot are all rotated and are connected in the wallboard, the drive belt is around rolling up in first pivot and second pivot.

Through adopting above-mentioned technical scheme, when operating personnel opens the door plant, when the door plant moves towards keeping away from holding tank diapire one side, the door plant can drive to accept the board and move towards keeping away from holding tank diapire one side, and it slides to accept the board again to drive the rack, and the rack drives first gear and first pivot through being connected with the meshing of first gear and rotates, then drives second gear and electro-magnet through the drive belt and rotates.

Preferably, a force application groove is formed in the side face of the door plate, far away from the cabinet body, a force application block for applying force by a hand is mounted on the force application groove, a first gap for a finger to extend in is reserved between the force application block and the side walls of the two sides of the force application groove, and a second gap for accommodating an arch finger is reserved between the force application block and the inner bottom wall of the force application groove.

Through adopting above-mentioned technical scheme, the cooperation of application of force piece and first clearance and second clearance can make things convenient for operating personnel to stimulate the door plant and promote the door plant.

Preferably, the device further comprises a second driving part and two baffles, wherein the baffles are provided with rotating rods, the rotating rods are rotationally connected to the force application blocks, the two baffles are respectively positioned at two sides of the force application blocks, the second driving part is used for driving the two baffles to rotate towards one side far away from the force application blocks to cover the two first gaps when no external force acts, and the baffles are far away from the second gaps when the baffles rotate towards one side of the force application blocks to be abutted to the force application blocks.

Through adopting above-mentioned technical scheme, two baffles are used for shielding two first clearances, can reduce the probability that the dust got into the application of force inslot, and after closing the door plant simultaneously, can make the door plant seem more pleasing to the eye.

Preferably, the locking device is further arranged on the rotating rod and synchronously connected with second gears, the two second gears are in meshed connection, and when the baffle rotates towards one side of the force application block to be abutted against the force application block and the door plate moves out of the accommodating groove, the locking device is used for locking the position of the force application block.

By adopting the technical scheme, the two second gears can facilitate the two baffles to synchronously rotate, and an operator can move away from the first gap no matter which baffle is forced by the operator; because the operator all need promote the baffle and rotate towards force application piece one side when removing the door plant each time, just so can stretch into the force application groove with the hand and carry out the application of force to force application piece, locking device can make the baffle remain the state of butt on force application piece all the time, and the operator need not all promote the baffle before the door plant application of force each time any more, can make things convenient for the operator to directly act on force application piece and remove the door plant.

Preferably, the locking device comprises a driving piece III, a moving block, a roller and an abutting block, wherein the moving block is slidably connected to the door plate along the axial direction parallel to the rotating shaft, the driving piece III drives the moving block to move towards one side of the top wall of the accommodating groove all the time, the abutting block is arranged on the moving block and is used for abutting against the second gear, the roller is rotationally connected to the moving block, the roller is used for abutting against the top wall of the accommodating groove and rotating along with the movement of the door plate in the accommodating groove, when the door plate is closed, the abutting block is far away from the second gear, and when the door plate is opened, the abutting block abuts against the bottom surface of the second gear and limits the rotation of the second gear.

Through adopting above-mentioned technical scheme, when the door plant is opened, the gyro wheel shifts out the holding tank after not having the restriction of holding tank roof, and three drive movable blocks of driving piece move up, and the movable block drives the butt piece and moves up and make the butt piece butt come the rotation of restriction second gear on the second gear, can lock the position of baffle this moment automatically.

The application provides a wallboard built-in cabinet based on real-time monitoring technology and a construction method thereof, which adopts the following technical scheme:

s1, a containing groove is formed in a wallboard, then a camera is installed on the wallboard, and the camera is enabled to face one side of the containing groove to monitor the construction of the built-in cabinet on the wallboard in real time;

s2, fixedly mounting the cabinet body in the accommodating groove, then slidably mounting the bearing plate on the accommodating groove, and finally mounting the door plate on the bearing plate;

s3: and debugging the installed built-in cabinet.

In summary, the present application includes at least one of the following beneficial technical effects:

through setting up the board that holds, when operating personnel opens the door plant, pull out door plant and the board that holds towards keeping away from holding tank bottom wall one side earlier, make the door plant shift out the holding tank, then pull the door plant again, make door plant and holding tank notch stagger, through changing the opening mode of door plant, reduce the influence of door plant on the built-in cabinet to the cabinet body;

through setting up locking device, because operating personnel all need promote the baffle and rotate towards application of force piece one side when removing the door plant each time, just so can stretch into the application of force groove with the hand and carry out the application of force to the application of force piece, locking device can make the baffle remain the state of butt on the application of force piece all the time, and operating personnel need not promote the baffle before all the time to the door plant application of force any more, can make things convenient for operating personnel direct action to remove the door plant on the application of force piece.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the related art.

Fig. 2 is a schematic view showing the whole structure of the door panel in the closed state according to the embodiment of the present application.

Fig. 3 is a schematic view showing a structure of an opened state of a door panel according to an embodiment of the present application.

Fig. 4 is a schematic structural view of a locking device and a door panel according to an embodiment of the present application.

Fig. 5 is a schematic diagram illustrating the cooperation of the electromagnet and the door panel when the door panel is in an open state according to the embodiment of the present application.

Fig. 6 is an enlarged view at a in fig. 4 of the embodiment of the present application.

Fig. 7 is a schematic diagram illustrating the cooperation of the electromagnet and the door panel when the door panel is in a closed state according to the embodiment of the present application.

Reference numerals illustrate: 1. a wallboard; 11. a receiving groove; 2. a built-in cabinet; 21. a door panel; 211. a force application groove; 212. a force application block; 213. a baffle; 214. a first gap; 215. a second gap; 216. a vertical groove; 217. a first magnetic block; 218. a second magnetic block; 22. a cabinet body; 221. a top plate; 222. a bottom plate; 223. a back plate; 224. a side plate; 225. a partition plate; 226. a chute; 23. a receiving plate; 231. a slide block; 24. a rotating rod; 25. a second driving piece; 251. a torsion spring; 26. a receiving shaft; 261. a conveyor belt; 262. a second gear; 27. a locking device; 271. a third driving member; 2711. a first spring; 272. a moving block; 273. a roller; 274. an abutment block; 2741. a connecting rod; 2742. abutting blocks; 2743. a through hole; 3. an electromagnet; 31. a second rotating shaft; 4. a first driving member; 41. a transmission belt; 42. a first rotating shaft; 43. a first gear; 44. a rack; 45. a fixing ring; 5. a camera; 51. a base; 52. ball head.

Detailed Description

The present application is described in further detail below in conjunction with figures 2-7.

The embodiment of the application discloses a wallboard built-in cabinet based on a real-time monitoring technology.

Referring to fig. 2 and 3, a built-in wall board cabinet based on a real-time monitoring technology in this embodiment includes a camera 5 and a built-in cabinet 2, a receiving groove 11 is formed on a side surface of a wall board 1, and the built-in cabinet 2 is used for being installed in the receiving groove 11 formed in the wall board 1.

Referring to fig. 3 and 4, the built-in cabinet 2 includes a cabinet body 22, a receiving plate 23, and a door panel 21, and the cabinet body 22 includes a top plate 221, a bottom plate 222, a back plate 223, side plates 224, and a plurality of partition plates 225. The length direction of the accommodating groove 11 is vertical, and the bottom end of the accommodating groove 11 is vertically downward and penetrates through the wallboard 1. The top plate 221 and the bottom plate 222 are respectively and fixedly connected to the top wall and the ground of the accommodating groove 11, the top plate 221 and the bottom plate 222 are opposite to each other, the back plate 223 is fixed on the inner bottom wall of one side of the accommodating groove 11 far away from the outside, and the upper end and the lower end of the back plate 223 are respectively and fixedly connected to the top plate 221 and the bottom plate 222. The side plate 224 is fixedly coupled to one side wall of the receiving groove 11, and three outer side walls of the side plate 224 are also fixed to the top plate 221, the bottom plate 222 and the rear plate 223. The plurality of separators 225 are uniformly fixed on the back plate 223 in the vertical direction, the separators 225 are horizontally arranged, and one end of the length direction of the separators 225 is fixed on the side plate 224.

Referring to fig. 3 and 4, the receiving plate 23 is slidably coupled to the receiving groove 11 in the depth direction of the receiving groove 11, and the side plate 224 is also slidably coupled to the top plate 221 and the bottom plate 222 in parallel to the depth direction of the receiving groove 11 in order to improve the sliding stability of the receiving plate 23. The side plate 224 and the receiving plate 23 are respectively located at both sides of the partition 225 in the longitudinal direction, and when the receiving plate 23 moves to abut against the bottom wall of the accommodating groove 11, the side plate 224 and the receiving plate 23 are disposed opposite to each other. Referring to fig. 4 and 5, in order to prevent the receiving plate 23 from sliding out of the receiving groove 11, a sliding groove 226 is formed in a side surface of the top plate 221 and the bottom plate 222 facing the receiving plate 23, two sliding blocks 231 corresponding to the two sliding grooves 226 are fixed on a side surface of the receiving plate 23 facing the top plate 221 and the bottom plate 222, and the sliding blocks 231 are slidably connected to the corresponding sliding grooves 226 along a sliding direction parallel to the receiving plate 23.

Referring to fig. 2 and 3, the door plate 21 is slidably connected to an end of the receiving plate 23 away from the bottom wall of the receiving groove 11 in a direction parallel to the length direction of the partition 225, and the sliding direction of the door plate 21 is perpendicular to the sliding direction of the receiving plate 23. When the door plate 21 is closed, the door plate 21 is abutted on one side surface of the top plate 221 and the bottom plate 222 far away from the bottom wall of the accommodating groove 11, the door plate 21 and the receiving plate 23 are completely positioned in the accommodating groove 11, the door plate 21 completely covers the notch of the accommodating groove 11, and one side surface of the door plate 21 far away from the bottom wall of the accommodating groove 11 is flush with the outer wall of the wallboard 1; when the door plate 21 is opened, the door plate 21 is located outside the accommodating groove 11 and is staggered with the notch of the accommodating groove 11, at this time, the sliding block 231 moves to be abutted on a side wall of the sliding groove 226 away from the bottom wall of the accommodating groove 11, and a side surface of the door plate 21 close to the bottom wall of the accommodating groove 11 is attached to the outer wall of the wallboard 1.

Referring to fig. 2 and 4, the camera 5 includes a base 51 and a ball 52 for photographing, the base 51 fixes the wall board 1 on one side surface of the receiving groove 11, the base 51 is located above the receiving groove 11, and the ball 52 is rotatably connected to the base 51 and is in interference fit with the base 51, so that the ball 52 can photograph different positions of a construction site. In the construction of the built-in cabinet 2, the ball 52 is rotated to the side facing the accommodating groove 11 and is used to monitor the construction of the built-in cabinet 2 on the wall board 1 in real time.

Referring to fig. 4 and 6, a force application groove 211 is formed in a side surface of the door plate 21, which is far from the bottom wall of the accommodating groove 11, a force application block 212 for applying force by a hand is mounted on the force application groove 211, the length direction of the force application block 212 is vertically arranged, and the upper end and the lower end of the force application block 212 are respectively and fixedly connected to the inner walls of the upper side and the lower side of the force application groove 211, and the side surface of the force application block 212, which is far from the bottom wall of the force application groove 211, is flush with the outer side surface of the door plate 21. A first gap 214 for the fingers to extend in is reserved between the force application block 212 and the side walls of the two sides of the force application groove 211 in the horizontal direction, and a second gap 215 for accommodating the arched fingers is reserved between the force application block 212 and the bottom wall of the force application groove 211. The operator can move the door plate 21 out of the accommodating groove 11 by pulling the urging block 212, and the operator can slide the door plate 21 on the receiving plate 23 by pushing the urging block 212.

Referring to fig. 4 and 6, two baffles 213 are rotatably connected to the force application block 212, the length direction of the baffles 213 is vertically arranged, one end of the width direction of the baffles 213 is fixed with a vertically arranged rotating rod 24, the two rotating rods 24 are respectively rotatably connected to two sides of the force application block 212, and the two baffles 213 are respectively positioned at two sides of the force application block 212. The second driving part 25 is arranged on the rotating rod 24, the second driving part 25 is a torsion spring 251, the torsion spring 251 is arranged on the rotating rod 24, when no external force acts, the rotating rod 24 rotates to cover the two first gaps 214 under the action of the torsion spring 251, and at the moment, one side surface of the two baffles 213 away from the bottom wall of the force application groove 211 is flush with the outer side surface of the door plate 21. When the force is required to be applied to the force application block 212, the operator rotates the baffle 213 toward the force application block 212 until the baffle 213 abuts against the force application block 212, and at this time, the side surface of the baffle 213 near the bottom wall of the accommodating groove 11 is flush with the side surface of the force application block 212 near the bottom wall of the accommodating groove 11.

Referring to fig. 4 and 6, the two baffles 213 are used to cover the two first gaps 214, so that the probability of dust entering the force application groove 211 can be reduced, and the door 21 can be more attractive when the door 21 is closed.

Referring to fig. 4 and 6, the door 21 is provided with a locking device 27, and the locking device 27 is used to lock the position of the force application block 212 when the shutter 213 rotates toward the force application block 212 to abut against the force application block 212 and the door 21 moves out of the accommodating groove 11. Since the operator needs to push the baffle 213 to rotate towards the force application block 212 when moving the door 21 each time, so that the operator can extend his hand into the force application groove 211 to apply force to the force application block 212, the locking device 27 can keep the baffle 213 in a state of being always abutted against the force application block 212, and the operator does not need to push the baffle 213 before applying force to the door 21 each time, so that the operator can conveniently and directly act on the force application block 212 to move the door 21.

Referring to fig. 4 and 6, the door panel 21 is rotatably connected with two receiving shafts 26, the two receiving shafts 26 respectively correspond to the two rotating rods 24, and the rotation axis direction of the receiving shafts 26 is parallel to the rotation axis direction of the rotating rods 24. The receiving shaft 26 is provided with a conveyor belt 261, and the conveyor belt 261 is wound around the corresponding receiving shaft 26 and the corresponding rotating lever 24. The receiving shaft 26 is fixedly connected with a second gear 262 coaxially, and the second gear 262 is connected to the rotating rod 24 through the receiving shaft 26 and the conveying belt 261. The two second gears 262 are engaged with each other. The two second gears 262 can facilitate the two baffles 213 to rotate synchronously, and the two baffles 213 can move to abut against the force application block 212 no matter the operator applies force to the baffle 213.

Referring to fig. 4 and 6, the locking device 27 includes a third driving member 271, a moving block 272, a roller 273, and two abutting blocks 274, a vertical slot 216 is formed in the door panel 21, and the moving block 272 is slidably connected in the vertical slot 216 in the vertical direction. The third driving part 271 is a plurality of first springs 2711, two ends of the first springs 2711 are respectively and fixedly connected to the bottom wall of the vertical groove 216 and the bottom wall of the moving block 272, and the first springs 2711 are always in a compressed state. The roller 273 is rotatably connected to the moving block 272, the rotation axis direction of the roller 273 is parallel to the length direction of the partition 225, and the roller 273 is located above the moving block 272. When no external force acts, the moving block 272 moves to be abutted against the top wall of the vertical groove 216 under the action of the first spring 2711, and the bottom ends of the rollers 273 move to extend out of the door plate 21 and are positioned above the door plate 21; when the door panel 21 is slidably coupled within the receiving groove 11, the rollers 273 can abut against the top wall of the receiving groove 11 and rotate following the movement of the door panel 21 within the receiving groove 11.

Referring to fig. 4 and 6, the abutment block 274 includes a connecting rod 2741 and an abutment block 2742, two ends of the connecting rod 2741 are respectively and fixedly connected to the moving block 272 and the corresponding abutment block 2742, a through hole 2743 is formed in the abutment block 2742, two abutment blocks 2742 respectively correspond to two receiving shafts 26, and the receiving shafts 26 are arranged on the corresponding through holes 2743 in a penetrating manner and are not in contact with the inner wall of the corresponding through holes 2743. The two abutting blocks 2742 correspond to the two second gears 262 respectively, and the abutting blocks 2742 are located right below the corresponding second gears 262 and are used for abutting against the corresponding second gears 262 to limit the rotation of the second gears 262.

Referring to fig. 4 and 6, when the door panel 21 is closed, the roller 273 abuts against the top wall of the accommodating groove 11, and the abutment 2742 is not in contact with the second gear 262, so that the shutter 213 can rotate under the action of external force or can shield the first gap 214 without the action of external force. When the door 21 is opened, the roller 273 moves out of the accommodating groove 11, the first spring 2711 drives the moving block 272 to move upwards, and the moving block 272 drives the abutting block 274 to move upwards, so that the abutting block 274 abuts against the second gear 262 to limit the rotation of the second gear 262, and at the moment, the position of the baffle 213 can be automatically locked.

Referring to fig. 5 and 7, the electromagnet 3 is rotationally connected to the wall board 1, the first driving member 4 for driving the electromagnet 3 to rotate is further arranged in the wall board 1, the second rotating shaft 31 is fixed at the end of the electromagnet 3, the second rotating shaft 31 is rotationally connected to the wall board 1 along the vertical direction, the electromagnet 3 is located at one side of the receiving board 23 far away from the cabinet 22, and the rotating direction of the electromagnet 3 is from one side close to the accommodating groove 11 to one side far away from the accommodating groove 11. The wall body is internally provided with a built-in power supply for supplying power to the electromagnet 3, the outer side of the door plate 21 is provided with a control switch, and the control switch is arranged on the door plate 21 and used for controlling the working state of the electromagnet 3.

Referring to fig. 5 and 7, a first magnetic block 217 and a second magnetic block 218 are fixed at different positions in the door panel 21. When the door 21 is closed, the electromagnet 3 can rotate toward the side of the accommodating groove 11 to face the first magnetic block 217, and the electromagnet 3 adsorbs the first magnetic block 217. The second magnetic block 218 is embedded in the side surface of the door plate 21, which is close to the accommodating groove 11, and meanwhile, the second magnetic block 218 is located at one end, close to the electromagnet 3, when the door plate 21 is in an open state, and when the door plate 21 is opened, the electromagnet 3 rotates to face the second magnetic block 218 towards the side, far away from the bottom wall of the accommodating groove 11, and at the moment, the electromagnet 3 adsorbs the second magnetic block 218.

Referring to fig. 5 and 7, since the door panels 21 are positioned differently when they are opened and closed, the door panels 21 in different states can be limited by driving the electromagnet 3 to rotate by the driving member one 4, so that the movement of the door panels 21 is reduced.

Referring to fig. 5 and 7, the first driving member 4 includes a driving belt 41, a first rotating shaft 42, a first gear 43 and a rack 44, the rack 44 is fixed on a side surface of the receiving plate 23 far away from the cabinet 22 and slidingly connected in the wall board 1 along a sliding direction parallel to the receiving plate 23, the first gear 43 is rotationally connected in the wall board 1 along a vertical axis direction, the rack 44 is engaged with and connected to the first gear 43, the first rotating shaft 42 is coaxially fixed on the first gear 43 and rotationally connected in the wall board 1, fixing rings 45 are coaxially sleeved on the first rotating shaft 42 and the second rotating shaft 31, the diameter of the fixing ring 45 on the first rotating shaft 42 is larger than that on the second rotating shaft 31, and the driving belt 41 is wound on the two fixing rings 45.

Referring to fig. 5 and 7, when an operator opens the door plate 21, the door plate 21 moves towards the side far away from the bottom wall of the accommodating groove 11, the door plate 21 drives the receiving plate 23 to move towards the side far away from the bottom wall of the accommodating groove 11, the receiving plate 23 drives the rack 44 to slide, the rack 44 drives the first gear 43 and the first rotating shaft 42 to rotate through meshed connection with the first gear 43, and then the electromagnet 3 is driven to rotate through the driving belt 41, so that the electromagnet 3 can rotate to a specific position to position and adsorb the door plate 21 along with the state change of the door plate 21.

The embodiment also discloses a wallboard built-in cabinet based on the real-time monitoring technology and a construction method thereof: the method comprises the following steps:

s1, an accommodating groove 11 is formed in a wallboard 1, then a camera 5 is installed on the wallboard 1, and the camera 5 is enabled to face one side of the accommodating groove 11 to monitor the construction of a built-in cabinet 2 on the wallboard 1 in real time;

s2, fixedly mounting the cabinet 22 in the accommodating groove 11, then slidably mounting the bearing plate 23 on the accommodating groove 11, and finally mounting the door plate 21 on the bearing plate 23;

s3: and debugging the built-in cabinet 2 after being installed.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (7)

1. The utility model provides a wallboard built-in cabinet based on real time monitoring technique, includes camera (5) and built-in cabinet (2), built-in cabinet (2) are used for installing in holding tank (11) that wallboard (1) were seted up, built-in cabinet (2) are including cabinet body (22) and door plant (21), camera (5) are used for installing on wallboard (1) and carry out real time monitoring to the construction of built-in cabinet (2) on wallboard (1), its characterized in that: the door plate (21) is connected to one end of the receiving plate (23) far away from the bottom wall of the containing groove (11) along the sliding direction perpendicular to the receiving plate (23), when the door plate (21) is closed, the door plate (21) and the receiving plate (23) are completely located in the containing groove (11), and when the door plate (21) is opened, the door plate (21) is located on the outer side of the containing groove (11) and staggered with the notch of the containing groove (11);

the door panel comprises a door panel body, a wall panel (1) and a door panel (21), and is characterized by further comprising a first driving part (4), an electromagnet (3) and a control switch, wherein the electromagnet (3) is positioned at the outer side of the accommodating groove (11) and is rotationally connected in the wall panel (1), the first driving part (4) drives the electromagnet (3) to rotate, the rotating direction of the electromagnet (3) is from one side close to the accommodating groove (11) to one side far away from the accommodating groove (11), and the control switch is arranged on the door panel (21) and is used for controlling the working state of the electromagnet (3);

the door plate (21) is provided with a first magnetic block (217) and a second magnetic block (218) at different positions, when the door plate (21) is closed, the electromagnet (3) rotates towards one side of the accommodating groove (11) to be opposite to the first magnetic block (217), the electromagnet (3) adsorbs the first magnetic block (217), when the door plate (21) is opened, the electromagnet (3) rotates towards one side far away from the bottom wall of the accommodating groove (11) to be opposite to the second magnetic block (218), and the electromagnet (3) adsorbs the second magnetic block (218).

2. The wallboard built-in cabinet based on the real-time monitoring technology as claimed in claim 1, wherein: the first driving piece (4) comprises a driving belt (41), a first rotating shaft (42), a first gear (43) and a rack (44), the bearing plate (23) is located on one side of the cabinet body (22), the rack (44) is arranged on the bearing plate (23) and is slidably connected in the wallboard (1) along the sliding direction parallel to the bearing plate (23), the first gear (43) is rotatably connected in the wallboard (1), the rack (44) is meshed and connected on the first gear (43), the first rotating shaft (42) is coaxially fixed on the first gear (43), the electromagnet (3) is provided with a second rotating shaft (31), the first rotating shaft (42) and the second rotating shaft (31) are rotatably connected in the wallboard (1), and the driving belt (41) is wound on the first rotating shaft (42) and the second rotating shaft (31).

3. The wallboard built-in cabinet based on the real-time monitoring technology as claimed in claim 1, wherein: the door plate (21) is far away from the side surface of one side of the cabinet body (22) and is provided with a force application groove (211), a force application block (212) for applying force by a hand is arranged on the force application groove (211), a first gap (214) for extending fingers is reserved between the force application block (212) and the side walls of the two sides of the force application groove (211), and a second gap (215) for accommodating arched fingers is reserved between the force application block (212) and the inner bottom wall of the force application groove (211).

4. A wall panel built-in cabinet based on a real-time monitoring technology according to claim 3, wherein: still include driver two (25) and two baffles (213), be equipped with bull stick (24) on baffle (213), bull stick (24) rotate and connect on application of force piece (212), two baffles (213) are located the both sides of application of force piece (212) respectively, driver two (25) are used for driving two baffles (213) and are kept away from application of force piece (212) one side and rotate to shelter from two first clearance (214) when no exogenic action, when baffle (213) are rotated to the butt on application of force piece (212) towards application of force piece (212) one side, baffle (213) are kept away from second clearance (215).

5. The wallboard built-in cabinet based on the real-time monitoring technology as set forth in claim 4, wherein: the locking device (27) is connected to the second gears (262) in a synchronous rotation mode on the rotating rod (24), the two second gears (262) are connected in a meshed mode, and when the baffle plate (213) rotates towards one side of the force application block (212) to be abutted to the force application block (212) and the door plate (21) moves out of the accommodating groove (11), the locking device (27) is used for locking the position of the force application block (212).

6. The wallboard built-in cabinet based on the real-time monitoring technology according to claim 5, wherein: the locking device (27) comprises a driving part III (271), a moving block (272), a roller (273) and an abutting block (274), wherein the moving block (272) is connected to the door plate (21) in a sliding mode along the axial direction parallel to the rotating shaft, the driving part III (271) drives the moving block (272) to move towards one side of the top wall of the accommodating groove (11) all the time, the abutting block (274) is arranged on the moving block (272) and is used for abutting against the second gear (262), the roller (273) is connected to the moving block (272) in a rotating mode, the roller (273) is used for abutting against the top wall of the accommodating groove (11) and rotating along with the movement of the door plate (21) in the accommodating groove (11), when the door plate (21) is closed, the abutting block (274) is far away from the second gear (262), and when the door plate (21) is opened, the abutting block (274) abuts against the bottom surface of the second gear (262) and limits the rotation of the second gear (262).

7. The wallboard built-in cabinet based on the real-time monitoring technology and the construction method thereof according to any one of claims 1-6, comprising the following steps:

s1, a containing groove (11) is formed in a wallboard (1), then a camera (5) is installed on the wallboard (1), and the camera (5) is enabled to face one side of the containing groove (11) to monitor construction of a built-in cabinet (2) on the wallboard (1) in real time;

s2, fixedly mounting the cabinet body (22) in the accommodating groove (11), then slidably mounting the bearing plate (23) on the accommodating groove (11), and finally mounting the door plate (21) on the bearing plate (23);

s3: and debugging the installed built-in cabinet (2).