CN118139391A - Assembled building BIM module management device and management method thereof - Google Patents

Abstract

The invention relates to the technical field of building BIM modules, and particularly discloses an assembled building BIM module management device and a management method thereof, wherein the management method comprises the following steps: the device comprises a cabinet shell, a door body, a controller, a BIM module mechanism, an emergency cooling mechanism and a refrigerating fan; the door body is arranged on the front side of the cabinet shell; the controller is arranged at the front side of the door body; the two BIM module mechanisms are respectively arranged at the left end and the right end of the inner front side of the cabinet shell from top to bottom; the emergency cooling mechanism is arranged in the inner cavity of the cabinet shell and is positioned at the rear side of the BIM module mechanism; the refrigerating fan is arranged on the left side of the cabinet shell, and the refrigerating fan is electrically connected with the controller. The invention can ensure the running working state of other BIM modules, effectively discharge the redundant heat to the outside for a single BIM module, avoid equipment damage caused by exceeding a threshold value, realize rapid cooling for a specific BIM module in an auxiliary mode, reduce the damage risk and prolong the service life of the equipment.

Description

Assembled building BIM module management device and management method thereof

Technical Field

The invention relates to the technical field of building BIM modules, in particular to an assembled building BIM module management device and a management method thereof.

Background

The BIM module is a component part in the building information model, can be understood as a tool in BIM software, is specially used for creating, editing, inquiring or managing model data of a certain specific aspect, has a steel structure module, an electric module, a pipeline module, a heating ventilation air conditioning module and the like, can help a user to more easily treat design and construction problems in the same field, and can comprehensively consider various factors on a platform by using the BIM module, optimize a design scheme and improve construction efficiency, thereby achieving the purposes of saving time, reducing cost and improving quality, and meanwhile, the BIM module can be integrated with other modules to form a complete building information model so as to provide support for digital transformation of the building industry;

In the prior art, in the operation process of the BIM module, electrical equipment in the BIM module is integrated inside the cabinet, and because a large amount of heat is generated when the electrical equipment in the BIM module works, if the heat exceeds a set threshold value for a long time, serious damage can be caused to the equipment, in order to ensure normal operation and prolonged service life of the equipment, the extra heat must be effectively controlled and removed as soon as possible, and the cabinet with the external BIM module at present only depends on an integral cooling and heat dissipation mode, and cannot conduct rapid cooling and heat dissipation on a single abnormal BIM module.

Disclosure of Invention

The present invention is directed to an assembled building BIM module management device and a management method thereof, so as to solve the above-mentioned problems in the background art.

In order to achieve the above purpose, the present invention provides the following technical solutions: an assembled building BIM module management device, comprising: the device comprises a cabinet shell, a door body, a controller, a BIM module mechanism, an emergency cooling mechanism and a refrigerating fan; the door body is arranged on the front side of the cabinet shell; the controller is arranged at the front side of the door body; the number of the BIM module mechanisms is two, the number of each BIM module mechanism is four, and the two BIM module mechanisms are respectively arranged at the left end and the right end of the inner front side of the cabinet shell from top to bottom; the emergency cooling mechanism is arranged in the inner cavity of the cabinet shell and is positioned at the rear side of the BIM module mechanism; the refrigerating fan is arranged on the left side of the cabinet shell, and the refrigerating fan is electrically connected with the controller.

Preferably, the emergency cooling mechanism comprises: the device comprises a rail, a rail moving module, a multi-stage telescopic module and an installation transverse plate; the track is arranged at the rear side of the inner top end of the cabinet shell along the left-right direction; the track moving module is arranged outside the track and is electrically connected with the controller; the multi-stage telescopic module is arranged at the center of the bottom end of the track moving module along the up-down direction, and is electrically connected with the controller; the mounting transverse plate is arranged at the bottom of the telescopic end of the multi-stage telescopic module along the left-right direction; wherein, the bottom left and right sides of installation diaphragm all is provided with folding subassembly to two folding subassembly fronts all are provided with the cooling subassembly about.

Preferably, the BIM module mechanism includes: the device comprises a device shell, a BIM module, a wiring board, a temperature sensor, a frame, a telescopic guide rail and a first electric push rod; the equipment shell is arranged in the cabinet shell along the front-back direction, and the back side of the equipment shell is communicated with the outside; the BIM module is arranged at the bottom end of the equipment shell; the wiring board is arranged at the rear side of the interior of the equipment shell, the wiring board is electrically connected with the equipment shell and the BIM module, and the wiring board is electrically connected with the controller; the temperature sensor is arranged at the center of the top end of the front side of the wiring board and is electrically connected with the wiring board; the frame is arranged in the middle of the front side of the wiring board; the number of the telescopic guide rails is two, the number of each telescopic guide rail is two, the two telescopic guide rails are respectively arranged on the upper side and the lower side of the left end and the right end of the frame from front to back, and the outer sides of the two telescopic guide rails are connected with the inner wall of the equipment shell; the number of the first electric push rods is two, the two first electric push rods are respectively arranged at the center positions of the left side and the right side of the inner wall of the equipment shell from front to back, the telescopic ends of the two first electric push rods are respectively connected with the middle parts of the left side and the right side of the frame, and the first electric push rods are electrically connected with the wiring board.

Preferably, the folding assembly includes: the device comprises a first mounting seat, a first rotating rod, a second rotating rod, a first motor and a connecting seat; the first mounting seat is arranged outside the bottom end of the mounting transverse plate; one end of the first rotating rod is rotationally connected to the front end of the inner side of the first mounting seat through a pin shaft; one end of the second rotating rod is rotationally connected with the rear end of the inner side of the first mounting seat through a pin shaft; the first motor is arranged at the left rear end of the first mounting seat, the rotating end of the first motor extends into the inner side of the first mounting seat and is connected with the axle center of the second rotating rod, and the first motor is electrically connected with the controller; the connecting seat is rotationally connected with the other ends of the first rotating rod and the second rotating rod through pin shafts.

Preferably, the cooling component comprises: the device comprises a first mounting plate, a first fixing seat, a second electric push rod, a second fixing seat, a rotating frame, a connecting rod, a limiting bracket, a third electric push rod and a second mounting plate; the first mounting plate is mounted on the front side of the connecting seat along the front-rear direction; the first fixing seat is arranged at the left rear side of the top end of the first mounting plate; the second electric push rod is rotationally connected to the inner side of the first fixing seat through a pin shaft, and is electrically connected with the controller; the second fixing seat is arranged in the middle of the top end of the first mounting seat; the rotating frame is rotationally connected to the inner side of the second fixing seat through a pin shaft; one end of the connecting rod is rotationally connected with the telescopic end of the second electric push rod through a pin shaft, and the other end of the connecting rod is fixedly connected with the left side of the rotating frame; the limiting bracket is arranged on the front side of the top end of the first mounting plate, and the upper surface of the limiting bracket is contacted with the front side of the bottom end of the rotating frame; the third electric push rod is arranged at the top of the rotating frame along the front-back direction, and is electrically connected with the controller; the second mounting plate is mounted on the front side of the telescopic end of the third electric push rod.

Preferably, the cooling assembly further comprises: the spray head comprises a second mounting seat, a second motor, a mounting seat and a spray head pipe; the second mounting seat is arranged on the front side of the second mounting plate; the number of the second motors is two, the two second motors are respectively arranged at the left end and the right end of the inner side of the second mounting seat, the rotating ends of the two second motors extend out of the outer sides of the second mounting seat, and the second motors are electrically connected with the controller; the mounting seats are arranged at the outer sides of the rotating ends of the left motor and the right motor; the shower nozzle pipe sets up along left and right directions the front side of mount pad, shower nozzle pipe and refrigerating fan are connected through the pipeline.

Preferably, the second motor can drive the mounting seat to drive the spray head pipe to swing back and forth outside the second mounting seat, so that the range of cold air sprayed out of the spray head pipe is increased.

Compared with the prior art, the invention has the beneficial effects that:

1. The temperature state of the BIM module in the equipment shell is detected through the temperature sensor, the first electric push rod stretches to drive the frame to move towards the rear side, the frame moves towards the rear side when pushing the wiring board, and the wiring board stops sealing the rear side in the equipment shell.

2. Through track movement module drive folding subassembly and cooling subassembly horizontal migration, multistage flexible module drive installation diaphragm drives folding subassembly and cooling subassembly and descends to appointed high position, first motor drive second dwang drives the connecting seat and stretches into cooling subassembly forward side to inside the equipment shell, second electric putter drive connecting rod drives the rotating turret and overturn downwards, third electric putter drive second mounting panel is moved forward side and is made the shower nozzle pipe to being close to the BIM module, second motor drive mount pad drives shower nozzle pipe up-and-down reciprocating swing in the second mount pad outside, in order to improve shower nozzle pipe blowout scope, realize the supplementary cooling to the BIM module.

In summary, the invention can ensure the operation working state of other BIM modules, realize that the redundant heat is effectively discharged to the outside for a single BIM module, avoid the damage to equipment caused by exceeding a threshold value, realize rapid cooling for a specific BIM module by adopting an auxiliary mode, reduce the damage risk and prolong the service life of the equipment.

Drawings

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

FIG. 2 is an exploded view of FIG. 1;

FIG. 3 is an exploded view of the BIM module mechanism of FIG. 2;

FIG. 4 is an exploded view of the emergency cooling mechanism of FIG. 2;

FIG. 5 is an enlarged view at A of FIG. 4;

Fig. 6 is an enlarged view at B of fig. 4.

In the figure: 1. a cabinet housing; 2. a door body; 3. a controller; 4. a BIM module mechanism; 41. an equipment housing; 42. a BIM module; 43. a wiring board; 44. a temperature sensor; 45. a frame; 46. a telescopic guide rail; 47. a first electrical push rod; 5. an emergency cooling mechanism; 51. a track; 52. a track movement module; 53. a multi-stage expansion module; 54. mounting a transverse plate; 55. a first mount; 56. a first rotating lever; 57. a second rotating lever; 58. a first motor; 59. a connecting seat; 510. a first mounting plate; 511. a first fixing seat; 512. a second electric push rod; 513. the second fixing seat; 514. a rotating frame; 515. a connecting rod; 516. a limit bracket; 517. a third electric push rod; 518. a second mounting plate; 519. a second mounting base; 520. a second motor; 521. a mounting base; 522. a shower nozzle pipe; 6. a refrigerating fan.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-6, the present invention provides a technical solution: an assembled building BIM module management device, comprising: the equipment cabinet comprises an equipment cabinet shell 1, a door body 2, a controller 3, a BIM module mechanism 4, an emergency cooling mechanism 5 and a refrigerating fan 6, wherein different types of heat dissipation systems can be built in the equipment cabinet shell 1 and replaced according to actual needs; the door body 2 is arranged on the front side of the cabinet shell 1; the controller 3 is arranged at the front side of the door body 2, and a program is arranged in the controller 3 to automatically carry out logic control on electric devices in the device; the number of the BIM module mechanisms 4 is two, the number of each BIM module mechanism 4 is four, and the two BIM module mechanisms 4 are respectively arranged at the left end and the right end of the inner front side of the cabinet shell 1 from top to bottom; the emergency cooling mechanism 5 is arranged in the inner cavity of the cabinet shell 1 and is positioned at the rear side of the BIM module mechanism 4; the refrigerating fan 6 is installed on the left side of the cabinet shell 1, the refrigerating fan 6 is electrically connected with the controller 3, the refrigerating fan 6 is controlled by the controller 3, low-temperature gas can be generated inside the refrigerating fan 6, and the low-temperature gas enters the spray head pipe 522 through a connecting pipeline.

Preferably, as shown in fig. 3, the BIM module mechanism 4 further includes: device housing 41, BIM module 42, wiring board 43, temperature sensor 44, frame 45, telescoping rail 46, and first electrical pushrod 47; the equipment shell 41 is arranged in the cabinet shell 1 along the front-back direction, the back side of the equipment shell 41 is communicated with the outside, and different heat dissipation systems can be built in the equipment shell 41 and replaced according to actual needs; BIM module 42 is mounted at the inner bottom end of device housing 41; the wiring board 43 is arranged at the rear side of the equipment shell 41, the wiring board 43 is electrically connected with the equipment shell 41 and the BIM module 42, the wiring board 43 is electrically connected with the controller 3, the wiring board 43 plays a role in transferring connection between an electric device in the BIM module mechanism 4 and the controller 3, and the electric connection circuit between the wiring board 43 and the electric device in the BIM module mechanism 4 is reserved with enough telescopic length; the temperature sensor 44 is arranged at the center of the top end of the front side of the wiring board 43, the temperature sensor 44 is electrically connected with the wiring board 43, the temperature sensor 44 is connected with the controller 3 through the wiring board 43, the temperature sensor 44 detects the temperature state of the BIM module 42 in the equipment shell 41 in the working process, and when the fact that the temperature in the equipment shell 41 is too high due to the working of the BIM module 42 is found, the temperature sensor 44 sends a signal to the controller 3; the frame 45 is installed at the front middle of the wiring board 43; the number of the telescopic guide rails 46 is two, the number of each telescopic guide rail 46 is two, the two telescopic guide rails 46 are respectively arranged on the upper side and the lower side of the left end and the right end of the frame 45 from front to back, the outer sides of the two telescopic guide rails 46 are connected with the inner wall of the equipment shell 41, and the telescopic guide rails 46 can perform multistage telescopic operation; the number of the first electric push rods 47 is two, the two first electric push rods 47 are respectively arranged at the center positions of the left side and the right side of the inner wall of the equipment shell 41 from front to back, the telescopic ends of the two first electric push rods 47 are respectively connected with the middle parts of the left side and the right side of the frame 45, the first electric push rods 47 are electrically connected with the wiring board 43, the first electric push rods 47 are connected with the controller 3 through the wiring board 43, the first electric push rods 47 are controlled by the controller 3, and the first electric push rods 47 stretch and shorten the driving frame 45 to move back and forth through self.

As a preferred embodiment, as shown in fig. 4, 5 and 6, the emergency cooling mechanism 5 includes: a rail 51, a rail moving module 52, a multi-stage telescopic module 53, and a mounting cross plate 54; the rail 51 is installed at the rear side of the inner tip end of the cabinet housing 1 in the left-right direction; the track moving module 52 is arranged outside the track 51, the track moving module 52 is electrically connected with the controller 3, the track moving module 52 is controlled by the controller 3, and the track moving module 52 can horizontally move along the left-right direction outside the track 51; the multi-stage telescopic module 53 is arranged at the center of the bottom end of the track moving module 52 along the up-down direction, the multi-stage telescopic module 53 is electrically connected with the controller 3, the multi-stage telescopic module 53 is controlled by the controller 3, and the multi-stage telescopic module 53 can perform multi-stage telescopic to drive the mounting transverse plate 54 to lift to a designated height position; the mounting cross plate 54 is arranged at the bottom of the telescopic end of the multi-stage telescopic module 53 along the left-right direction; wherein, the bottom left and right sides of installation diaphragm 54 all is provided with folding subassembly, and folding subassembly includes: a first mount 55, a first rotating lever 56, a second rotating lever 57, a first motor 58, and a connection base 59; the first mount 55 is mounted outside the bottom end of the mounting cross plate 54; one end of a first rotating rod 56 is rotatably connected to the front end of the inner side of the first mounting seat 55 through a pin shaft; one end of the second rotating rod 57 is rotatably connected to the inner rear end of the first mounting seat 55 through a pin shaft; the first motor 58 is mounted at the left rear end of the first mounting seat 55, the rotating end of the first motor 58 extends into the inner side of the first mounting seat 55 and is connected with the axle center of the second rotating rod 57, the first motor 58 is electrically connected with the controller 3, the first motor 58 is controlled by the controller 3, and the first motor 58 drives the second rotating rod 57 to rotate clockwise or anticlockwise; the connecting seat 59 is rotatably connected to the other ends of the first rotating rod 56 and the second rotating rod 57 through a pin shaft; and all be provided with the cooling subassembly in two folding subassembly fronts about, the cooling subassembly includes: the first mounting plate 510, the first fixing seat 511, the second electric push rod 512, the second fixing seat 513, the rotating frame 514, the connecting rod 515, the limit bracket 516, the third electric push rod 517, the second mounting plate 518, the second mounting seat 519, the second motor 520, the mounting seat 521 and the nozzle pipe 522; the first mounting plate 510 is mounted on the front side of the connection seat 59 in the front-rear direction; the first fixing seat 511 is provided at the top left rear side of the first mounting plate 510; the second electric push rod 512 is rotatably connected to the inner side of the first fixing seat 511 through a pin shaft, the second electric push rod 512 is electrically connected with the controller 3, the second electric push rod 512 is controlled by the controller 3, the second electric push rod 512 can rotate on the inner side of the first fixing seat 511 in the process of self-stretching and shortening, and one end of the second electric push rod 512 drives the connecting rod 515 to rotate through self-stretching and shortening; the second fixing seat 513 is installed in the middle of the top end of the first installation seat 55; the rotating frame 514 is rotatably connected to the inner side of the second fixed seat 513 through a pin shaft, and the rotating frame 514 can rotate on the inner side of the second fixed seat 513; one end of the connecting rod 515 is rotatably connected to the telescopic end of the second electric push rod 512 through a pin shaft, and the other end of the connecting rod 515 is fixedly connected with the left side of the rotating frame 514; the limiting bracket 516 is mounted on the front side of the top end of the first mounting plate 510, and the upper surface of the limiting bracket 516 is contacted with the front side of the bottom end of the rotating frame 514; the third electric push rod 517 is arranged at the top of the rotating frame 514 along the front-back direction, and the third electric push rod 517 is electrically connected with the controller 3; the second mounting plate 518 is mounted on the front side of the telescopic end of the third electric push rod 517; the second mounting seat 519 is mounted on the front side of the second mounting plate 518; the number of the second motors 520 is two, the two second motors 520 are respectively arranged at the left end and the right end of the inner side of the second mounting seat 519, the rotating ends of the two second motors 520 extend out of the outer side of the second mounting seat 519, the second motors 520 are electrically connected with the controller 3, the second motors 520 are controlled by the controller 3, and the second motors 520 can drive the mounting seat 521 to rotate clockwise or anticlockwise; the mounting bases 521 are disposed outside the rotating ends of the left and right second motors 520; the nozzle pipe 522 is provided at the front side of the mounting seat 521 in the left-right direction, and the nozzle pipe 522 and the cooling fan 6 are connected by a pipe.

A BIM module management method for an assembled building comprises the following steps:

Step one: when the BIM module 42 works, heat is radiated through the built-in heat radiation systems of the equipment shell 41 and the cabinet shell 1, and the temperature sensor 44 monitors the working temperature of the equipment in real time by detecting the temperature state of the BIM module 42 inside the equipment shell 41;

Step two: when the temperature sensor 44 detects that the internal temperature of the equipment shell 41 exceeds a set threshold value, an alarm signal is immediately sent to the controller 3, and after the controller 3 receives the alarm signal, the first electric push rod 47 is started to execute the next operation according to the judgment of the preset program logic;

Step three: after the first electric push rod 47 is started, the frame 45 moves to the rear side stably by extending the driving frame 45, the frame 45 moves along the limit position of the telescopic guide rail 46, and the terminal board 43 completely blocks the sealing of the rear side inside the equipment shell 41 after being pushed, so that heat generated in the working process of the BIM module 42 can be effectively dissipated, and the aim of auxiliary heat dissipation and ventilation is fulfilled;

step four: the controller 3 controls the track moving module 52, the multi-stage telescopic module 53, the first motor 58, the second electric push rod 512, the refrigerating fan 6 and the second mounting seat 519 to start and execute the next operation according to the preset program logic judgment;

Step five: the track moving module 52 moves horizontally along the outside of the track 51 to move the folding assembly and the cooling assembly to the correct positions, the multi-stage telescopic module 53 stretches to drive the mounting transverse plate 54 to descend to the designated height position, so that the folding assembly and the cooling assembly are driven and inserted into the inner side of the frame 45 in the BIM module mechanism 4 at the designated positions;

step six: the first motor 58 drives the second rotating rod 57 to rotate clockwise, so that the connecting seat 59 moves forwards, and the cooling component is inserted into the equipment shell 41 to be ready for the subsequent cooling operation;

Step seven: the second electric push rod 512 is shortened, one end of the driving connecting rod 515 is rotated upwards, the rotating frame 514 is contacted with the top of the limiting bracket 516 to realize overturning, the third electric push rod 517 is extended, the second mounting plate 518 is driven to move forwards, the spray head pipe 522 is close to the BIM module 42, and preparation is made for cooling operation;

Step eight: the low-temperature gas in the refrigerating fan 6 enters the spray head pipe 522 through the connecting pipeline, is sprayed out of the spray head pipe 522 to cool the inside of the track 51 in the equipment shell 41, and the second motor 520 drives the mounting seat 521 to drive the spray head pipe 522 to reciprocate up and down, so that the spraying range is increased, the wider cooling coverage range of the BIM module 42 is realized, and the temperature control effect of the equipment is ensured;

Step nine: when the temperature sensor 44 detects that the temperature inside the equipment housing 41 is restored below the set threshold, the nozzle pipe 522 moves out of the equipment housing 41, and the wiring board 43 seals the rear side inside the equipment housing 41 again, so that the operating state of the BIM module 42 is ensured.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. An assembled building BIM module management device, comprising:

A cabinet housing (1);

the door body (2) is arranged at the front side of the cabinet shell (1);

The controller (3) is arranged at the front side of the door body (2);

The BIM module mechanisms (4) are two groups, each group of BIM module mechanisms (4) is four, and the two groups of BIM module mechanisms (4) are respectively arranged at the left end and the right end of the inner front side of the cabinet shell (1) from top to bottom;

the emergency cooling mechanism (5) is arranged in the inner cavity of the cabinet shell (1) and is positioned at the rear side of the BIM module mechanism (4);

the refrigerating fan (6) is arranged at the left side of the cabinet shell (1), and the refrigerating fan (6) is electrically connected with the controller (3);

The emergency cooling mechanism (5) comprises:

a rail (51) installed at the rear side of the inner top end of the cabinet housing (1) in the left-right direction;

The track moving module (52) is arranged outside the track (51), and the track moving module (52) is electrically connected with the controller (3);

the multistage telescopic module (53) is arranged at the bottom center of the track moving module (52) along the up-down direction, and the multistage telescopic module (53) is electrically connected with the controller (3);

the mounting transverse plate (54) is arranged at the bottom of the telescopic end of the multi-stage telescopic module (53) along the left-right direction;

Wherein, the bottom left and right sides of installation diaphragm (54) all is provided with folding subassembly to two folding subassembly fronts all are provided with the cooling subassembly about.

2. A building in assembly BIM module management arrangement according to claim 1, wherein the BIM module mechanism (4) includes:

An equipment housing (41) installed inside the cabinet housing (1) in the front-rear direction, the inside rear side of the equipment housing (41) being communicated with the outside;

A BIM module (42) mounted at the inner bottom end of the equipment housing (41);

the wiring board (43) is arranged at the rear side of the inside of the equipment shell (41), the wiring board (43) is electrically connected with the equipment shell (41) and the BIM module (42), and the wiring board (43) is electrically connected with the controller (3);

the temperature sensor (44) is arranged at the center of the front top end of the wiring board (43), and the temperature sensor (44) is electrically connected with the wiring board (43);

A frame (45) mounted in the middle of the front side of the wiring board (43);

The number of the telescopic guide rails (46) is two, the number of each telescopic guide rail (46) is two, the two telescopic guide rails (46) are respectively arranged on the upper side and the lower side of the left end and the right end of the frame (45) from front to back, and the outer sides of the two telescopic guide rails (46) are connected with the inner wall of the equipment shell (41);

The number of the first electric pushing rods (47) is two, the two first electric pushing rods (47) are respectively arranged at the center positions of the left side and the right side of the inner wall of the equipment shell (41) from front to back, the telescopic ends of the two first electric pushing rods (47) are respectively connected with the middle parts of the left side and the right side of the frame (45), and the first electric pushing rods (47) are electrically connected with the wiring board (43).

3. The fabricated building BIM module management device of claim 2, wherein the folding assembly includes:

a first mounting seat (55) mounted outside the bottom end of the mounting cross plate (54);

one end of the first rotating rod (56) is rotationally connected to the front end of the inner side of the first mounting seat (55) through a pin shaft;

One end of the second rotating rod (57) is rotationally connected to the rear end of the inner side of the first mounting seat (55) through a pin shaft;

The first motor (58) is arranged at the left rear end of the first mounting seat (55), the rotating end of the first motor (58) extends into the inner side of the first mounting seat (55) and is connected with the axle center of the second rotating rod (57), and the first motor (58) is electrically connected with the controller (3);

The connecting seat (59) is rotatably connected to the other ends of the first rotating rod (56) and the second rotating rod (57) through a pin shaft.

4. A modular building BIM module management apparatus according to claim 3, wherein the cooling assembly includes:

A first mounting plate (510) mounted on the front side of the connection base (59) in the front-rear direction;

The first fixing seat (511) is arranged at the left rear side of the top end of the first mounting plate (510);

The second electric push rod (512) is rotationally connected to the inner side of the first fixing seat (511) through a pin shaft, and the second electric push rod (512) is electrically connected with the controller (3);

The second fixing seat (513) is arranged in the middle of the top end of the first mounting seat (55);

The rotating frame (514) is rotationally connected to the inner side of the second fixed seat (513) through a pin shaft;

One end of the connecting rod (515) is rotationally connected with the telescopic end of the second electric push rod (512) through a pin shaft, and the other end of the connecting rod (515) is fixedly connected with the left side of the rotating frame (514);

The limiting bracket (516) is arranged on the front side of the top end of the first mounting plate (510), and the upper surface of the limiting bracket (516) is contacted with the front side of the bottom end of the rotating frame (514);

The third electric push rod (517) is arranged at the top of the rotating frame (514) along the front-back direction, and the third electric push rod (517) is electrically connected with the controller (3);

and a second mounting plate (518) mounted on the front side of the telescopic end of the third electric push rod (517).

5. The modular building BIM module management apparatus of claim 4, wherein the cooling assembly further comprises:

a second mounting seat (519) mounted on the front side of the second mounting plate (518);

The number of the second motors (520) is two, the two second motors (520) are respectively arranged at the left end and the right end of the inner side of the second mounting seat (519), the rotating ends of the two second motors (520) extend out of the outer side of the second mounting seat (519), and the second motors (520) are electrically connected with the controller (3);

Mounting bases (521) arranged outside the rotating ends of the left and right second motors (520);

The spray head pipe (522) is arranged at the front side of the mounting seat (521) along the left-right direction, and the spray head pipe (522) is connected with the refrigerating fan (6) through a pipeline.

6. The assembled building BIM module management device of claim 5, wherein the second motor (520) can drive the mounting base (521) to drive the shower nozzle pipe (522) to swing reciprocally outside the second mounting base (519), so as to increase the range of cold air sprayed by the shower nozzle pipe (522).

7. An assembled building BIM module management method applied to the assembled building BIM module management device according to claim 6, comprising the following steps:

Step one: when the BIM module (42) works, heat is dissipated through the built-in heat dissipation systems of the equipment shell (41) and the cabinet shell (1), and the temperature sensor (44) monitors the working temperature of the equipment in real time by detecting the temperature state of the BIM module (42) inside the equipment shell (41);

Step two: when the temperature sensor (44) detects that the internal temperature of the equipment shell (41) exceeds a set threshold value, an alarm signal is immediately sent to the controller (3), and after the controller (3) receives the alarm signal, the controller starts the first electric push rod (47) to execute the next operation according to the judgment of the preset program logic;

Step three: after the first electric push rod (47) is started, the frame (45) moves to the rear side stably by extending the driving frame (45), the frame (45) moves along the limit position of the telescopic guide rail (46), and the terminal board (43) completely blocks the sealing of the rear side inside the equipment shell (41) after being pushed, so that heat generated in the working process of the BIM module (42) can be effectively dissipated, and the aim of auxiliary heat dissipation and ventilation is fulfilled;

Step four: the controller (3) judges according to preset program logic, and controls the track moving module (52), the multistage telescopic module (53), the first motor (58), the second electric push rod (512), the refrigerating fan (6) and the second mounting seat (519) to start and execute the next operation;

Step five: the track moving module (52) horizontally moves along the outside of the track (51) to move the folding assembly and the cooling assembly to the correct positions, the multi-stage telescopic module (53) stretches to drive the mounting transverse plate (54) to descend to the designated height position, so that the folding assembly and the cooling assembly are driven and inserted into the inner side of the frame (45) in the BIM module mechanism (4) at the designated positions;

Step six: the first motor (58) drives the second rotating rod (57) to rotate clockwise, so that the connecting seat (59) moves forwards, the cooling component is inserted into the equipment shell (41), and preparation is made for the subsequent cooling operation;

Step seven: the second electric push rod (512) is shortened, one end of the driving connecting rod (515) rotates upwards to enable the rotating frame (514) to be in contact with the top of the limiting bracket (516) so as to realize overturning, the third electric push rod (517) extends to drive the second mounting plate (518) to move towards the front side, and the spray head pipe (522) is close to the BIM module (42) so as to be ready for cooling operation;

Step eight: the low-temperature gas in the refrigerating fan (6) enters the spray head pipe (522) through the connecting pipeline, is sprayed out of the spray head pipe (522) to cool the inside of the track (51) in the equipment shell (41), and the second motor (520) drives the mounting seat (521) to drive the spray head pipe (522) to reciprocate up and down, so that the spraying range is increased, the wider cooling coverage range of the BIM module (42) is realized, and the temperature control effect of the equipment is ensured;

step nine: when the temperature sensor (44) detects that the internal temperature of the equipment shell (41) is recovered below a set threshold value, the spray head pipe (522) moves out of the equipment shell (41), the wiring board (43) seals the rear side of the inside of the equipment shell (41) again, and the working state of the BIM module (42) is ensured.