CN114046046A - Green building installation and construction method based on BMI technology - Google Patents

Abstract

The invention discloses a BMI technology-based green building installation construction method, and relates to the technical field of green buildings. The green building installation construction method based on the BMI technology comprises a base structure, the base structure comprises a base, a bottom ring is movably connected to the inner side wall of the base through a bearing, first sliding teeth are uniformly arranged on the inner side wall of the bottom ring at equal intervals, the surface of the first sliding teeth is arc-shaped and rough, gears are arranged inside the bottom ring, the number of the gears is two, the two gears are arranged in a bilateral symmetry mode, second sliding teeth are fixedly connected to the outer sides of the two gears at equal intervals and are fixedly connected with, the surface of the second sliding teeth is arc-shaped and rough, the second sliding teeth are meshed with the first sliding teeth, the lower surfaces of the gears are movably connected to the lower inner wall of the base through the bearing, the upper surfaces of the gears are movably connected with an upper plate through the bearing, and the green building installation construction method based on the BMI technology guarantees that the inner body building cannot be invaded by the vertical surface strong wind.

Description

Green building installation and construction method based on BMI technology

Technical Field

The invention relates to the technical field of green buildings, in particular to a BMI technology-based green building installation construction method.

Background

The green building is a high-quality building which saves resources, protects the environment, reduces pollution, provides healthy, applicable and efficient use space for people and furthest realizes harmonious symbiosis between people and nature in the life cycle.

Most green building framework on the market at present, on the comparatively big area of wind-force, often suffer from the invasion and attack of wind-force, and the building that stands wind-force invasion and attack throughout the year can make the outer wall of building bear great wind-force pressure, and wind-force wraps up in the sand that winds and makes the outer wall weathering of building faster for building life is not long by itself, uses danger to increase.

Disclosure of Invention

The invention aims to provide a BMI technology-based green building installation and construction method to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a green building installation construction method based on BMI technology comprises a base structure, wherein the base structure comprises a base, a bottom ring is movably connected to the inner side wall of the base through a bearing, sliding teeth I are uniformly arranged on the inner side wall of the bottom ring at equal intervals, the surface of the sliding teeth I is arc-shaped and rough, gears are arranged inside the bottom ring, the number of the gears is two, the two gears are arranged in bilateral symmetry, sliding teeth II are fixedly connected to the outer sides of the two gears at equal intervals, the surface of the sliding teeth II is arc-shaped and rough, the sliding teeth II are meshed with the sliding teeth I, the lower surface of the gear is movably connected to the lower inner wall of the base through the bearing, the upper surface of the gear is movably connected with an upper plate through the bearing, an upper groove is formed in the upper surface of the upper plate, and the number of the upper groove is two, two go up the groove and be around putting central symmetry and offering, the inside in last groove has inserted the pole setting, the lower extreme fixedly connected with stand of pole setting, the lower extreme fixedly connected with diaphragm of stand, the stand is in that the diaphragm is close the end of bottom ring on.

Preferably, the upper end of the vertical rod is fixedly connected with two wind blowing plates which are arc-shaped, the number of the wind blowing plates is two, the two wind blowing plates are symmetrically arranged, the center of the wind blowing plate on the front side is recessed backwards, inner body buildings are fixedly arranged on the left side and the right side of the upper surface of the upper plate, and the inner body buildings are located below the wind blowing plates.

Preferably, the quantity of diaphragm is two, two the diaphragm and last groove one-to-one, the lower inner wall of lower surface contact base of diaphragm, two the one side equidistance that the diaphragm deviates from is even fixedly connected with slides tooth three, the surface of sliding tooth three presents arc and roughness, two the one side contact that the diaphragm is close to, slide tooth three and the meshing of sliding tooth two.

Preferably, the outer side of the upper plate is provided with an outer cover structure, the outer cover structure comprises an outer cover, the lower end of the outer cover is fixedly connected with a bottom ring, the upper surface of the outer cover is flush with the upper surface of the air blowing plate, the outer cover is in a cylindrical shape with an upper opening and a lower opening, an air opening is formed in the front side of the outer cover, the air blowing plate in the front side is right opposite to the air opening, a first rear groove is formed in the rear side surface of the outer cover, and a second rear groove is formed in the rear inner wall of the first rear groove.

Preferably, the inside fixedly connected with mounting bracket of back groove two, the front surface upper end embedding fixedly connected with ball splint of mounting bracket, the lateral wall slope sets up about the ball splint, the double-layered ball has been placed to the inside of ball splint, the quantity of double-layered ball is two, two set up about the double-layered ball, the back surface middle part of mounting bracket is run through and is seted up slotted one, the front surface middle part of mounting bracket is run through and is seted up slotted two, slot two and groove one intercommunication, the ball splint are run through to the two upper ends in groove.

Preferably, the rear of the outer cover structure is provided with a wind guide structure, the wind guide structure comprises a clamping structure, a wind guide structure, a first hinge and a second hinge, the clamping structure and the wind guide structure are movably connected through the first hinge, the clamping structure is located above the wind guide structure, the number of the clamping structures is one, and the wind guide structures are movably connected through the second hinge.

Preferably, the clamping structure comprises a first clamping plate, a clamping groove is formed in the lower side of the rear surface of the first clamping plate, a first clamping column is fixedly connected to the middle of the left side wall and the right side wall of the clamping groove, the first clamping column is L-shaped, a second clamping plate is arranged behind the first clamping plate, a ball groove is formed in the front end of the second clamping plate, a clamping ball is fixedly connected to the lower inner wall of the ball groove, a clamping column is fixedly connected to the front end of the second clamping plate, the clamping column is inserted into the clamping groove and adapted to the clamping groove, first clamping column grooves are formed in the left side wall and the right side wall of the clamping column, the first clamping column is inserted into the first clamping column and adapted to the first clamping column, the second clamping plate penetrates through the first clamping groove and adapted to the first clamping groove, the clamping ball is located above the two clamping balls and contacts with the clamping balls, and the clamping ball is adapted to the second clamping groove.

Preferably, the air guide structure comprises a first air guide plate, an air guide groove is formed in the middle of the rear surface of the first air guide plate, clamping columns second are fixedly connected to the middle of the left inner wall and the right inner wall of the air guide groove in an equidistant mode, the clamping columns second are L-shaped, an air guide column is inserted into the air guide groove, clamping column grooves second are uniformly formed in the left side wall and the right side wall of the air guide column in an equidistant mode, the clamping columns second are inserted into the clamping column grooves second and are matched with the clamping column grooves, an air guide plate second is fixedly connected to the rear end of the air guide column, a spring column is fixedly connected to the rear end of the air guide plate second, air guide plates third are movably hinged to the left side and the right side of the spring column, the first air guide plate is inserted into the rear groove first and is matched with the rear groove first, the second air guide plate passes through the groove second and is matched with the groove first air guide plate, and the third air guide plate is located behind the mounting frame.

A BMI technology-based green building installation construction method is characterized by comprising the following steps: the method comprises the following steps:

s1: inserting the first clamping plate into the first rear groove from the lower part, and then inserting the second clamping plate into the first clamping plate for fixing through connection of the clamping columns and the clamping grooves;

s2: inserting the first air deflector into the first rear groove from the lower part, and then inserting the second air deflector into the first air deflector for fixing through the connection of the air guide column and the air guide groove;

s3: the clamping ball is pushed up to the upper part of the clamping ball, so that the whole air guide structure is clamped on the mounting frame.

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

(1) this a green building installation construction method based on BMI technique, when the strong wind blows from the just opposite face of wind gap to the face, wind-force can blow the board backward with blowing, simultaneously the arc design of blowing the board, can effectually turn into the power that the board moved is blown in the promotion wind with wind-force, the board backward motion is blown in the wind afterwards, under the connection of pole setting and stand, make diaphragm and three whole removals of slip tooth, thereby make three drive of slip tooth two and rotate, the rotation of slip tooth two drives slip tooth one and rotates, thereby make the bottom ring drive dustcoat turn to, make the position at wind gap place just remove from the position just right with the wind direction, guarantee that endosome building can not the invasion and attack of straight face strong wind.

(2) According to the BMI technology-based green building installation construction method, the reset spring is arranged, the wind blowing plates are arranged on the front side and the rear side, the linkage type of meshing of the sliding teeth III, the gear and the sliding teeth I is arranged between the two wind blowing plates, the wind blowing plates are arranged in a multi-way manner, when the outer cover rotates, the problem of the neutral position between the air opening and the wind blowing direction is greatly reduced, and the inner body building is protected by the aid of the outer cover structure in a comprehensive wind power mode by matching with the outer cover structure.

(3) According to the BMI technology-based green building installation construction method, the air guide structure is designed to be a split type structure with a clamping structure and an air guide structure, meanwhile, the hinge I and the hinge II are movably connected, and the clamping structure and the air guide structure are in split type connection, so that the separability of the device is greatly improved, and a convenient effect is achieved for the device to be stored.

(4) The BMI technology-based green building installation construction method comprises the steps of clamping a structure and an air guide structure, movably hinging the clamping structure and the air guide structure through a first hinge and a second hinge, and sequentially inserting a first clamping plate and a first air guide plate into a first rear groove for installation of the air guide structure.

(5) According to the BMI technology-based green building installation and construction method, due to the split type design of the clamping structure and the air guide structure, the air guide plate III is blown by wind for a long time under the problem of overlarge wind power, the installation and the disassembly of the clamping plate II and the clamping plate I as well as the air guide plate II and the air guide plate I are more convenient and faster through the split type design of the clamping structure and the air guide structure, meanwhile, the structure damaged by wind power can be replaced partially, and the building cost is saved.

(6) According to the BMI technology-based green building installation construction method, due to the design of the return spring in the upper groove, under the condition that wind power is weakened or no wind power exists, the wind port can automatically return to the front position with the help of the upper groove, and the automatic return capability of the device is improved.

(7) According to the BMI technology-based green building installation and construction method, when wind strikes the third air deflector from the front, the third air deflector can be blown to the position in contact with the outer cover, and due to the special setting of the length of the third air deflector, the position in contact with the outer cover is the tangent position of the edge of the outer cover, so that the wind blowing from the front can be broken and dispersed to the two sides of the outer cover by bending the third air deflector, the direct impact of the wind on the outer cover and an inner body building is avoided, and the invasion of the wind on the building is effectively reduced to the greatest extent.

Drawings

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

FIG. 2 is a schematic view of a base structure according to the present invention;

FIG. 3 is a schematic view of the back side of the housing structure of the present invention;

FIG. 4 is a schematic view of a mount of the present invention;

FIG. 5 is an enlarged view of the invention at A;

FIG. 6 is a schematic view of the rear side of the wind guide structure according to the present invention;

FIG. 7 is a schematic view of the connection of the wind guide structure of the present invention;

FIG. 8 is a rear view of the card mounting structure of the present invention;

FIG. 9 is an enlarged view of the invention at B;

fig. 10 is a schematic back view of the air guiding structure of the present invention;

FIG. 11 is an enlarged view of the present invention at point C.

In the figure: 1. a base structure; 101. a base; 102. a bottom ring; 103. a first sliding tooth; 104. a gear; 105. an upper plate; 106. an upper groove; 107. erecting a rod; 108. a wind blowing plate; 109. a column; 110. a transverse plate; 111. building an inner body; 112. a second sliding tooth; 113. a third sliding tooth; 2. an outer cover structure; 201. a housing; 202. a tuyere; 203. a first rear groove; 204. a second rear groove; 205. a mounting frame; 206. a ball clamp plate; 207. clamping a ball; 208. a first groove; 209. a second groove; 3. a wind guide structure; 301. a first hinge; 302. a second hinge; 4. a clamping structure; 401. clamping a first plate; 402. clamping grooves; 403. clamping the first column; 404. a second clamping plate; 405. a ball groove; 406. blocking the ball; 407. clamping the column; 408. a first clamping column groove; 5. a wind guide structure; 501. a first air deflector; 502. a wind guide groove; 503. a second clamping column; 504. a wind guide post; 505. a second clamping column groove; 506. a second air deflector; 507. a spring post; 508. and a third air deflector.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-11, the present invention provides a technical solution: a green building installation construction method based on BMI technology comprises a base structure 1, wherein the base structure 1 comprises a base 101, the inner side wall of the base 101 is movably connected with a bottom ring 102 through a bearing, sliding teeth I103 are uniformly arranged on the inner side wall of the bottom ring 102 at equal intervals, the surface of the sliding teeth I103 is arc-shaped and rough, gears 104 are arranged inside the bottom ring 102, the number of the gears 104 is two, the two gears 104 are arranged in bilateral symmetry, sliding teeth II 112 are fixedly connected to the outer sides of the two gears 104 at equal intervals, the surface of the sliding teeth II 112 is arc-shaped and rough, the sliding teeth II 112 are meshed with the sliding teeth I103, the lower surface of the gear 104 is movably connected to the lower inner wall of the base 101 through a bearing, the upper surface of the gear 104 is movably connected with an upper plate 105 through a bearing, the upper surface of the upper plate 105 is provided with an upper groove 106, the number of the upper groove 106 is two, the two upper grooves 106 are arranged in a front-back position and center symmetry manner, the vertical rod 107 is inserted into the upper groove 106, the return spring is fixedly connected inside the upper groove 106, the upright post 109 is fixedly connected to the lower end of the vertical rod 107, the transverse plate 110 is fixedly connected to the lower end of the upright post 109, the upright post 109 is located at the end, close to the bottom ring 102, of the transverse plate 110, the vertical rod 107 is located on the side, far away from the center of the upper plate 105, of the upper groove 106 in an initial state, and the sliding teeth I103, the sliding teeth II 112 and the sliding teeth III 113 can slide under the condition that a mechanism is locked.

The upper end of the vertical rod 107 is fixedly connected with two wind blowing plates 108, the wind blowing plates 108 are arc-shaped, the number of the wind blowing plates 108 is two, the two wind blowing plates 108 are symmetrically arranged, the center of the wind blowing plate 108 at the front side is recessed backwards, inner body buildings 111 are fixedly mounted on the left side and the right side of the upper surface of the upper plate 105, and the inner body buildings 111 are located below the wind blowing plates 108.

The number of the transverse plates 110 is two, the two transverse plates 110 correspond to the upper grooves 106 one by one, the lower surfaces of the transverse plates 110 are in contact with the lower inner wall of the base 101, the surfaces of the two transverse plates 110, which are far away from each other, are fixedly connected with third sliding teeth 113 in an equidistant mode, the surfaces of the third sliding teeth 113 are arc-shaped and rough, the surfaces of the two transverse plates 110, which are close to each other, are in contact, and the third sliding teeth 113 are meshed with the second sliding teeth 112.

The outside of upper plate 105 is provided with dustcoat structure 2, dustcoat structure 2 includes dustcoat 201, dustcoat 201's lower extreme fixed connection end ring 102, the upper surface of dustcoat 201 flushes with the upper surface of blowing board 108, dustcoat 201 presents upper and lower open-ended tube-shape, the front side of dustcoat 201 is opened and is equipped with wind gap 202, it is just right with wind gap 202 that the wind that is in the front side blows board 108, rear groove one 203 has been seted up to the trailing flank of dustcoat 201, rear groove two 204 has been seted up on the back inner wall of rear groove one 203.

Inside fixedly connected with mounting bracket 205 of two 204 back grooves, fixedly connected with ball splint 206 is embedded to the front surface upper end of mounting bracket 205, lateral wall slope setting about ball splint 206, ball 207 has been placed to the inside of ball splint 206, the quantity of pressing from both sides ball 207 is two, two press from both sides and set up about ball 207, the rear surface middle part of mounting bracket 205 runs through and sets up slotted 208, the front surface middle part of mounting bracket 205 runs through and sets up slotted two 209, slot two 209 and slot one 208 intercommunication, ball splint 206 is run through to slot two 209 upper ends, through the design of pressing from both sides ball 207 and card ball 406, can be so that the installation of wind guide structure 3 is more convenient, and when needs dismantle wind guide structure 3 simultaneously, only need continue to push up wind guide structure 3 and can dismantle, the simple and convenient and firm of operation ten minutes.

The rear of the outer cover structure 2 is provided with a wind guide structure 3, the wind guide structure 3 comprises a clamping structure 4, a wind guide structure 5, a first hinge 301 and a second hinge 302, the clamping structure 4 and the wind guide structure 5 are movably connected through the first hinge 301, the clamping structure 4 is located above the wind guide structure 5, the quantity of the clamping structures 4 is one, and the wind guide structures 5 are movably connected through the second hinge 302.

The clamping structure 4 comprises a first clamping plate 401, a clamping groove 402 is formed in the lower side of the rear surface of the first clamping plate 401, a first clamping column 403 is fixedly connected to the middle of each of the left side wall and the right side wall of the clamping groove 402, the first clamping column 403 is L-shaped, a second clamping plate 404 is arranged behind the first clamping plate 401, a ball groove 405 is formed in the front end of the second clamping plate 404, a clamping ball 406 is fixedly connected to the lower inner wall of the ball groove 405, a clamping column 407 is fixedly connected to the front end of the second clamping plate 404, the clamping column 407 is inserted into the clamping groove 402 and adapted to the clamping groove, a first clamping column groove 408 is formed in each of the left side wall and the right side wall of the clamping column 407, the first clamping column 403 is inserted into the first clamping column 403 and adapted to the first clamping plate 401, the first clamping plate 401 is inserted into the first rear groove 203 and adapted to the clamping plate 404, the second clamping plate 404 penetrates through the first groove 209 and is adapted to the first groove 208, the clamping ball 406 is located above the two clamping balls 207 and contacts the clamping balls 406 and is adapted to the second groove 209.

The air guide structure 5 comprises a first air guide plate 501, an air guide groove 502 is formed in the middle of the rear surface of the first air guide plate 501, a second clamping column 503 is fixedly connected to the middle of the left inner wall and the right inner wall of the air guide groove 502 at equal intervals, the second clamping column 503 is L-shaped, an air guide column 504 is inserted and connected into the air guide groove 502, a second clamping column groove 505 is uniformly formed in the left side wall and the right side wall of the air guide column 504 at equal intervals, the second clamping column 503 is inserted into the second clamping column groove 505 and matched with the second clamping column groove, an air guide plate second 506 is fixedly connected to the rear end of the air guide column 504, a spring column 507 is fixedly connected to the rear end of the air guide plate second 506, a third air guide plate 508 is movably hinged to the left side and the right side of the spring column 507, when the third air guiding plate 508 contacts the outer cover 201, the third air guiding plate 508 is tangent to the outer side wall of the outer cover 201, the first air guiding plate 501 is inserted into the first rear groove 203 and is matched with the first rear groove 203, the second air guiding plate 506 is inserted into the first groove 208 through the second groove 209 and is matched with the first groove 208, and the third air guiding plate 508 is located behind the mounting frame 205.

A BMI technology-based green building installation construction method is characterized by comprising the following steps: the method comprises the following steps:

s1: inserting the first clamping plate into the first rear groove from the lower part, and then inserting the second clamping plate into the first clamping plate for fixing through connection of the clamping columns and the clamping grooves;

s2: inserting the first air deflector into the first rear groove from the lower part, and then inserting the second air deflector into the first air deflector for fixing through the connection of the air guide column and the air guide groove;

s3: the clamping ball is pushed up to the upper part of the clamping ball, so that the whole air guide structure is clamped on the mounting frame.

The working principle is as follows:

the first step is as follows: when strong wind blows from the right opposite side of the wind gap 202 to the front side, the wind can blow the wind blowing plate 108 backwards, meanwhile, due to the arc-shaped design of the wind blowing plate 108, the wind can be effectively converted into power for pushing the wind blowing plate 108 to move, then the wind blowing plate 108 moves backwards, under the connection of the vertical rod 107 and the upright column 109, the transverse plate 110 and the sliding tooth third 113 move integrally and move inwards, so that the sliding tooth third 113 drives the sliding tooth second 112 to rotate, the sliding tooth second 112 rotates to drive the sliding tooth first 103 to rotate, the bottom ring 102 drives the outer cover 201 to turn, the position of the wind gap 202 is moved away from the position opposite to the wind direction, and the inner body building 111 is guaranteed not to be invaded by the direct strong wind.

The second step is that: through the reset spring and the linkage type that both sides all set up wind and blow board 108 around and, through the meshing of sliding tooth three 113, gear 104 and sliding tooth 103 between two wind and blow boards 108 in addition, the many ways of setting up wind and blow board 108 and when dustcoat 201 rotates, the neutral position problem between wind gap 202 and the wind-force blowing direction is great dwindles, cooperates dustcoat structure 2 for endosome building 111 carries out omnidirectional wind-force protection under dustcoat structure 2's protection.

The third step: through the split type structure with air guide structure 3 design for clamping structure 4 and air guide structure 5, carry out swing joint through hinge 301 and hinge 302 simultaneously, and clamp structure 4 and air guide structure 5 and be split type connection, great improvement like this the separability of device, to accomodating of device play convenient effect.

The fourth step: through the split type design that clamps structure 4 and air guide structure 5, and clamp structure 4 and air guide structure 5 and carry out the activity hinge through hinge 301 and hinge 302, make for the installation of air guide structure 3, can at first insert back groove 203 with clamping plate 401 and air guide plate 501 in proper order and install, secondly connecting clamping plate two 404 and air guide plate two 506, make the installation of air guide structure 3 more nimble like this, and the structure that can split makes the installation of air guide structure 3 need not leave too much space, practice thrift the space energy.

The fifth step: through the split type design of the clamping structure 4 and the air guide structure 5, the air guide plate III 508 can be blown by wind power for a long time under the problem of overlarge wind power, and through the split type design of the clamping structure 4 and the air guide structure 5, the installation and the disassembly of the clamping plate II 404, the clamping plate I401, the air guide plate II 506 and the air guide plate I501 are more convenient and quicker, meanwhile, the structure damaged by the wind power can be replaced partially, and the building cost is saved.

And a sixth step: the design of the return spring in the upper groove 106 improves the automatic return capability of the device by allowing the tuyere 202 to automatically return to the front position with the help of the upper groove 106 in the case of weak wind or no wind.

The seventh step: when wind power strikes the third air deflector 508 from the front, the third air deflector 508 can be blown to the position contacting with the outer cover 201, and due to the special setting of the length of the third air deflector 508, the position where the third air deflector 508 contacts with the outer cover 201 is the tangential position of the edge of the outer cover 201, so that the wind power blowing from the positive direction can be broken and dispersed to the two sides of the outer cover 201 by the bending of the third air deflector 508, the direct impact of the wind power on the outer cover 201 and the inner-body building 111 is avoided, and the invasion of the building by the wind power is effectively reduced to the maximum extent.

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

Claims (9)

1. A green building installation construction method based on BMI technology comprises a base structure (1), wherein the base structure (1) comprises a base (101), and is characterized in that: there are end ring (102) on the inside wall of base (101) through bearing swing joint, sliding tooth one (103) have been seted up to the equidistance on the inside wall of end ring (102) is even, the surface of sliding tooth one (103) presents arc and coarse, the inside of end ring (102) is provided with gear (104), the quantity of gear (104) is two, two gear (104) bilateral symmetry sets up, two the even fixedly connected with sliding tooth two (112) of outside equidistance of gear (104), the surface of sliding tooth two (112) presents arc and coarse, sliding tooth two (112) and sliding tooth one (103) meshing, the lower surface of gear (104) passes through bearing swing joint on the lower inner wall of base (101), the upper surface of gear (104) has upper plate (105) through bearing swing joint, upper groove (106) have been seted up to the upper surface of upper plate (105), the number of the upper grooves (106) is two, the two upper grooves (106) are arranged in a front-back central symmetry manner, the vertical rod (107) is inserted into the upper groove (106), the lower end of the vertical rod (107) is fixedly connected with an upright column (109), the lower end of the upright column (109) is fixedly connected with a transverse plate (110), and the upright column (109) is positioned at the end, close to the bottom ring (102), of the transverse plate (110).

2. The BMI technology-based green building installation and construction method according to claim 1, wherein: the upper end of the vertical rod (107) is fixedly connected with a wind blowing plate (108), the wind blowing plate (108) is arc-shaped, the number of the wind blowing plates (108) is two, the two wind blowing plates (108) are symmetrically arranged, the center of the wind blowing plate (108) on the front side is backward sunken, inner-body buildings (111) are fixedly installed on the left side and the right side of the upper surface of the upper plate (105), and the inner-body buildings (111) are located below the wind blowing plates (108).

3. The BMI technology-based green building installation and construction method according to claim 1, wherein: the quantity of diaphragm (110) is two, two diaphragm (110) and last groove (106) one-to-one, the lower surface contact inner wall of base (101) of diaphragm (110), two the even fixedly connected with of the one side equidistance that diaphragm (110) deviates from mutually slides tooth three (113), the surface of sliding tooth three (113) presents arc and roughness, two that diaphragm (110) is close mutually contacts, slide tooth three (113) and the meshing of sliding tooth two (112).

4. The BMI technology-based green building installation and construction method according to claim 2, wherein: the outer side of the upper plate (105) is provided with an outer cover structure (2), the outer cover structure (2) comprises an outer cover (201), the lower end of the outer cover (201) is fixedly connected with a bottom ring (102), the upper surface of the outer cover (201) is flush with the upper surface of a wind blowing plate (108), the outer cover (201) is in a cylindrical shape with an upper opening and a lower opening, a wind port (202) is formed in the front side of the outer cover (201), the wind blowing plate (108) in the front side is right opposite to the wind port (202), a first rear groove (203) is formed in the rear side face of the outer cover (201), and a second rear groove (204) is formed in the inner rear wall of the first rear groove (203).

5. The BMI technology-based green building installation and construction method according to claim 4, wherein: inside fixedly connected with mounting bracket (205) of back groove two (204), the front surface upper end embedding fixedly connected with ball splint (206) of mounting bracket (205), the slope of lateral wall sets up about ball splint (206), the inside of ball splint (206) has been placed and has been pressed from both sides ball (207), the quantity that presss from both sides ball (207) is two set up about pressing from both sides ball (207), the rear surface middle part of mounting bracket (205) runs through and sets up slotted (208), the front surface middle part of mounting bracket (205) runs through and sets up slotted two (209), groove two (209) and groove one (208) intercommunication, ball splint (206) are run through to groove two (209) upper ends.

6. The BMI technology-based green building installation and construction method according to claim 5, wherein: the rear of dustcoat structure (2) is provided with wind-guiding structure (3), wind-guiding structure (3) carry out swing joint through hinge (301) including clamping structure (4), wind-guiding structure (5), hinge (301) and hinge two (302), clamp and carry out swing joint between structure (4) and the wind-guiding structure (5), it is one to clamp the top that structure (4) is in wind-guiding structure (5) and the quantity that clamps structure (4), carry out swing joint through hinge two (302) between wind-guiding structure (5).

7. The BMI technology-based green building installation and construction method according to claim 6, wherein: the clamping structure (4) comprises a first clamping plate (401), a clamping groove (402) is formed in the lower side of the rear surface of the first clamping plate (401), a first clamping column (403) is fixedly connected to the middle portions of the left side wall and the right side wall of the clamping groove (402), the first clamping column (403) is L-shaped, a second clamping plate (404) is arranged behind the first clamping plate (401), a ball groove (405) is formed in the front end of the second clamping plate (404), a clamping ball (406) is fixedly connected to the lower inner wall of the ball groove (405), a clamping column (407) is fixedly connected to the front end of the second clamping plate (404), the clamping column (407) is inserted into and adapted to the clamping groove (402), first clamping column grooves (408) are formed in the left side wall and the right side wall of the clamping column (407), the first clamping column (403) is inserted into and adapted to the first clamping column (403), the first clamping plate (401) is inserted into and adapted to the first rear groove (203), the second clamping plate (404) penetrates through the second slot (209) to be inserted into the first slot (208) and is matched with the first slot (208), the clamping balls (406) are positioned above the two clamping balls (207) and are in contact with the clamping balls (207), and the clamping balls (406) are matched with the second slot (209).

8. The BMI technology-based green building installation and construction method according to claim 6, wherein: the air guide structure (5) comprises a first air guide plate (501), an air guide groove (502) is formed in the middle of the rear surface of the first air guide plate (501), clamping columns II (503) are fixedly connected to the middle of the left inner wall and the right inner wall of the air guide groove (502) in an equidistant mode, the clamping columns II (503) are L-shaped, an air guide column (504) is inserted and connected into the air guide groove (502), clamping column grooves II (505) are formed in the left side wall and the right side wall of the air guide column (504) in an equidistant mode, the clamping columns II (503) are inserted into the clamping column grooves II (505) and are matched with each other, an air guide plate II (506) is fixedly connected to the rear end of the air guide column (504), spring columns (507) are fixedly connected to the rear end of the air guide plate II (506), air guide plate III (508) are movably hinged to the left side and the right side of the spring columns (507), the first air guide plate (501) is inserted into the rear groove I (203) and is matched with the rear groove I (203), the second air deflector (506) penetrates through the second groove (209) to be inserted into the first groove (208) and is matched with the first groove (208), and the third air deflector (508) is located behind the mounting frame (205).

9. A BMI technology-based green building installation construction method is characterized by comprising the following steps: the method comprises the following steps:

s1: inserting the first clamping plate into the first rear groove from the lower part, and then inserting the second clamping plate into the first clamping plate for fixing through connection of the clamping columns and the clamping grooves;

s2: inserting the first air deflector into the first rear groove from the lower part, and then inserting the second air deflector into the first air deflector for fixing through the connection of the air guide column and the air guide groove;

s3: the clamping ball is pushed up to the upper part of the clamping ball, so that the whole air guide structure is clamped on the mounting frame.

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