CN117758906A - Energy-saving building curtain wall structure and construction process - Google Patents

Abstract

The invention relates to the technical field of building curtain walls, in particular to an energy-saving building curtain wall structure and a construction process, wherein the energy-saving building curtain wall structure comprises a frame, a first limiting component and a second overturning component, wherein the first limiting component comprises two side plates which are parallel to each other, and a top plate and a bottom plate which are used for connecting the two side plates, and the bottom plate and the side plates are detachably and fixedly connected; the overturning assembly comprises a supporting seat, a rotating seat and a sliding assembly; the rotating seat is arranged on the outer side of the side plate and is in rotating connection with one end of the supporting seat; the supporting seat is in sliding connection with the inner side wall of the frame; the sliding component is arranged on the outer side of the side plate and used for driving the rotating seat to linearly displace on the side plate. The invention enables staff to install and replace the curtain wall in the building, thereby improving the production safety.

Description

Energy-saving building curtain wall structure and construction process

Technical Field

The invention relates to the technical field of building curtain walls, in particular to an energy-saving building curtain wall structure and a construction process.

Background

The exterior-protected structure outside the existing building in China is poor in heat preservation and air tightness, particularly the outer wall and the outer window, the heat loss degree is high, and most of building energy consumption is lost through the outer wall and the outer window. The curtain wall is an outer wall enclosure of a building, is hung like a curtain, is also called as a curtain wall, and is a light wall with a decorative effect commonly used in modern large-scale and high-rise buildings.

Chinese patent CN115030380B discloses an energy-saving and heat-preserving building curtain wall structure and a construction method thereof, wherein the energy-saving and heat-preserving building curtain wall structure comprises a connecting backboard and a shell, an outer heat-preserving board, a partition board, an inner heat-preserving board and a convex board are arranged in the shell, the shell is movably abutted to one side of the connecting backboard, two sliding holes are formed in one side of the connecting backboard, sliding frames are slidably mounted in the sliding holes, clamping plates are fixedly mounted on one sides, far away from each other, of the two sliding frames, clamping grooves are formed in the inner wall of the top and the inner wall of the bottom of the shell, the two clamping plates are movably clamped in the corresponding clamping grooves respectively, a sliding plate is slidably mounted in the sliding frames, a pull rod is fixedly connected to the left side of the sliding plate, and the left end of the pull rod is fixedly connected with the pull plate. The invention has reasonable design, realizes the installation work of the inner and outer heat insulation boards through the cooperation of the connecting backboard and the shell, improves the construction efficiency and ensures the heat insulation performance.

When the device is installed or replaced, the staff is located on the outer side of a building, and then when the curtain wall structure at a high position is processed, the staff needs to reach the corresponding position through the high-altitude operation hanging basket, when the high-altitude operation hanging basket is used, the hanging basket and the steel wire rope need to be checked at all times, otherwise, when the hanging basket is problematic, production safety accidents are extremely easy to cause, and meanwhile, the device can be influenced by factors such as external weather, temperature and wind power when in operation.

Disclosure of Invention

To above-mentioned problem, provide an energy-saving building curtain wall construction and construction process, through setting up the bottom plate rotation to the frame inside of the first spacing subassembly of upset subassembly to the bottom plate can be taken off from the curb plate, so that the staff can install and change in the building, and then improved the security of work, ensured staff's life safety.

In order to solve the problems in the prior art, the invention provides an energy-saving building curtain wall structure, which comprises a frame, a limiting component I and a turnover component, wherein the limiting component I comprises two side plates which are parallel to each other, and a top plate and a bottom plate which are used for connecting the two side plates, and the bottom plate and the side plates are detachably and fixedly connected; the overturning assembly comprises a supporting seat, a rotating seat and a sliding assembly; the rotating seat is arranged on the outer side of the side plate and is in rotating connection with one end of the supporting seat; the supporting seat is in sliding connection with the inner side wall of the frame; the sliding component is arranged on the outer side of the side plate and used for driving the rotating seat to linearly displace on the side plate.

Preferably, the sliding component comprises a sliding seat and a first elastic component; the sliding seat and the first elastic component are arranged on the outer side of the side plate, and the sliding seat is fixedly connected with the rotating seat; the sliding seat is in sliding connection with the side plate, and the sliding direction is parallel to the length direction of the side plate; the first elastic component is used for driving the sliding seat to be away from the top plate.

Preferably, a second limiting component is arranged between the rotating seat and the supporting seat, and the second limiting component comprises a limiting block, a guide shaft and a second elastic component; the top end of the limiting block is connected with the guide shaft; a limiting groove clamped with the limiting block is formed in the supporting seat; the guide shaft is inserted into the rotating seat and is in clearance fit with the rotating seat, and the axis of the guide shaft passes through the axis of the rotating seat; the second elastic component is connected with the rotating seat and the limiting block respectively and is used for driving the limiting block to be far away from the rotating seat.

Preferably, a positioning assembly is arranged in the supporting seat, and the positioning assembly comprises a first sliding block and a positioning shaft; the first sliding block is arranged in the supporting seat in a sliding manner and is rotationally connected with the positioning shaft; the positioning shaft is used for being inserted into the sliding seat.

Preferably, one end of the positioning shaft inserted into the sliding seat is provided with a plurality of circular arc buckles distributed circumferentially; the sliding seat is provided with a positioning groove which is mutually clamped with the arc buckle.

Preferably, a pull rod connected with the side plate is arranged at the top end of the frame.

Preferably, tenon strips are respectively arranged at two ends of the bottom plate; the side plates are provided with mortise grooves for accommodating tenon strips; and the side plates are also provided with clamping pins which penetrate through the mortise and are inserted into the tenon strips.

Preferably, the side plate is further provided with a third elastic component for driving the bayonet lock to be close to the inside of the mortise.

Preferably, the top plate and the bottom plate are respectively provided with a second sliding block inserted into the frame; the second sliding block is connected with the frame in a sliding way.

The application also relates to a construction process of the building curtain wall, which comprises the following steps:

s1, rotating a first limiting assembly to a horizontal state, then removing a bottom plate from a side plate and installing glass between the two side plates;

s2, fixing the bottom plate on the side plate and rotating the first limiting assembly to a vertical state;

s3, pulling the first limiting component to be close to the frame until the top plate of the first limiting component is mutually abutted with the frame;

s4, driving the limiting assembly to vertically move downwards, so that the top plate and the bottom plate are simultaneously abutted with the frame.

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

1. according to the invention, the bottom plate of the first limiting component is rotated into the frame through the overturning component, and the bottom plate can be taken down from the side plate, so that workers can install and replace the bottom plate in a building, the working safety is improved, and the life safety of the workers is ensured.

2. The positioning shaft is arranged and inserted into the sliding seat, so that the displacement of the sliding seat can be limited, the first limiting component is prevented from automatically generating vertical upward displacement, the first limiting component can be fixed on the frame, the positioning shaft is provided with the arc buckle, the displacement between the positioning shaft and the sliding seat can be limited, and the positioning shaft can be ensured to stably limit the sliding seat.

3. According to the invention, the bayonet lock is inserted into the mortise and tenon strip, so that the bottom plate can be fixed on the side plate, and the third elastic assembly is further arranged on the side plate, so that the bayonet lock can be always in a state of being inserted into the mortise and tenon strip, and the situation that the bayonet lock falls off from the side plate when the limiting assembly rotates is avoided.

Drawings

Fig. 1 is a perspective view of an energy-saving building curtain wall structure.

Fig. 2 is a schematic perspective view of an energy-saving building curtain wall structure after the limiting assembly is turned over.

Fig. 3 is a schematic perspective view of an energy-efficient building curtain wall construction with the frame hidden.

Fig. 4 is a partial perspective view of a roll-over assembly in an energy efficient building curtain wall construction.

Fig. 5 is a schematic view of a partial structure of a roll-over assembly in an energy efficient building curtain wall structure.

Fig. 6 is a structural cross-sectional view of a second spacing assembly in an energy efficient building curtain wall structure.

Fig. 7 is a schematic perspective view of a positioning assembly in an energy efficient building curtain wall structure.

Fig. 8 is a perspective view of a first spacing assembly in an energy efficient building curtain wall structure.

Fig. 9 is a sectional view of the structure of the energy-saving building curtain wall structure when the bottom plate and the side plates are fixed.

Fig. 10 is a schematic perspective view of a side panel of an energy efficient building curtain wall construction.

The reference numerals in the figures are: 1. a frame; 2. a first limiting component; 21. a side plate; 211. mortise; 22. a top plate; 221. a second slider; 23. a bottom plate; 231. tenon strips; 24. a bayonet lock; 25. a third elastic component; 3. a flip assembly; 31. a support base; 32. a rotating seat; 33. a sliding assembly; 331. a slide; 332. a first elastic component; 34. a second limiting component; 341. a limiting block; 342. a guide shaft; 343. a second elastic component; 35. a positioning assembly; 351. a first slider; 352. positioning a shaft; 3521. arc buckle; 36. and (5) a pull rod.

Detailed Description

The invention will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the invention and the specific objects and functions achieved.

Referring to fig. 1 to 5, the present invention provides: the energy-saving building curtain wall structure comprises a frame 1, a limiting component I2 and a turnover component 3, wherein the limiting component I2 comprises two side plates 21 which are parallel to each other, and a top plate 22 and a bottom plate 23 which are used for connecting the two side plates 21, and the bottom plate 23 and the side plates 21 are detachably and fixedly connected; the overturning assembly 3 comprises a supporting seat 31, a rotating seat 32 and a sliding assembly 33; the rotating seat 32 is arranged on the outer side of the side plate 21, and the rotating seat 32 is rotationally connected with one end of the supporting seat 31; the supporting seat 31 is in sliding connection with the inner side wall of the frame 1; the sliding assembly 33 is disposed outside the side plate 21 and is used for driving the rotating seat 32 to linearly displace on the side plate 21.

The side plate 21 has two parallel clamping grooves, the inner side of the side plate 21 is provided with two parallel clamping grooves, so that two pieces of glass can be respectively placed in the corresponding clamping grooves, and a certain space can be reserved between the two pieces of glass after the two pieces of glass are installed by limiting the distance between the two clamping grooves, and meanwhile, the installation place can be sealed when the glass is installed, so that the space between the two pieces of glass is in a sealed state, then inert gas can be injected into the inner space, so that heat exchange inside and outside a building can be reduced, the functions of heat preservation and heat insulation are achieved, the two ends of the side plate 21 are respectively connected with the top plate 22 and the bottom plate 23, and due to the two side plates 21, the two ends of the top plate 22 and the bottom plate 23 are respectively connected with one side plate 21, wherein the top plate 22 can be fixedly connected with the side plates 21 in a non-detachable manner or in a detachable manner, and the bottom plate 23 and the side plates 21 are fixedly connected in a detachable manner, so that when glass needs to be installed, the bottom plate 23 can be removed, then the glass is inserted between the two side plates 21 from the opening until the glass and the top plate 22 are abutted with each other, then the bottom plate 23 is fixed on the side plates 21, so that the glass can be fixed, then the outer sides of the two side plates 21 are respectively provided with a rotating seat 32, the rotating seats 32 are rotatably connected with one end of the supporting seat 31, the other end of the supporting seat 31 is inserted into the frame 1 and is in sliding connection with the frame 1, so that the limiting assembly 1 can be driven to be close to or far away from the frame 1, and the rotating seats 32 are connected with the side plates 21 through the sliding assembly 33, when the first limiting component 2 rotates around one end of the supporting seat 31, the position of the rotating seat 32 on the side plate 21 can be adjusted, so that when glass needs to be replaced, the supporting seat 31 can be driven to slide relative to the side plate 21 through the sliding component 33, the first integral limiting component 2 can be driven to slide vertically upwards, the whole limiting component 2 can be driven to rotate around the axis of the rotating seat 32 until the first integral limiting component 2 rotates to a horizontal state, the bottom plate 23 in the first limiting component 2 is rotated into the frame 1, the bottom plate 23 can be removed and replaced with glass, after the glass is replaced, the first limiting component 2 can be driven to rotate reversely, the top plate 22 is mutually abutted with the frame 1, then the first limiting component 2 is driven to slide downwards, the top plate 22 and the bottom plate 23 are abutted with the frame 1, the first limiting component 2 can be prevented from rotating, the inner side wall of the supporting seat 31 is driven to slide and be connected with the inner side wall of the frame 1, the first limiting component 2 is driven to move upwards, the first limiting component 2 is driven to be separated from the frame 1, the first limiting component 2 can be driven to rotate smoothly, the inside the frame 23 can be replaced with the frame 1, the inside of the frame 23 can be replaced with the glass is guaranteed, and the inside of a life personnel can be replaced conveniently, and the inside of the frame 23 can be replaced with the frame is guaranteed, and the life of the life is guaranteed; meanwhile, not only glass can be installed between the two side plates 21, but also an insulating layer can be installed between the two side plates 21 when no illumination is needed but a better insulating effect is needed.

Referring to fig. 5, it is shown that: the sliding component 33 comprises a sliding seat 331 and a first elastic component 332; the sliding seat 331 and the first elastic component 332 are both disposed outside the side plate 21, wherein the sliding seat 331 is fixedly connected with the rotating seat 32; the sliding seat 331 is slidably connected with the side plate 21, and the sliding direction is parallel to the length direction of the side plate 21; the first elastic component 332 is used to urge the slide 331 away from the top plate 22.

The sliding seat 331 is fixedly connected with the rotating seat 32, and the sliding seat 331 can be far away from the top plate 22 under the action of the first elastic component 332, so that the sliding seat 331 can drive the rotating seat 32 to be far away from the top plate 22 synchronously, the first limiting component 2 can integrally move upwards, the bottom plate 23 in the first limiting component 2 can be far away from the frame 1, and the sliding seat 31 is in sliding connection with the frame 1, so that the first limiting component 2 can be driven to integrally separate from the frame 1, the first limiting component 2 can be further guaranteed to rotate the bottom plate 23 into the frame 1, the glass can be conveniently replaced and maintained by workers, and the first elastic component 332 can adopt elastic elements such as a compression spring or a gas spring, so that the first elastic component 332 can be guaranteed to smoothly push the sliding seat 331 to move on the side plate 21.

Referring to fig. 6, it is shown: a second limiting component 34 is arranged between the rotating seat 32 and the supporting seat 31, and the second limiting component 34 comprises a limiting block 341, a guide shaft 342 and a second elastic component 343; the top end of the limiting block 341 is connected with a guide shaft 342; a limiting groove clamped with the limiting block 341 is formed in the supporting seat 31; the guide shaft 342 is inserted into the rotary seat 32 and is in clearance fit with the rotary seat 32, and the axis of the guide shaft 342 passes through the axis of the rotary seat 32; the second elastic component 343 is connected to the rotating seat 32 and the limiting block 341, respectively, and the second elastic component 343 is used for driving the limiting block 341 away from the rotating seat 32.

The limiting groove is provided with two mutually perpendicular supporting seats 31, an arc groove is arranged between the two limiting grooves, when the rotating seat 32 rotates, the limiting block 341 can move from one limiting groove to the other limiting groove, meanwhile, the limiting block 341 is connected with the rotating seat 32 through a guide shaft 342, the guide shaft 342 is inserted into the rotating seat 32 and is in clearance fit with the rotating seat 32, the limiting block 341 can be close to or far away from the rotating seat 32 along the axis of the guide shaft 342, a second elastic component 343 is arranged between the limiting block 341 and the rotating seat 32, the second elastic component 343 can adopt an elastic element such as a compression spring or an air spring, so that the abutting block can be driven to be far away from the rotating seat 32, the limiting block 341 can be stably inserted into the limiting groove, an inclined plane can be arranged between the arc groove and the limiting groove, and the rotating seat 32 rotate, the limiting block 341 can move onto the arc groove along the inclined plane, the second elastic component 343 is extruded until the limiting block 341 moves to the other limiting block 32 along the axis of the guide shaft 342, and the limiting block is rapidly inserted into the limiting groove 32.

Referring to fig. 5 and 7, it is shown that: a positioning assembly 35 is arranged in the supporting seat 31, and the positioning assembly 35 comprises a first sliding block 351 and a positioning shaft 352; the first sliding block 351 is slidably arranged in the supporting seat 31, and the first sliding block 351 is rotatably connected with the positioning shaft 352; the positioning shaft 352 is inserted into the slide 331.

The first sliding block 351 is located inside the supporting seat 31 and is slidably connected with the supporting seat 31, a first sliding groove and a second sliding groove which are slidably connected with the first sliding block 351 are arranged inside the supporting seat 31, the first sliding groove and the second sliding groove are perpendicular to each other and are mutually communicated, the first sliding groove is used for driving the first sliding block 351 to move the positioning shaft 352 to the outer side of the supporting seat 31, the second sliding groove is used for driving the first sliding block 351 to insert the positioning shaft 352 into the sliding seat 331, so that the sliding seat 331 is limited, the first elastic component 332 is prevented from driving the sliding seat 331 to move, when the bottom plate 23 is required to be rotated into the frame 1, the first sliding block 351 is driven to be away from the sliding seat 331 through the first sliding block 351, and then the first sliding block 351 and the positioning shaft 352 are driven to move into the supporting seat 31 through the first sliding groove, so that interference between the side plate 21 and the first sliding block 351 can be avoided when the limiting component 2 is rotated.

Referring to fig. 7, it is shown that: one end of the positioning shaft 352 inserted into the sliding seat 331 is provided with a plurality of circular arc buckles 3521 distributed circumferentially; the sliding seat 331 is provided with a positioning slot which is clamped with the arc buckle 3521.

The positioning shaft 352 is rotationally connected with the first sliding block 351, so that the positioning shaft 352 can be rotated when the positioning shaft 352 is inserted into the sliding seat 331, the arc buckle 3521 can be mutually clamped with the positioning groove, axial displacement of the positioning shaft 352 relative to the sliding seat 331 can be avoided, patterns can be arranged at one end, far away from the sliding seat 331, of the positioning shaft 352, friction force on the surface of the positioning shaft 352 is increased, and the positioning shaft 352 is convenient for workers to rotate.

Referring to fig. 2, it is shown: the top end of the inside of the frame 1 is provided with a pull rod 36 connected with the side plate 21.

The pull rod 36 may be composed of a first telescopic rod and a second telescopic rod, where the first telescopic rod is inserted into the second telescopic rod and is in clearance fit with the second telescopic rod, the first telescopic rod is hinged to the side plate 21, and the second telescopic rod is hinged to the frame 1, so that when the first limiting component 2 integrally rotates to a horizontal state, the first telescopic rod can slide out from the second telescopic rod, and meanwhile, an extension spring can be further arranged in the second telescopic rod, so that a pull-back acting force is applied to the first telescopic rod, and the pull rod 36 can assist in supporting the first limiting component 2, so that a worker can smoothly replace and maintain glass.

Referring to fig. 9 and 10, it is shown that: the two ends of the bottom plate 23 are respectively provided with a tenon strip 231; the side plate 21 is provided with a mortise 211 for accommodating the tenon bar 231; the side plate 21 is further provided with a bayonet 24, and the bayonet 24 penetrates into the mortise 211 and is inserted into the tenon 231.

The two ends of the bottom plate 23 are respectively provided with a tenon bar 231 for being inserted into the side plates 21, so that after the glass is installed between the two side plates 21, the bottom plate 23 can be attached to the side plates 21, the tenon bar 231 is inserted into the mortise 211, then the bayonet lock 24 is inserted into the mortise 211 from the outer side of the side plates 21, and the bayonet lock 24 is also inserted into the tenon bar 231, so that the tenon bar 231 can be limited into the mortise 211, and the bottom plate 23 can be stably installed on the side plates 21, so that the glass is fixed into the limiting assembly 2.

Referring to fig. 9, it is shown that: the side plate 21 is further provided with a third elastic component 25 for driving the bayonet 24 to approach the inside of the mortise 211.

The bayonet lock 24 is gone up and is close to the inside one end of mortise 211 and is equipped with the lug, be equipped with third elastic component 25 between lug and the curb plate 21, third elastic component 25 can adopt compression spring or air spring to this can ensure through third elastic component 25 that bayonet lock 24 is in the mortise 211 all the time inside, and then restrict tenon strip 231 in the mortise 211 inside, thereby avoid when rotatory spacing subassembly one 2, bayonet lock 24 breaks away from curb plate 21.

Referring to fig. 8, it is shown that: the top plate 22 and the bottom plate 23 are respectively provided with a second sliding block 221 inserted into the frame 1; the second slider 221 is slidably connected to the frame 1.

The frame 1 is provided with a third sliding groove for accommodating the second sliding block 221, and the top end of the third sliding groove is provided with an opening for the second sliding block 221 to be far away from or close to the frame 1, so that after the glass is mounted on the first limiting component 2, the first limiting component 2 is firstly rotated to be vertical, then the first limiting component 2 can be pulled to be close to the frame 1, then the second sliding block 221 can enter the inside of the third sliding groove, and then the first limiting component 2 is driven to slide downwards, so that the second sliding block 221 can be limited in the inside of the third sliding groove, and the first limiting component 2 can be smoothly fixed on the frame 1, so that the first limiting component 2 is prevented from rotating on the frame 1.

Referring to fig. 1-10: a construction process of a building curtain wall comprises the following steps:

s1, rotating the first limiting component 2 to be in a horizontal state, and then removing the bottom plate 23 from the side plates 21 and installing glass between the two side plates 21;

s2, fixing the bottom plate 23 on the side plate 21 and rotating the first limiting component 2 to a vertical state;

s3, pulling the first limiting component 2 to be close to the frame 1 until the top plate 22 of the first limiting component 2 is mutually abutted with the frame 1;

s4, the first limiting component 2 is driven to move vertically downwards, so that the top plate 22 and the bottom plate 23 are simultaneously abutted against the frame 1.

When new glass needs to be installed or replaced, the limiting device can firstly drive the limiting device to vertically move upwards, so that the second sliding blocks 221 of the top plate 22 and the bottom plate 23 are separated from the third sliding groove, then the limiting device 1 is pushed to be far away from the frame 1, so that the second sliding blocks 221 are far away from the frame 1, then the limiting device 2 can be rotated, meanwhile, under the action of the limiting device 34, the limiting device 2 can be rotated to be in a horizontal state, then the bottom plate 23 is removed from the side plate 21, then the glass can be installed or replaced, when the glass is installed, the bottom plate 23 can be fixed on the side plate 21, then the limiting device 2 is rotated to be in a vertical state, then the limiting device 2 is pulled, so that the limiting device 2 is gradually close to the frame 1 until the top plate 22 and the frame 1 are mutually attached, meanwhile, the second sliding blocks 221 are inserted into the third sliding groove, then the limiting device 2 can be driven to vertically move downwards, so that the top plate 22 and the bottom plate 23 are simultaneously abutted against the surface of the frame 1, then the positioning shaft 352 is inserted into the sliding seat 331, and the limiting device 2 is limited in the vertical direction.

The foregoing examples merely illustrate one or more embodiments of the invention, which are described in greater detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of the invention should be assessed as that of the appended claims.

Claims (10)

1. The energy-saving building curtain wall structure comprises a frame (1), a first limiting component (2) and a turnover component (3), wherein the first limiting component (2) comprises two side plates (21) which are parallel to each other, and a top plate (22) and a bottom plate (23) which are used for connecting the two side plates (21), and the bottom plate (23) is detachably and fixedly connected with the side plates (21);

the turnover assembly (3) is characterized by comprising a supporting seat (31), a rotating seat (32) and a sliding assembly (33);

the rotating seat (32) is arranged on the outer side of the side plate (21), and the rotating seat (32) is rotationally connected with one end of the supporting seat (31);

the supporting seat (31) is in sliding connection with the inner side wall of the frame (1);

the sliding component (33) is arranged on the outer side of the side plate (21) and is used for driving the rotating seat (32) to linearly displace on the side plate (21).

2. An energy efficient building curtain wall construction according to claim 1, wherein the sliding assembly (33) comprises a slide (331) and a first elastic assembly (332);

the sliding seat (331) and the first elastic component (332) are arranged on the outer side of the side plate (21), and the sliding seat (331) is fixedly connected with the rotating seat (32);

the sliding seat (331) is in sliding connection with the side plate (21), and the sliding direction is parallel to the length direction of the side plate (21);

the first elastic component (332) is used for driving the sliding seat (331) away from the top plate (22).

3. An energy-saving building curtain wall structure according to claim 1, characterized in that a second limiting component (34) is arranged between the rotating seat (32) and the supporting seat (31), and the second limiting component (34) comprises a limiting block (341), a guide shaft (342) and a second elastic component (343);

the top end of the limiting block (341) is connected with a guide shaft (342);

a limiting groove which is clamped with the limiting block (341) is formed in the supporting seat (31);

the guide shaft (342) is inserted into the rotating seat (32) and is in clearance fit with the rotating seat (32), and the axis of the guide shaft (342) passes through the axis of the rotating seat (32);

the second elastic component (343) is respectively connected with the rotating seat (32) and the limiting block (341), and the second elastic component (343) is used for driving the limiting block (341) to be far away from the rotating seat (32).

4. An energy-efficient building curtain wall construction according to claim 2, characterized in that the support seat (31) is internally provided with a positioning assembly (35), the positioning assembly (35) comprising a first slider (351) and a positioning shaft (352);

the first sliding block (351) is arranged in the supporting seat (31) in a sliding mode, and the first sliding block (351) is rotationally connected with the positioning shaft (352);

the positioning shaft (352) is used for being inserted into the sliding seat (331).

5. The energy-saving building curtain wall structure according to claim 4, wherein one end of the positioning shaft (352) inserted into the sliding seat (331) is provided with a plurality of circular arc buckles (3521) distributed circumferentially;

the sliding seat (331) is provided with a positioning groove which is mutually clamped with the arc buckle (3521).

6. An energy efficient building curtain wall construction according to claim 1, characterized in that the top end of the frame (1) interior is provided with a pull rod (36) connected to the side plates (21).

7. An energy-efficient building curtain wall construction according to claim 1, characterized in that the two ends of the bottom plate (23) are provided with tongue bars (231) respectively;

the side plates (21) are provided with mortise slots (211) for accommodating tenon strips (231);

the side plate (21) is also provided with a bayonet lock (24), and the bayonet lock (24) penetrates into the mortise (211) and is inserted into the tenon strip (231).

8. An energy-efficient building curtain wall construction according to claim 7, characterized in that the side plates (21) are further provided with a third elastic assembly (25) for driving the bayonet lock (24) close to the inside of the mortise slot (211).

9. An energy-efficient building curtain wall construction according to claim 1, characterized in that the top plate (22) and the bottom plate (23) are provided with second sliding blocks (221) inserted into the frame (1) respectively;

the second sliding block (221) is in sliding connection with the frame (1).

10. A construction process of a building curtain wall, adopting the energy-saving building curtain wall structure and the construction process as claimed in any one of claims 1 to 9, characterized by comprising the following steps:

s1, rotating a first limiting component (2) to be in a horizontal state, and then removing a bottom plate (23) from a side plate (21) and installing glass between the two side plates (21);

s2, fixing a bottom plate (23) on the side plate (21) and rotating the first limiting component (2) to a vertical state;

s3, pulling the first limiting component (2) to be close to the frame (1) until a top plate (22) of the first limiting component (2) is mutually abutted with the frame (1);

s4, then driving the first limiting component (2) to vertically move downwards, so that the top plate (22) and the bottom plate (23) are simultaneously abutted with the frame (1).