CN114809770A - Damping assembly type full-exposed frame glass curtain wall - Google Patents

Abstract

The invention discloses a shock-absorbing assembly type full-exposed frame glass curtain wall, which comprises a superposed glass plate, a metal clamping frame, a vertical elastic framework, a horizontal elastic framework and a central pivot positioning device, wherein the superposed glass plate is arranged on the outer side of the metal clamping frame; the metal clamping frame is spliced around the superposed glass plate to jointly form a curtain wall component of the device; the outer side of the metal clamping frame is connected with the vertical elastic framework in the vertical direction and is connected with the horizontal elastic framework in the horizontal direction, and the vertical elastic framework and the horizontal elastic framework are connected through the center positioning device. The invention can simplify the installation procedure of the curtain wall by assembling the modularized superposed glass plate, the clamping frame and the framework, has simple operation, improves the installation efficiency, and can effectively control the operation quality by prefabricating the component; in addition, the inner and outer damping gaskets and the damping spacer blocks are arranged on the components, so that vibration energy can be effectively eliminated, and the safety of the curtain wall is ensured.

Description

Damping assembly type full-exposed frame glass curtain wall

Technical Field

The invention relates to the field of building curtain walls, in particular to a damping assembly type full-exposed frame glass curtain wall.

Background

The curtain wall is an outer enclosure structure of a building, and is a peripheral enclosure wall which consists of a panel and a supporting structure, can have a certain displacement capacity or a certain deformation capacity relative to a main structure and does not bear the action of the main structure.

The glass curtain wall is made up of steel structure as skeleton point and metal member and glass plate. The glass of the exposed frame glass curtain wall is embedded in the metal frame to form a curtain wall component with the metal frame on four sides. The members are embedded on the cross beams and the upright posts to form a vertical surface with the exposed cross beams and the exposed upright posts and obvious frame lattices. The exposed frame glass curtain wall is the most traditional form, has the most extensive application and reliable working performance.

In the existing construction, the full-exposed frame glass curtain wall framework is usually welded, glued or mechanically extruded to ensure the connection and fastening, and in addition, the installation operation of the double-layer glass curtain plate is also completed layer by layer in high-altitude operation, so that the installation operation period of the curtain wall is long and the high-rise construction process is complicated. Moreover, site operation uncertain factors are more, and product quality can not be guaranteed really, thereby influencing the installation quality of the glass curtain wall.

In addition, currently the support systems of the curtain wall skeleton are connected with the floor structure to fix the glass curtain wall in the vertical direction. When the floor slab vibrates up and down due to the vertical load, the connection part of the floor slab structure and the curtain wall structure is usually rigid, so that the vertical face curtain wall is inevitably subjected to the vibration transmitted by the rigid connection part. The corner rubber joint of the curtain wall and even the welding joint of the steel frame of the curtain wall are torn off and cracked, and then the safety of the curtain wall is affected.

In summary, how to effectively solve the problems that the existing glass curtain wall has various field procedures and equipment during installation operation, and the curtain wall and the framework thereof cannot effectively dissipate energy and reduce vibration when vibration occurs is a problem which needs to be solved by technicians in the field at present.

Disclosure of Invention

The purpose of the invention is as follows: the glass curtain wall can be quickly installed on a construction site, and good energy dissipation and shock absorption capacity for vibration is provided for the curtain wall. The products required by the installation of the curtain wall are prefabricated, and the assembly process is short. Therefore, the assembled full-exposed frame glass curtain wall capable of absorbing shock is provided.

The technical scheme is as follows: in order to achieve the purpose, the invention adopts the technical scheme that:

a shock-absorbing assembly type full-exposed frame glass curtain wall comprises a superposed glass plate, a metal clamping frame, a vertical elastic framework, a horizontal elastic framework and a central positioning device. The metal clamping frame is spliced around the superposed glass plate to jointly form a curtain wall component of the device. The outer side of the metal clamping frame is connected with the vertical elastic framework in the vertical direction and is connected with the horizontal elastic framework in the horizontal direction. The vertical elastic framework and the horizontal elastic framework are connected through the central positioning device.

The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 1, is characterized in that: the laminated glass plate comprises two glass plates and a damping frame. The damping frame is an outer frame made of damping materials and has certain elasticity; two mounting grooves are formed in the damping frame, and the groove width is the same as the plate thickness of the glass plate.

The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 1, is characterized in that: the metal clamping frame comprises a vertical clamp, a horizontal clamp, a connecting ring, a positioning column, a damping splicing block and a buffer slot. The vertical clamp and the horizontal clamp are steel C-shaped components and are respectively arranged on the left side, the right side, the upper side and the lower side of the laminated glass plate. The connecting rings are evenly distributed at the axial end parts of the vertical clamp and the horizontal clamp. The positioning column is arranged in the transverse middle of the outer surfaces of the vertical clamp and the horizontal clamp. The damping splicing blocks are arranged at the tops of the positioning columns. The buffer slot is a slot with the depth the same as the thickness of the strip-shaped outer damping gasket and is arranged in the longitudinal middle of the surfaces of the vertical clamp and the horizontal clamp.

Preferably, the side frames of the vertical clamps are provided with symmetrically distributed grooves, and the side frames of the vertical horizontal clamps are provided with symmetrically distributed convex plates.

Preferably, the connecting rings of the vertical clamp ends are arranged at the left and right edges of the clamp ends, and the connecting rings of the horizontal clamp ends are arranged at the middle of the clamp ends.

Preferably, the damping splicing block is a damping material part, the lower layer of the damping splicing block is cylindrical, and the upper layer of the damping splicing block is a cross convex block or a cross concave block.

The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 1, is characterized in that: the vertical elastic framework and the horizontal elastic framework are steel column components with symmetrically hollowed middle parts, the side surfaces are symmetrically provided with outer damping gaskets and damping spacer blocks, one end part of each side surface is provided with a connecting ring, and the other end part is provided with a semicircular groove embedded with the positioning column.

Preferably, the end part of the vertical direction of the vertical elastic framework is provided with a first insert (31), and the end part of the horizontal direction of the horizontal elastic framework is provided with a second insert. The first insert is a Bu-shaped component made of damping material, and the second insert is a C-shaped component made of damping material.

Preferably, the vertical dimension of the second insert is twice the lateral dimension of the first insert superstructure.

Preferably, the shock-absorbing spacer block comprises a contact plate, an inner damping shim and a shock-absorbing spring.

The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 1, is characterized in that: the pivot positioning device comprises a fixing plate, a positioning rod and a positioning box. The fixing plate is a steel rectangular flat plate, and holes with the same radial size as the screw heads at the end parts of the right prisms in the positioning rods are symmetrically formed in the surface of the fixing plate. The locating rod is a steel component with a rectangular flat plate at the rear end face, four corner points protrude out of a right prism, and a screw head is arranged at the end part of the right prism. The positioning box is a combined steel member with a front end being a thick plate with a hollowed middle part and a rear end being a large-size plane thin plate, four corner points at the rear end of the positioning box are provided with wall attaching holes, and the front end is provided with a sealing cushion layer fixedly embedded with the rear end face of the positioning rod.

Preferably, the rear end face of the positioning rod is attached with an inner damping gasket and a damping spring. The inner side of the front end of the positioning box is attached with an inner damping gasket matched with the cushioning spring.

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

compared with the prior art, the curtain wall mounting process can be simplified by assembling the modularized superposed glass plate, the clamping frame and the framework, the operation is simple, the mounting efficiency is improved, and meanwhile, the operation quality can be effectively controlled by prefabricating the components. In addition, the inner and outer damping gaskets and the damping spacer blocks are arranged on the components, so that vibration energy can be effectively eliminated, and the safety of the curtain wall is ensured.

Drawings

Fig. 1 is a schematic view of the whole device of the assembled full-exposed frame glass curtain wall capable of damping according to the invention.

Fig. 2 is a schematic perspective view of the laminated glass sheet according to the present invention.

Fig. 3 is an isometric view of a metal bezel of the present invention.

Fig. 4 is an exploded view of the metal frame of the present invention.

Fig. 5 is an isometric view of a vertical elastomeric carcass of the present invention.

Fig. 6 is an isometric view of a horizontal elastic armature of the present invention.

FIG. 7 is a schematic view of a skeleton insert structure of the present invention

Fig. 8 is a schematic cross-sectional structure diagram of the vertical elastic skeleton of the invention.

FIG. 9 is an exploded view of the hub positioning device of the present invention

Fig. 10 is an enlarged schematic view of a portion a of fig. 4.

Fig. 11 is an enlarged schematic view at B in fig. 4.

Fig. 12 is an enlarged schematic view at C in fig. 8.

In the figure: 1 is coincide glass board, 2 is the metal clamp frame, 3 is vertical elasticity skeleton, 4 is horizontal elasticity skeleton, 5 is maincenter positioner, 11 is the glass board, 12 is the damping frame, 121 is the mounting groove, 21 is vertical anchor clamps, 22 is horizontal anchor clamps, 23 is the go-between, 24 is the reference column, 25 is damping splice block, 26 is the dashpot, 31 is first inserts, 32 is outer damping shim, 33 is the shock attenuation spacer block, 331 is the contact plate, 332 is interior damping shim, 333 is the bradyseism spring, 41 is the second inserts, 51 is the fixed plate, 52 is the locating lever, 53 is the locating box, 531 is attaching the wall hole, 532 is the seal cushion layer.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by persons skilled in the art without creative efforts based on the embodiments of the present invention belong to the protection scope of the present invention.

Referring to fig. 1 to 11, the shock-absorbing assembly type full-exposed frame glass curtain wall of the present invention includes a laminated glass plate 1, a metal clamping frame 2, a vertical elastic frame 3, a horizontal elastic frame 4, and a central positioning device 5. Two sets of metal clamping frames 2 which are symmetrical in the direction are spliced around the superposed glass plate 1 to jointly form a curtain wall component of the device. The outer side of the metal clamping frame 2 is connected with the vertical elastic framework 3 in the vertical direction and is connected with the horizontal elastic framework 3 in the horizontal direction. The vertical elastic framework 3 and the horizontal elastic framework 4 are connected through the central positioning device 5.

As shown in fig. 2, the laminated glass plate 1 comprises two glass plates 11 and a damping frame 12. The damping frame 12 is an outer frame made of damping material and has certain elasticity; two mounting grooves 121 are formed in the damping frame 12, and the width of a single mounting groove 121 is the same as the thickness of the glass plate. When the glass plate damping frame is used in field operation, workers can install the glass plate 11 into the installation groove 121 of the damping frame 12 along the peripheral edge, and the construction process is simple and quick.

As shown in fig. 3 to 4 and fig. 10 to 11, the metal clamping frame 2 includes a vertical clamp 21, a horizontal clamp 22, a connecting ring 23, a positioning column 24, a damping splice 25 and a buffer slot 26. The connecting rings 23 are evenly distributed at the axial ends of the vertical clamps 21 and the horizontal clamps 22. The positioning column 24 is arranged in the transverse middle of the outer surfaces of the vertical clamp 21 and the horizontal clamp 22. The damping splicing block 25 is arranged on the top of the positioning column 24. The buffer groove 26 is a groove with the depth the same as the thickness of the strip-shaped outer damping gasket 32, and is arranged in the longitudinal middle of the surfaces of the vertical clamp 21 and the horizontal clamp 22. The side frame department of vertical anchor clamps 21 is provided with the recess of symmetric distribution, and the side frame department of horizontal anchor clamps 22 is provided with the flange of symmetric distribution, the recess with the flange can mesh correspondingly when carrying out anchor clamps installation to the accuracy of anchor clamps installation location in the assurance class. And a positioning column 24 is arranged in the transverse middle of the outer surfaces of the two types of clamps, the component is a cylindrical component, and a damping splicing block 25 is arranged at the upper part of the positioning column 24. The damping splicing blocks 25 are in a cross convex shape and a cross concave shape, and the two types of damping splicing blocks 25 can be correspondingly embedded when being installed, so that the accuracy of installation and positioning of the fixture between the types is ensured. The end part of one longitudinal side of the clamp is provided with a connecting ring 23, wherein the vertical clamp 21 and the horizontal clamp 22 are both provided with two connecting rings 23, the two connecting rings of the vertical clamp 21 are arranged at the left edge and the right edge of the end part, and the two connecting rings of the horizontal clamp 22 are arranged in the middle of the end part. The longitudinal middle part of the outer surfaces of the two types of clamps is provided with a buffer groove 26, the groove depth and the groove width are the same as those of the strip-shaped outer damping gasket 32, and the deformation space of the outer damping gasket 32 can be provided when the curtain wall is vibrated.

As shown in fig. 5 to 7, the vertical elastic frame 3 and the horizontal elastic frame 4 are steel column members with symmetrically hollowed middle portions, the lateral surfaces are symmetrically provided with outer damping spacers 32 and shock absorbing spacers 33 with different shapes, a connecting ring 23 is provided at one longitudinal end of the lateral surface, and a semicircular groove embedded with the positioning post 24 is provided at the other longitudinal end. The vertical elastic framework 3 is provided with two connecting rings 23, the horizontal elastic framework 4 is provided with one connecting ring 23, and the transverse size of the total three connecting rings 23 is the same as the three space sizes of the four connecting rings 23 at the end parts of the vertical clamp 21 and the horizontal clamp 22. During installation, bolts with corresponding sizes penetrate through the seven connecting rings 23, and accordingly the fixed connection between the framework and the clamping frame in the corresponding direction can be achieved. The thickness and width of the strip-shaped pad in the outer damping pad 32 are the same as the groove depth and width of the buffer groove 26. The end part of the vertical direction of the vertical elastic framework 3 is provided with a first insert 31, and the end part of the horizontal direction of the horizontal elastic framework 4 is provided with a second insert 41. The first insert 31 is a Bu-shaped member made of a damping material, and the second insert 41 is a C-shaped member made of a damping material. The vertical dimension of the second insert 41 is twice the lateral dimension of the superstructure of the first insert 31. The inserts can be spliced correspondingly, four empty grooves are reserved at the corners, and the positioning rods 52 can be used for penetrating positioning.

As shown in fig. 8 and 12, the hollowed parts of the vertical elastic frame 3 and the horizontal elastic frame 4 comprise a contact plate 331, an internal damping shim 332 and a damping spring 333. The inner damping gasket 332 and the cushioning spring 333 are mounted on the back sides of the contact plate 331 and the outer damping gasket 32, and can generate elastic deformation when the curtain wall vibrates and the framework is under tension and compression, so that in-plane energy consumption is realized.

As shown in fig. 9, the center positioning device 5 includes a fixing plate 51, a positioning rod 52, and a positioning box 53. The fixing plate 51 is a rectangular steel plate, and holes with the same radial size as the screw heads at the end of the right prism in the positioning rod 52 are symmetrically formed on the surface of the fixing plate. The edge of the hole is also provided with an annular rubber sealing cushion layer 532 made of rubber, and the surface resistance of the rod piece can be increased after the screw head penetrating through the front end of the positioning rod 52 penetrates through the hole, so that the slipping danger is avoided. After the fixing plate 51 is installed, four nuts are screwed to complete the fixed connection of the central positioning device 5 with the vertical elastic framework 3 and the horizontal elastic framework 4. The positioning rod 52 is a steel member with a rectangular flat rear end face and four corner points protruding out of a rectangular prism, and a screw head is arranged at the end of the rectangular prism. The positioning box 53 is a combined steel member with a middle hollowed thick plate at the front end and a large-size plane thin plate at the rear end, four corner points at the rear end of the positioning box 53 are provided with wall attaching holes 531, the front end is provided with a sealing cushion layer 532 embedded with the rear end face of the positioning rod 52, the contact resistance between the surface of the member at the rear end of the positioning rod 52 and the inner face of the front end of the positioning box is increased, and meanwhile, the elastic energy consumption in four directions is realized when the positioning rod 52 is vibrated. An inner damping washer 332 and a damping spring 333 are attached to the rear end surface of the positioning rod 52. An inner damping washer 332 fitted with a damper spring 333 is attached to the inner side of the front end of the positioning box 52. The two damping gaskets 332 and the cushioning spring 333 are integrated components, so that the freedom degree of the positioning rod 52 perpendicular to the plane of the curtain wall glass is provided, and out-of-plane energy consumption is realized.

According to the invention, the corresponding number of prefabricated components such as the laminated glass plate, the metal clamping frame and the like can be selected according to actual requirements, gluing and welding are not needed in site construction, and the quality of the used components is ensured; various embedded positioning components are arranged among the components, so that the field installation precision is good; after the damping pad is installed, the assembly has appropriate freedom degree in the plane and the out-of-plane, and can generate deformation to dissipate energy through the damping pad, the cushioning spring and other members.

The above description is only of the preferred embodiments of the present invention, and it should be noted that: it will be apparent to those skilled in the art that various modifications and adaptations can be made without departing from the principles of the invention, and such modifications and adaptations are intended to be within the scope of the invention.

Claims (10)

1. A shock-absorbing assembly type full-exposed frame glass curtain wall comprises a superposed glass plate (1), a metal clamping frame (2), a vertical elastic framework (3), a horizontal elastic framework (4) and a central positioning device (5); the metal clamping frame (2) is spliced around the laminated glass plate (1) to jointly form a curtain wall component of the device; the metal clamping frame (2) is connected with the vertical elastic framework (3) in the vertical direction and connected with the horizontal elastic framework (4) in the horizontal direction, and the vertical elastic framework (3) and the horizontal elastic framework (4) are connected through the center positioning device (5).

2. The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 1, is characterized in that: the laminated glass plate (1) comprises two glass plates (11) and a damping frame (12), wherein the damping frame (12) is an outer frame made of damping materials; two mounting grooves (121) are formed in the damping frame (12), and the groove width is the same as the plate thickness of the glass plate (11).

3. The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 1, is characterized in that: the metal clamping frame (2) comprises a vertical clamp (21), a horizontal clamp (22), a connecting ring (23), a positioning column (24), a damping splicing block (25) and a buffer groove (26); vertical anchor clamps (21) and horizontal anchor clamps (22) are a steel C type component, set up respectively in the side and the last downside about coincide glass board (1), go up the axial tip of ring (23) evenly distributed at vertical anchor clamps (21) and horizontal anchor clamps (22), reference column (24) set up in the horizontal middle part of vertical anchor clamps (21) and horizontal anchor clamps (22) surface, damping concatenation piece (25) set up the top of reference column (24), dashpot (26) are the same groove of the outer damping gasket (32) thickness of a degree of depth and bar, set up in the vertical middle part on vertical anchor clamps (21) and horizontal anchor clamps (22) surface.

4. The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 3, is characterized in that: the side frame of the vertical clamp (21) is provided with symmetrically distributed grooves, and the side frame of the horizontal clamp (22) is provided with symmetrically distributed convex plates.

5. The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 3, is characterized in that: the connecting rings (23) at the ends of the vertical clamps (21) are arranged at the left edge and the right edge of the ends of the clamps, and the connecting rings (23) at the ends of the horizontal clamps (22) are arranged in the middle of the ends of the clamps.

6. The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 3, is characterized in that: the damping splicing block (25) is a damping material part, the lower layer of the damping splicing block is cylindrical, and the upper layer of the damping splicing block is a cross convex block or a cross concave block.

7. The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 1, is characterized in that: the vertical elastic framework (3) and the horizontal elastic framework (4) are steel column components with symmetrically hollowed middle parts, the side surfaces are symmetrically provided with outer damping gaskets (32) and damping spacers (33), one end part of each side surface is provided with a connecting ring (23), and the other end part of each side surface is provided with a semicircular groove fixedly embedded with the positioning column (24).

8. The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 7, is characterized in that: a first insert (31) is arranged at the end part of the vertical elastic framework (3) in the vertical direction, and a second insert (41) is arranged at the end part of the horizontal elastic framework (4) in the horizontal direction;

the first insert (31) is a Bu-shaped component made of a damping material, and the second insert (41) is a C-shaped component made of a damping material; the vertical dimension of the second insert (41) is twice the transverse dimension of the superstructure of the first insert (31); the shock absorption spacer block (33) comprises a contact plate (331), an inner damping gasket (332) and a shock absorption spring (333).

9. The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 1, is characterized in that: the central positioning device (5) comprises a fixing plate (51), a positioning rod (52) and a positioning box (53); fixed plate (51) are a steel rectangle flat board, and the surface symmetry is opened has the hole the same with the spiral shell head radial dimension of right prism tip in locating lever (52), the hole edge still is provided with rubber system annular seal bed course (532), can increase member surface resistance after the spiral shell head that passes the locating lever 52 front end passes the hole, locating lever (52) are the rectangle flat board for the rear end face, four corners point protrusion right prism's steel component, the tip of right prism is equipped with the spiral shell head, locating box (53) are a front end and dig out the thick plate for the middle part, the rear end is the combination steel component of jumbo size plane sheet metal, locating box (53) rear end four corners point has been seted up and has been attached wall hole (531), the front end is opened has and is inlayed solid seal bed course (532) with locating lever (52) rear end face.

10. The assembly type full exposed frame glass curtain wall capable of absorbing shock according to claim 9, wherein: an inner damping gasket (332) and a cushioning spring (333) are attached to the rear end face of the positioning rod (52), and an inner damping gasket (332) adapted to the cushioning spring (333) is attached to the inner side of the front end of the positioning box (52).

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