CN216130757U - Earthquake-resistant connection integrated structure for building door and window frames - Google Patents

Abstract

The utility model relates to a building door and window frame antidetonation integrated structure of connecting, especially, relate to door and window frame structure field, including outer frame body and inner frame body, the outer frame body sets firmly in the wall body, still include elasticity latch mechanism, the inner frame body passes through elasticity latch mechanism joint to be fixed in outer frame body inner chamber, elasticity latch mechanism includes two sets of elasticity joint subassemblies, two elasticity joint subassemblies set up in the both sides of inner frame body direction of height, elasticity joint subassembly includes the pressure spring, clamp plate and slider, pressure spring one end is connected with the inner frame body lateral wall, the other end is connected with the clamp plate, the slider presss from both sides and establishes between clamp plate and outer frame body inside wall, the draw-in groove that is used for the joint slider is offered to the outer frame body inside wall below the slider. This application has the effect that improves door and window frame connection structure shock resistance.

Description

Earthquake-resistant connection integrated structure for building door and window frames

Technical Field

The application relates to the field of door and window frame structures, in particular to an earthquake-resistant connection integrated structure of a building door and window frame.

Background

Along with the development of the building industry, people pay more attention to the safety performance of buildings, the safety of the buildings is influenced to a great extent by the building structure, and even if the building structure is a common door and window frame, the structure of the building structure is safer and more stable.

The utility model discloses a chinese utility model patent document of application number 201621433285.9 discloses an aluminium door and window frame structure, including metal casing, connect the cornerite, rivers pipeline and drainage tube, metal casing is the rectangle form, metal casing one side is through bolted connection cornerite, the inside rivers pipeline that is equipped with of metal casing, it is equipped with the drainage tube to connect the interior rivers pipeline department of being located of cornerite, it divide into two parts to connect the cornerite, including preceding cornerite and back cornerite wherein, preceding cornerite passes through on the frame of bolted connection metal casing one side, back cornerite passes through on the adjacent metal casing frame of bolted connection preceding cornerite, preceding cornerite is inside to be equipped with through the mould pressing and detains the seat, inside moulding pressing connection buckle that passes through of back cornerite.

In view of the above-mentioned related art, the inventors considered that there was a drawback that the seismic capacity was insufficient and it was difficult to maintain a stable structure when a natural disaster such as an earthquake occurred.

SUMMERY OF THE UTILITY MODEL

In order to improve the lower problem of door and window frame connection structure shock resistance, this application provides a building door and window frame antidetonation connection integral structure.

The application provides a pair of building door and window frame antidetonation connection integral structure adopts following technical scheme:

building door and window frame antidetonation connection integral structure, including outer frame body and interior frame body, the outer frame body sets firmly in the wall body, still includes elasticity latch mechanism, interior frame body passes through elasticity latch mechanism joint to be fixed in the outer frame inner chamber, elasticity latch mechanism includes two sets of elasticity joint subassemblies, two elasticity latch subassembly set up in the both sides of interior frame body direction of height, elasticity latch subassembly includes pressure spring, clamp plate and slider, pressure spring one end is connected with the inner frame body lateral wall, the other end with the clamp plate is connected, the slider clamp is established the clamp plate with between the outer frame body inside wall, the draw-in groove that is used for the joint slider is offered in the slider below to the outer frame body inside wall.

By adopting the technical scheme, when no earthquake occurs, the inner frame body is abutted tightly through the two elastic clamping mechanisms, the sliding block is pressed on the inner side wall of the outer frame body through the pressure spring by the pressure spring, when the earthquake occurs, the inner frame body shakes leftwards and rightwards, when the inner frame body shakes to the left side, the abutting action of the pressure spring and the pressure plate on the right side on the sliding block is weakened, the sliding block on the right side slides downwards along the inner side wall of the outer frame body under the action of self gravity, when the inner frame body shakes to the right side, the abutting action of the pressure spring and the pressure plate on the left side on the sliding block is weakened, the sliding block on the left side slides downwards along the inner side wall of the outer frame body under the action of self gravity, when the left sliding block and the right sliding block slide to the corresponding clamping grooves, the sliding block is pressed into the clamping grooves under the action of the pressure spring, the compression amplitude of the pressure spring is weakened at the moment, and the pressure spring drives the inner frame body to elastically shake by a larger amplitude in the horizontal direction, so as to weaken the earthquake, thereby achieving the effect of shock absorption.

Optionally, two sets of limiting parts are arranged on the inner side wall of the outer frame body corresponding to the two sliding blocks, each set of limiting parts comprises two limiting strips, the two limiting strips are respectively located on two corresponding sides of the corresponding sliding block, and the lower ends of the limiting strips extend to the upper ends of the clamping grooves.

Through adopting above-mentioned technical scheme, spacing can restrict the slip orbit of slider for the slider can accurately slide in the draw-in groove.

Optionally, be provided with the canceling release mechanical system that is used for reseing the slider that inserts the draw-in groove on the outer frame body inside wall, canceling release mechanical system is including supporting the ejector pad and setting up the connecting rod on supporting the ejector pad, it all sets up to the wedge to support ejector pad and slider, just the inclined plane that supports ejector pad and slider sets up relatively, set up along outer frame body direction of height on the outer frame body inside wall of draw-in groove below with the recess of draw-in groove intercommunication, it slides and sets up to support the ejector pad in the recess, the connecting rod is kept away from the one end that supports the ejector pad and is stretched out to the outer frame body.

Through adopting above-mentioned technical scheme, after the earthquake, can manually promote the connecting rod and drive to support the ejector pad and support the slider to push out from the draw-in groove, realize restoring to the throne of slider, pressure spring for the centre gripping is fixed in outer frame inner chamber under the effect of pressure spring to interior frame, reduces the possibility of skew in the daily use.

Optionally, the elastic connection mechanism is set to be two springs, the two springs are symmetrically arranged on the upper side and the lower side of the inner frame body, one end of each spring is connected with the outer side wall of the inner frame body, and the other end of each spring is connected with the inner side wall of the outer frame body.

By adopting the technical scheme, when an earthquake occurs, the spring can enable the inner frame body to elastically rock in the height direction, and the vibration of the earthquake to the inner frame body in the height direction is weakened.

Optionally, a rubber layer is arranged between the inner side wall of the inner frame body and the outer side wall of the door and window mounting frame.

Through adopting above-mentioned technical scheme, can be further absorbed when the rubber layer is conducted in the vibrations of earthquake for the degree of rocking that door and window mounting frame received reduces, has reduced the possibility that the earthquake damaged door and window mounting frame.

Optionally, a clamping groove is formed in the inner side wall of the door and window mounting frame, and a damping pad strip is arranged in the clamping groove.

Through adopting above-mentioned technical scheme, when the earthquake takes place, the shock attenuation filler strip makes door and window not directly collide with the joint groove of door and window installing frame when rocking, has reduced the damage that the door and window installing frame probably caused door and window.

Optionally, a damping layer is arranged between the outer side wall of the outer frame body and the wall body.

Through adopting above-mentioned technical scheme for vibrations just are weakened before conducting outer frame, and then make the follow-up possibility that causes the damage to door and window frame inner structure of vibrations reduce.

Optionally, the door and window installing frame, inner frame body, outer frame body and buffer layer are covered with outer shrouding jointly, outer shrouding is connected with the outer frame body, is close to seted up the confession on the outer shrouding of connecting rod the strip groove that the connecting rod was worn out and was removed.

Through adopting above-mentioned technical scheme, with the inside structure of door and window frame and external environment isolation, increased the life of the inside elasticity latch mechanism of door and window frame.

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

the elastic clamping mechanism is arranged between the inner frame body and the outer frame body, so that the sliding block can slide into the clamping groove under the action of self gravity when an earthquake occurs, the inner frame body can elastically shake to a larger extent in the horizontal direction, the energy transmitted to the inner frame body by the earthquake is further weakened, and the shock absorption effect is realized;

the reset mechanism is arranged on the inner side wall of the outer frame body, and after the earthquake is over, the connecting rod can be manually pushed to drive the pushing block to push the sliding block out of the clamping groove, so that the sliding block and the pressure spring are reset, the inner frame body is firmly pressed on the inner side wall of the outer frame body again, and the possibility of deviation in daily use is reduced;

when the sliding block slides into the clamping groove, the inner frame body can elastically rock in the height direction by the aid of the two springs, and vibration of the earthquake to the inner frame body in the height direction is weakened.

Drawings

Fig. 1 is a schematic overall structure view of an earthquake-resistant connection integrated structure of a building door and window frame in an embodiment of the application.

Fig. 2 is a schematic view of the internal structure of the integrated structure for earthquake-proof connection of the building window and door frame in the embodiment of the application.

Fig. 3 is a partial structural view of the integrated structure for earthquake-proof connection of the window and door frame of the building in fig. 2.

Fig. 4 is an exploded view of the portion of the resilient latch mechanism of fig. 2.

Reference numerals: 1. an outer frame body; 11. a card slot; 12. a limiting strip; 13. a groove; 2. an inner frame body; 21. a spring; 3. a door and window mounting frame; 31. a clamping groove; 311. doors and windows; 4. an elastic clamping mechanism; 41. a pressure spring; 42. pressing a plate; 43. a slider; 5. a reset mechanism; 51. pushing the block; 52. a connecting rod; 6. an outer sealing plate; 61. a strip-shaped groove; 7. a shock-absorbing layer; 8. a wall body.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses building door and window frame integrated structure is connected to antidetonation.

Referring to fig. 1, fig. 2, fig. 3, building door and window frame antidetonation is connected integral structure and is included buffer layer 7, outer frame 1, elasticity latch mechanism 4, inner frame 2, door and window installing frame 3, and outer shrouding 6, outer frame 1 passes through the bolt fastening in wall body 8, buffer layer 7 is filled between 1 lateral wall of outer frame and wall body 8, buffer layer 7 adopts the sponge, inner frame 2 is fixed in 1 inner chamber of outer frame through the 4 joint of elasticity latch mechanism, 3 joints of door and window installing frame are fixed in 2 inner chambers of inner frame, 6 welds on outer frame 1 of outer shrouding, outer shrouding 6 covers buffer layer 7, outer frame 1, elasticity latch mechanism 4, inner frame 2, door and window installing frame 3.

Referring to fig. 3 and 4, elasticity latch mechanism 4 includes two sets of elasticity latch subassemblies, two elasticity latch subassemblies set up in 2 both sides of interior framework along 2 direction of height of interior framework, elasticity latch subassembly includes pressure spring 41, clamp plate 42 and slider 43, frame 2 including pressure spring 41 sets up perpendicularly, pressure spring 41 one end glues and establishes on 2 lateral walls of interior framework, the other end glues and establishes on clamp plate 42, slider 43 presss from both sides and establishes and keeps away from between pressure spring 41 one side and the 1 inside wall of outer framework at clamp plate 42, draw-in groove 11 that is used for joint slider 43 is offered to the 1 inside wall of outer framework below slider 43. In the draw-in groove 11 for the smooth income that slider 43 can be accurate, correspond two sliders 43 on the 1 inside wall of outer frame and be provided with two sets of locating parts, every locating part of group includes two and glues the spacing 12 of establishing on 1 inside wall of outer frame, and two spacing 12 are located slider 43 both sides respectively, and two spacing 12 lower extremes extend to draw-in groove 11 upper end.

Referring to fig. 2, fig. 3, fig. 4, in order to reduce the possibility of the deviation of the inner frame body 2 in daily use, a reset mechanism 5 for resetting the slider 43 inserted into the slot 11 is arranged on the inner side wall of the outer frame body 1, the reset mechanism 5 comprises a pushing block 51 and a connecting rod 52 welded on the pushing block 51, the pushing block 51 and the slider 43 are both arranged to be wedge-shaped blocks, the slopes of the pushing block 51 and the slider 43 are opposite and parallel, a groove 13 with a depth shallower than the slot 11 is formed in the inner side wall of the outer frame body 1 below the slot 11 along the height direction of the outer frame body 1, the groove 13 is communicated with the slot 11, the pushing block 51 is slidably clamped in the groove 13, the connecting rod 52 is welded on the pushing block 51, one end of the connecting rod 52 far away from the pushing block 51 extends out of the outer frame body 1, and a strip-shaped groove 61 for the connecting rod 52 to penetrate out and move is formed in the outer sealing plate 6 near the connecting rod 52.

Referring to fig. 3, an elastic connection mechanism is further arranged between the inner frame body 2 and the outer frame body 1, the elastic connection mechanism is composed of two springs 21, the two springs 21 are symmetrically welded on the upper side and the lower side of the inner frame body 2, one end of each spring 21 is connected with the outer side wall of the inner frame body 2, and the other end of each spring 21 is connected with the inner side wall of the outer frame body 1.

Referring to fig. 2 and 4, 3 joints of door and window installing frame are fixed in the 2 inner chambers of inner frame body, glue between 3 lateral walls of door and window installing frame and the 2 inside walls of inner frame body and be equipped with the rubber layer, and the rubber layer is not shown in the figure, has seted up joint groove 31 on the inside wall of door and window installing frame 3, and joint inslot 31 inside callipers has door and window 311, and the diapire in joint groove 31 and two lateral walls and door and window 311 between all fill up and be equipped with the shock pad strip, and the shock pad strip is not shown in the figure.

The implementation principle of the integrated structure is connected to building door and window frame antidetonation of this application embodiment does: when no earthquake occurs, the inner frame body 2 is abutted by the two elastic clamping mechanisms 4, and the sliding block 43 is pressed on the inner side wall of the outer frame body 1 by the pressure spring 41 through the pressure plate 42; when an earthquake occurs, the inner frame body 2 shakes left and right, when the inner frame body 2 shakes to the left, the pressing action of the pressure spring 41 and the pressure plate 42 on the right side on the sliding block 43 is weakened, the sliding block 43 on the right side slides downwards along the inner side wall of the outer frame body 1 under the action of self gravity, when the inner frame body 2 shakes to the right side, the pressing action of the pressure spring 41 and the pressure plate 42 on the left side on the sliding block 43 is weakened, the sliding block 43 on the left side slides downwards along the inner side wall of the outer frame body 1 under the action of self gravity, when the two sliding blocks 43 on the left side and the right side slide to the corresponding clamping grooves 11, the sliding block 43 is pressed into the clamping grooves 11 under the action of the pressure spring 41, the compression amplitude of the pressure spring 41 is weakened, and the pressure spring 41 drives the inner frame body 2 to shake elastically by a larger amplitude in the horizontal direction, so that the earthquake vibration is weakened, and the damping effect is achieved; when the earthquake is over, the connecting rod 52 is manually pushed to drive the pushing block 51 to push the sliding block 43 out of the clamping groove 11, so that the sliding block 43 and the pressure spring 41 are reset, the inner frame body 2 is firmly pressed on the inner side wall of the outer frame body 1 again, and the possibility of the inner frame body 2 shifting in daily use is reduced.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. Building door and window frame antidetonation connection integral structure, including outer frame body (1) and interior frame body (2), outer frame body (1) sets firmly in wall body (8), its characterized in that: still include elasticity latch mechanism (4), interior framework (2) are fixed through elasticity latch mechanism (4) joint in outer framework (1) inner chamber, elasticity latch mechanism (4) include two sets of elasticity joint subassemblies, two elasticity latch subassembly set up in interior framework (2) direction of height's both sides, elasticity latch subassembly includes pressure spring (41), clamp plate (42) and slider (43), pressure spring (41) one end is connected with interior framework (2) lateral wall, the other end with clamp plate (42) are connected, slider (43) press from both sides and establish clamp plate (42) with between outer framework (1) inside wall, draw-in groove (11) that are used for joint slider (43) are offered in slider (43) below to outer framework (1) inside wall.

2. The integrated structure for earthquake-resistant connection of a building door and window frame according to claim 1, wherein: correspond two on outer frame body (1) inside wall slider (43) are provided with two sets of locating parts, and every group the locating part includes two spacing (12), two spacing (12) are located the correspondence respectively slider (43) both sides, spacing (12) lower extreme extends to draw-in groove (11) upper end.

3. The integrated structure for earthquake-resistant connection of a building door and window frame according to claim 1, wherein: be provided with canceling release mechanical system (5) that is used for restoring to the throne slider (43) that inserts draw-in groove (11) on outer frame body (1) inside wall, canceling release mechanical system (5) are including supporting ejector pad (51) and setting connecting rod (52) on supporting ejector pad (51), it sets up to the wedge to support ejector pad (51) and slider (43), just support the relative setting in inclined plane of ejector pad (51) and slider (43), set up along outer frame body (1) direction of height on outer frame body (1) inside wall of draw-in groove (11) below with recess (13) of draw-in groove (11) intercommunication, it slides and sets up to support ejector pad (51) in recess (13), the one end of keeping away from to ejector pad (51) of connecting rod (52) is stretched out outside outer frame body (1).

4. The integrated structure for earthquake-resistant connection of a building door and window frame according to claim 1, wherein: still include elastic connection mechanism, elastic connection mechanism sets up to two springs (21), two spring (21) symmetry set up in both sides about interior framework (2), spring (21) one end with interior framework (2) lateral wall is connected, the other end with outer framework (1) inside wall is connected.

5. The integrated structure for earthquake-resistant connection of a building door and window frame according to claim 3, wherein: the door and window installing frame is characterized in that a door and window installing frame (3) is connected in the inner cavity of the inner frame body (2) in a clamping mode, and a rubber layer is arranged between the outer side wall of the door and window installing frame (3) and the inner side wall of the inner frame body (2).

6. The integrated structure for earthquake-resistant connection of a building door and window frame according to claim 5, wherein: the door and window mounting frame is characterized in that a clamping groove (31) is formed in the inner side wall of the door and window mounting frame (3), and a damping pad strip is arranged in the clamping groove (31).

7. The integrated structure for earthquake-resistant connection of a building door and window frame according to claim 1, wherein: and a damping layer (7) is arranged between the outer side wall of the outer frame body (1) and the wall body (8).

8. The integrated structure for earthquake-resistant connection of a building door and window frame according to claim 5, wherein: door and window installing frame (3), inner frame body (2), outer frame body (1) and buffer layer (7) cover jointly outward and are equipped with outer shrouding (6), outer shrouding (6) are connected with outer frame body (1), are close to seted up the confession on outer shrouding (6) of connecting rod (52) strip groove (61) that connecting rod (52) were worn out and were removed.

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