CN217439812U - Sliding attaches frame door and window system with high heat preservation performance - Google Patents

Abstract

The utility model relates to a sliding attaches frame door and window system with high heat preservation performance relates to door and window's technical field, and it includes supporting mechanism, glass, supporting mechanism includes: thermal-insulated nut, attach frame, linking frame, thermal-insulated nut sets up attach on the frame, linking frame is last to have seted up the through-hole, and linking frame links to each other with attaching the frame through thermal-insulated nut, and the heat just can transmit to attaching on the frame and then transmit the wall body when the conduction through thermal-insulated nut on, because thermal conduction efficiency has been reduced in setting up of thermal-insulated nut, and then has improved door and window's heat preservation effect.

Description

Sliding attaches frame door and window system with high heat preservation performance

Technical Field

The utility model belongs to the technical field of the door and window technique and specifically relates to a sliding attaches frame door and window system with high heat preservation performance.

Background

In order to increase the lighting and ventilation area or represent the character and character of modern buildings, the door and window area of the building is larger and larger, and the building is provided with a full-glass curtain wall, so that the heat loss of the door and window accounts for more than 40% of the total heat loss of the building; therefore, the energy saving of the doors and windows is the key of the energy saving of buildings. At present, most of glass is energy-saving glass such as LOW-E glass, and heat in a building is difficult to directly conduct to the outside of the building through the glass, so that heat loss of the building is mostly dissipated to a wall body through a window frame.

At present, China invention application with publication number CN106837060A on 2017, 06 and 13.2017 provides an auxiliary frame combination system of a bridge-cut heat-insulation window frame, which comprises a window frame, an auxiliary frame and an angle code, wherein glass is installed on the window frame, the window frame is connected to the auxiliary frame through self-tapping screws in a threaded manner, the auxiliary frame is fixedly connected to the angle code through bolts and nuts, and the angle code is connected to a wall body through shooting nails.

In view of the above-mentioned related art, the inventor believes that the window frame and the auxiliary frame are directly connected by using the tapping screws, so that heat on the window frame is easily conducted to the auxiliary frame through the tapping screws, and further, the heat preservation effect of the window frame is poor.

Disclosure of Invention

In order to improve the poor problem of the thermal-insulated effect of heat preservation that the door and window frame protected, this application provides a sliding attaches frame door and window system with high heat preservation performance.

The utility model discloses a realize that the technical scheme that above-mentioned purpose adopted is:

the utility model provides a sliding attaches frame door and window system with high heat preservation performance, includes supporting mechanism, glass and coupling mechanism, supporting mechanism includes: thermal-insulated subassembly, attach frame, linking frame, thermal-insulated subassembly includes thermal-insulated nut and thermal-insulated bolt, thermal-insulated nut sets up attach on the frame, linking frame is last to have seted up first through-hole, linking frame is attaching on the frame through thermal-insulated bolted connection, glass sets up on linking frame, attach the frame and pass through coupling mechanism and connect on the wall body.

Through adopting above-mentioned technical scheme, thermal-insulated nut is connected on attaching the frame, and the linking frame links to each other with attaching the frame through thermal-insulated nut, and the heat just can transmit to attaching the frame and then transmit the wall body on through thermal-insulated nut when the conduction, because thermal conduction efficiency has been reduced in setting up of thermal-insulated nut, and then has improved door and window's heat preservation effect.

Optionally, a sliding groove is formed in the auxiliary frame, the heat insulation nut is arranged in the sliding groove in a sliding mode, and the heat insulation nut is connected with the sliding groove in the auxiliary frame in a transition fit mode.

By adopting the technical scheme, the position of the heat insulation nut is adjusted, so that the heat insulation nut is aligned with the through hole; because the heat insulation nut is in transition fit connection with the sliding groove on the auxiliary frame, after the position of the heat insulation nut is adjusted, the heat insulation nut is not easy to slide in the sliding groove, the heat insulation bolt is convenient to be connected with the heat insulation nut, and then the connecting frame is convenient to be connected on the auxiliary frame.

Optionally, a rubber cushion block is arranged between the connecting frame and the auxiliary frame, and the rubber cushion block covers the sliding groove.

By adopting the technical scheme, the rubber cushion block can support the connecting frame, and the rubber cushion block has elasticity and elasticity for the auxiliary frame and the connecting frame, so that the heat insulation bolt is more compact in connecting the auxiliary frame and the connecting frame; and the rubber cushion block has the heat insulation effect, heat can be transferred to the auxiliary frame only through the rubber cushion block when being transferred, and then is transferred to the wall body, and the heat transfer efficiency is reduced due to the arrangement of the rubber cushion block, so that the heat insulation effect of the door and window is improved.

Optionally, a foam cushion strip is further arranged between the connecting frame and the auxiliary frame, and the foam cushion strip is arranged at a gap between the auxiliary frame and the connecting frame.

Through adopting above-mentioned technical scheme, the foam filler strip makes and does not leave the space between connection frame and the connection window frame, makes the leakproofness of window better, and then has reduced the conduction efficiency of temperature, and then has improved door and window's heat preservation effect.

Optionally, a heat insulation mechanism is arranged on the auxiliary frame, the heat insulation mechanism includes an outer heat insulation layer, and the outer heat insulation layer is arranged outside the auxiliary frame.

Through adopting above-mentioned technical scheme, attach the heat preservation that the frame outside was filled, can conduct to attaching the frame when the heat conducts again on, the heat can be by indoor to outdoor transmission attaching frame department, because the setting of heat preservation, makes the heat reduce attaching the conduction efficiency of frame department, and then improves door and window's heat preservation effect.

Optionally, the exterior of the external insulating layer is further provided with insulating mortar, the insulating mortar is also arranged on the wall, and one surface of the insulating mortar far away from the wall is flush with one surface of the external insulating layer far away from the wall.

Through adopting above-mentioned technical scheme, heat preservation mortar has prevented the direct contact who attaches frame and wall body, and the heat need be earlier can be conducted to the wall body through heat preservation mortar through outer heat preservation when conducting again, because heat preservation mortar's setting, and then has reduced the conduction efficiency of heat to the wall body, has improved the heat preservation effect of window frame.

Optionally, the heat-insulating mechanism further comprises an inner heat-insulating layer, and the inner heat-insulating layer is filled in the auxiliary frame.

Through adopting above-mentioned technical scheme, attach the interior heat preservation that the frame was inside to be filled, need pass through when the heat conducts again and attach the frame, just can conduct to the wall body on through interior heat preservation again, because the setting of interior heat preservation has reduced the rate of heat to the wall body conduction.

Optionally, the heat preservation mechanism further comprises heat preservation mortar, the heat preservation mortar is arranged on the wall, and one surface of the heat preservation mortar, which is far away from the wall, is flush with one surface of the auxiliary frame, which is far away from the wall.

Through adopting above-mentioned technical scheme, the heat need be when the transmission through heat preservation mortar attach the frame and attach the inside interior heat preservation of frame, and then reduced the conduction efficiency of heat to the wall body, improved the heat preservation effect of window frame.

Drawings

Fig. 1 is a schematic overall structure diagram of embodiment 1 of the present application;

FIG. 2 is a schematic cross-sectional view of embodiment 1 of the present application;

FIG. 3 is a schematic structural view of a heat-insulating nut according to embodiment 1 of the present application;

FIG. 4 is a schematic cross-sectional view of example 2 of the present application;

FIG. 5 is a schematic structural view of a heat-insulating nut according to embodiment 2 of the present application;

FIG. 6 is a schematic cross-sectional view showing the structure of embodiment 3 of the present application;

fig. 7 is a schematic structural view of an insulating nut according to embodiment 3 of the present application.

Description of reference numerals: reference numerals: 100. a support mechanism; 110. an auxiliary frame; 120. a sliding groove; 130. an insulating assembly; 131. a heat-insulating nut; 1311. a threaded portion; 1312. an anti-drop part; 1313 a support part; 140. a connecting frame; 150. a first through hole; 160. a second through hole; 200. a connecting mechanism; 210. an expansion bolt; 220. hot dip galvanized connecting piece; 230. self-tapping screw; 240. a heat-insulating bolt; 300. a heat preservation mechanism; 310. a heat-insulating layer; 320. insulating mortar; 330. a foam padding strip; 340. a rubber cushion block; 350. weather-resistant sealant; 400. glass; 500. a wall body; 600. a rubber gasket.

Detailed Description

The present invention will be described in further detail with reference to the accompanying fig. 1 to 7.

Example 1:

the embodiment of the application discloses sliding attaches frame door and window system with high heat preservation performance, refers to fig. 1, 2 and 3, and sliding door and window includes supporting mechanism 100, coupling mechanism 200, heat preservation mechanism 300, glass 400. The supporting mechanism 100 includes a connecting frame 140, an auxiliary frame 110 and a heat insulation assembly 130, the auxiliary frame 110 is connected to the wall 500 through a connecting mechanism 200, the connecting frame 140 is connected to the auxiliary frame 110 through the heat insulation assembly 130, and the heat insulation mechanism 300 is disposed on the auxiliary frame 110. After the heat in the building is conducted to the connection frame 140, the heat is conducted to the auxiliary frame 110 through the heat insulation assembly 130; the heat on the auxiliary frame 110 can be conducted to the outside of the building only through the heat preservation mechanism 300, so that the heat conduction efficiency is reduced, and the heat preservation effect is improved.

The connection mechanism 200 comprises a hot-dip galvanized connection 220, and the hot-dip galvanized connection 220 is mounted on the wall 500 through an expansion bolt 210. The heat preservation mechanism 300 comprises a heat preservation layer 310, in the embodiment of the present application, the heat preservation layer 310 is made of a graphite polystyrene board, the heat preservation layer 310 and the auxiliary frame 110 are co-extruded and formed through a steel-plastic co-extrusion integrated machine, and the heat preservation layer 310 is arranged outside the auxiliary frame 110. The heat-insulating layer 310 is further provided with a mounting groove, and the hot-dip galvanized connecting piece 220 is arranged in the mounting groove.

The connecting mechanism 200 further includes a tapping screw 230, the auxiliary frame 110 is provided with a second through hole 160 through which the tapping screw 230 passes, and the tapping screw 230 passes through the second through hole 160 and then is in threaded connection with the hot galvanizing connector 220, so that the auxiliary frame 110 is fixed on the hot galvanizing connector 220.

The auxiliary frame 110 is provided with a sliding groove 120, the heat insulation assembly 130 comprises a heat insulation nut 131 and a heat insulation bolt 240, the heat insulation nut 131 comprises a threaded portion 1311, a retaining portion 1312 and a supporting portion 1313, the threaded portion 1311 is arranged at a notch of the sliding groove 120, the retaining portion 1312 is connected with the threaded portion 1313, the retaining portion 1312 is arranged inside the sliding groove 120, and the supporting portion 1313 is connected with one end, away from the threaded portion 1311, of the retaining portion 1312. The heat insulation nut 131 is made of nylon 66, so that the heat insulation function is achieved, and the heat insulation nut 131 is in transition fit connection with the sliding groove 120 on the auxiliary frame 110.

The connection frame 140 is provided with a first through hole 150, and the heat insulation bolt 240 passes through the first through hole 150 and then is in threaded connection with the heat insulation nut 131, so as to connect the connection frame 140 to the auxiliary frame 110. When the heat insulation nut 131 is not aligned with the first through hole 150, the position of the heat insulation nut 131 is manually adjusted so that the threaded portion of the heat insulation nut 131 is aligned with the first through hole 150 and then threaded.

The heat preservation mechanism 300 comprises a rubber cushion block 340 and foam cushion strips 330, the rubber cushion block 340 is arranged between the connecting frame 140 and the heat preservation layer 310, the rubber cushion block 340 is covered on the auxiliary frame 110, the two foam cushion strips 330 are respectively arranged on two sides of the rubber cushion block 340, and the foam cushion strips 330 are arranged at a gap between the connecting frame 140 and the heat preservation layer 310; the heat preservation mechanism 300 further comprises weather-proof sealant 350, wherein the weather-proof sealant 350 is arranged on one side of the foam gasket 330 far away from the rubber cushion block 340; the heat insulation bolt 240 penetrates through the first through hole 150 of the connection frame 140 and penetrates through the rubber cushion block 340 to be connected with the heat insulation nut 131, and the connection between the connection frame 140 and the auxiliary frame 110 is tighter due to the elasticity of the rubber cushion block 340.

The connecting frame 140 is provided with a rubber gasket 600, the rubber gasket 600 is adhered to the connecting frame 140 through glue, the glass 400 is placed on the rubber gasket 600 to prevent the glass 400 from directly contacting the connecting frame 140, and the glass 400 is firmly adhered and sealed with the edge glass of the connecting frame 140.

The heat insulation mechanism 300 further comprises heat insulation mortar 320, the heat insulation mortar 320 is arranged on the wall 500, and one end, far away from the wall 500, of the heat insulation mortar 320 is flush with one end, far away from the wall 500, of the heat insulation layer 310. The heat is required to pass through the heat insulation nut 131 and then the heat insulation layer 310 when being conducted from the window frame to the wall body 500, and due to the arrangement of the heat insulation nut 131 and the heat insulation layer 310, the rate of heat conduction to the wall body 500 through the auxiliary frame 110 is reduced, so that the heat insulation effect is achieved.

The implementation principle of the sliding type auxiliary frame door and window system with high heat insulation performance is as follows: firstly, the hot galvanizing connector 220 is fixed on the wall body 500 through the expansion bolt 210, and the auxiliary frame 110 is fixed on the hot galvanizing connector 220 through the self-tapping screw 230. The heat insulation nut 131 is arranged in the sliding groove 120 in a transition mode, then the rubber cushion block 340 is covered on the heat insulation nut 131, then the connecting frame 140 is placed on the rubber cushion block 340, and the connecting frame 140, the rubber cushion block 340 and the heat insulation nut 131 are tightly connected through the heat insulation bolt 240; the foam gasket 330 is adhered to a gap between the connection frame 140 and the sub-frame 110 by weather-resistant sealant 350, and the foam gasket 330 is in contact with the rubber mat 340. The glass 400 is mounted on the connection frame 140 and is fixed to the connection frame 140 by bonding with a glass paste. Finally, spraying thermal mortar 320 on the wall 500, so that one end of the thermal mortar 320, which is far away from the wall 500, is flush with the thermal insulation layer 310.

The heat is conducted from the connection frame 140 to the auxiliary frame 110, to the heat preservation 310, to the heat preservation mortar 320, and finally to the wall 500.

The arrangement of the heat insulation nut 131 reduces the conduction efficiency of heat from the connecting frame 140 to the attached frame 110, the heat insulation layer 310 wrapped outside the attached frame 110 can slow down the conduction speed of heat from the attached frame 110 to the wall body 500, the heat insulation mortar 320 on the wall can slow down the conduction speed of heat at the hot galvanizing connecting piece 220, the heat needs to be transmitted to the wall body 500 through the heat insulation nut 131 and the heat insulation layer 310 and then through the heat insulation mortar 320 during conduction, and further the heat insulation effect of doors and windows is improved.

Example 2:

the embodiment of the present application discloses a sliding type attached frame door and window system with high thermal insulation performance, referring to fig. 4 and 5, the embodiment of the present application is different from embodiment 1 in that the thermal insulation layer 310 is filled in the whole sliding groove 120, and the thermal insulation layer 310 is made of graphite polystyrene board; the heat insulation nut 131 comprises a threaded portion 1311 and a retaining portion 1312, the threaded portion 1311 is arranged at a notch of the sliding groove 120, the retaining portion 1312 is connected with the threaded portion 1312, the retaining portion 1312 is arranged inside the sliding groove 120, the heat insulation mortar 320 is arranged on the wall body 500, one end, away from the wall body 500, of the heat insulation mortar 320 is flush with one end, away from the wall body 500, of the attachment frame 110, the rubber cushion block 340 is arranged between the attachment frame 110 and the connecting frame 140, and the rubber cushion block 340 covers the attachment frame 110. The foam padding strip 330 is arranged between the connecting frame 140 and the auxiliary frame 110, and the foam padding strip 330 is in close contact with one side of the rubber cushion block 340 close to the thermal insulation mortar 320.

The implementation principle of the sliding type auxiliary frame door and window system with high heat insulation performance is as follows: the heat insulation nut 131 is in transition fit connection with the sliding groove 120 on the auxiliary frame 110, the heat insulation nut 131 is not easy to slide relatively on the sliding groove 120, meanwhile, the heat insulation effect can be achieved, and the heat insulation layer 310 filled in the sliding groove 120 can strengthen the fixation of the heat insulation nut 131; the heat insulation mortar 320 on the wall can slow down the conduction speed of heat at the hot galvanizing connector 220, the heat can be conducted to the wall 500 through the heat insulation layer 310 and the heat insulation mortar 320 during conduction, and the heat insulation effect of the door and window is further improved due to the fact that the heat insulation layer 310 and the heat insulation mortar 320 are arranged to further prevent the heat from being conducted to the wall 500 from the window frame.

Example 3:

the embodiment of the present application discloses a sliding type attached frame door and window system with high thermal insulation performance, referring to fig. 6 and 7, the embodiment of the present application differs from embodiment 1 in that the thermal insulation layer 310 is filled inside the sliding groove 120 and is also arranged outside the attached frame 110, and the thermal insulation layer 310 is made of graphite polystyrene board; the end of the thermal insulation mortar 320 far away from the wall 500 is kept level with the end of the outer thermal insulation layer 310 far away from the wall 500.

The implementation principle of the sliding type auxiliary frame door and window system with high heat insulation performance is as follows: the heat insulation nut 131 is in transition fit connection with the sliding groove 120 on the auxiliary frame 110, the heat insulation nut 131 is not easy to slide relatively on the sliding groove 120, and meanwhile, the heat insulation nut 131 can play a role in energy conservation and heat insulation, the heat insulation layer 310 filled in the auxiliary frame 110 can strengthen the fixation of the heat insulation nut 131, and the heat insulation layer 310 is arranged in the auxiliary frame 110 and outside the auxiliary frame 110; the heat can be conducted to the wall 500 through the heat insulation nut 131, the heat insulation layer 310, the auxiliary frame 110, the heat insulation layer 310 and the heat insulation mortar 320 in sequence during conduction, and the heat insulation effect of the door and window is further improved due to the fact that the heat insulation layer 310 and the heat insulation mortar 320 are arranged to further prevent the heat from being conducted to the wall 500.

Above is the preferred embodiment of the utility model, not limit according to this the utility model discloses a protection scope, the event: all equivalent changes made according to the structure, shape and principle of the present invention should be covered within the protection scope of the present invention.

Claims (8)

1. A sliding type auxiliary frame door and window system with high heat insulation performance is characterized in that; including supporting mechanism (100), glass (400) and coupling mechanism (200), supporting mechanism (100) includes: thermal-insulated subassembly (130), attach frame (110), linking frame (140), thermal-insulated subassembly (130) is including thermal-insulated nut (131) and thermal-insulated bolt (240), thermal-insulated nut (131) set up attach on frame (110), first through-hole (150) have been seted up on linking frame (140), linking frame (140) are connected on attaching frame (110) through thermal-insulated bolt (240), glass (400) set up on linking frame (140), attach frame (110) and pass through coupling mechanism (200) and connect on wall body (500).

2. The sliding type auxiliary frame door and window system with high heat preservation performance as claimed in claim 1, wherein the auxiliary frame (110) is provided with a sliding groove (120), the heat insulation nut (131) is slidably disposed in the sliding groove (120), and the heat insulation nut (131) is in transition fit connection with the sliding groove (120) on the auxiliary frame (110).

3. The sliding type auxiliary frame door and window system with high heat insulation performance as claimed in claim 2, wherein a rubber pad (340) is disposed between the connecting frame (140) and the auxiliary frame (110), and the rubber pad (340) covers the sliding groove (120).

4. The sliding type auxiliary frame window and door system with high heat insulation performance as claimed in any one of claims 1-3, wherein a foam spacer (330) is further disposed between the connecting frame (140) and the auxiliary frame (110), and the foam spacer (330) is disposed at the gap between the auxiliary frame (110) and the connecting frame (140).

5. The sliding type auxiliary frame door and window system with high heat insulation performance according to any one of claims 1-3, wherein a heat insulation mechanism (300) is arranged on the auxiliary frame (110), the heat insulation mechanism (300) comprises an outer heat insulation layer (310), and the outer heat insulation layer (310) is arranged outside the auxiliary frame (110).

6. The sliding type auxiliary frame door and window system with high heat insulation performance as claimed in claim 5, wherein the outer heat insulation layer (310) is further provided with heat insulation mortar (320), the heat insulation mortar (320) is also provided on the wall body (500), and a surface of the heat insulation mortar (320) far away from the wall body (500) is flush with a surface of the outer heat insulation layer (310) far away from the wall body (500).

7. The sliding type auxiliary frame door and window system with high heat insulation performance as claimed in claim 5, wherein the heat insulation mechanism (300) further comprises an inner heat insulation layer (310), and the inner heat insulation layer (310) is filled inside the auxiliary frame (110).

8. The sliding type auxiliary frame door and window system with high heat insulation performance as claimed in claim 7, wherein the heat insulation mechanism (300) further comprises heat insulation mortar (320), the heat insulation mortar (320) is disposed on the wall (500), and a surface of the heat insulation mortar (320) far away from the wall (500) is flush with a surface of the auxiliary frame (110) far away from the wall (500).

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