CN218206354U - Novel heat preservation door - Google Patents

Abstract

The utility model is suitable for a thermal insulation door technical field provides a novel thermal insulation door, including door frame mechanism and door leaf mechanism, door frame mechanism includes first framework and second framework, two first thermal-insulated strips of horizontal fixedly connected with between the front end of the rear end of first framework and second framework, forms first thermal-insulated chamber between the rear end surface of two first thermal-insulated strips and first framework and the front end surface of second framework. This novel heat preservation door, through setting up first thermal-insulated frame and the thermal-insulated frame of second, the heat preservation door is when closing, make the position of being connected between framework and the fan body obtain dual sealed through two first adhesive tapes and two second adhesive tapes, the sealed effect of junction has been improved, simultaneously the cavity between framework and the fan body junction is filled up to first thermal-insulated frame and the thermal-insulated frame of second, under the effect of the thermal-insulated silver of first heat preservation inside between them, the heat preservation effect at the position of being connected of framework and the fan body has also obtained the guarantee, thereby the heat preservation effect of whole heat preservation door has been improved, the practicality of this door has been improved.

Description

Novel heat preservation door

Technical Field

The utility model belongs to the technical field of the heat preservation door, especially, relate to a novel heat preservation door.

Background

In recent years, with the improvement of living standards and the rapid development of society, large-area glass doors and windows are adopted for more and more buildings in order to increase lighting and ventilation areas and improve the attractiveness of the buildings, but the heat loss of the external windows of the buildings accounts for about half of the heat loss of the whole buildings due to heat transfer and air permeation, so that the energy consumption of air conditioning systems in the buildings is very high in order to keep indoor comfort.

The heat preservation door product on the market is various now, nevertheless greatly with the difference all is with the framework and the fan internal portion of door set up a plurality of cavitys, thereby later fill in insulation material in the cavity inside and reach heat retaining effect, this kind of door and window compares with ordinary door and window though heat preservation performance has very big improvement really, nevertheless because the connection position of door frame and door leaf does not do any processing yet, the heat still runs off through this position easily, the heat preservation effect is not ideal.

SUMMERY OF THE UTILITY MODEL

The utility model provides a novel heat preservation door aims at solving ordinary heat preservation door because the connection position of door frame and door leaf does not do any processing yet, and the heat still runs off through this position easily, and the unsatisfactory problem of heat preservation effect.

The utility model is realized in such a way, a novel heat preservation door comprises a door frame mechanism and a door leaf mechanism;

the door frame mechanism comprises a first frame body and a second frame body, wherein two first heat insulation strips are transversely and fixedly connected between the rear end of the first frame body and the front end of the second frame body, a first heat insulation cavity is formed between the two first heat insulation strips and the rear end surface of the first frame body and the front end surface of the second frame body, the bottom ends of the first frame body and the second frame body are fixedly connected with mounting strips along the length direction of the first frame body, the front end of the upper surface of the first frame body is vertically and fixedly connected with a first mounting plate along the length direction of the first frame body, the top end of the rear side surface of the first mounting plate is fixedly connected with a first buckle strip, the upper surface of the first frame body is fixedly connected with a first heat insulation frame, and the rear end of the first heat insulation frame is fixedly connected with a second buckle strip along the length direction of the first heat insulation frame body;

the door leaf mechanism comprises a first leaf body and a second leaf body, wherein two second heat insulation strips are transversely and fixedly connected between the rear end of the first leaf body and the front end of the second leaf body, a second heat insulation cavity is formed between the two second heat insulation strips and the rear end surface of the first leaf body and the front end surface of the second leaf body, the rear end surface of the second leaf body is vertically and fixedly connected with a second mounting plate along the length direction of the second heat insulation strips, the bottom end of the front side surface of the second mounting plate is fixedly connected with a third buckling strip, the front end of the upper surface of the first leaf body is vertically and fixedly connected with a third mounting plate along the length direction of the first heat insulation strips, the top end of the rear side surface of the third mounting plate and the top end of the front side surface of the second mounting plate are fixedly connected with fourth buckling strips, the bottom end of the second leaf body is fixedly connected with a second heat insulation frame along the length direction of the second heat insulation frame, and the front end surface of the second heat insulation frame is fixedly connected with fifth buckling strips corresponding to the third buckling strips along the length direction of the second heat insulation frame.

Preferably, a first heat insulation cotton sliver is detachably arranged in the first frame body, the first heat insulation frame, the first fan body and the second heat insulation frame along the length direction of the first heat insulation cotton sliver.

Preferably, the inside of the first heat insulation cavity and the inside of the second heat insulation cavity are both detachably provided with a second heat insulation cotton sliver along the length direction of the first heat insulation cavity and the second heat insulation cavity.

Preferably, the inside of the second frame body and the inside of the second fan body are both detachably provided with a support steel lining along the length direction thereof.

Preferably, the inside of first buckle strip and the inside of third buckle strip all are provided with first adhesive tape along its length direction detachably, the inside of second buckle strip and the inside of fifth buckle strip all are provided with the second adhesive tape along its length direction detachably.

Preferably, the upper surfaces of the first sector and the second sector are detachably provided with heat-insulating glass between the two third buckling strips, and weather-resistant glue layers are arranged between the two third buckling strips and the front and back surfaces of the heat-insulating glass.

Preferably, a plurality of supporting cushion blocks are arranged between the bottom end of the heat-insulating glass and the upper surfaces of the first fan body and the second fan body.

Advantageous effects

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses a novel heat preservation door, through setting up first thermal-insulated frame and the thermal-insulated frame of second, this heat preservation door is when closing, the position of first buckle strip and the front end overlap joint of the first fan body, the position of third buckle strip and the rear end overlap joint of second framework, under the effect of first adhesive tape, carry out first heavy sealing to the connection position of the fan body and framework, first thermal-insulated frame and the thermal-insulated frame of second fill up the cavity position of the fan body with framework junction simultaneously, the second adhesive tape of first thermal-insulated frame rear end and the thermal-insulated frame front end of second contacts each other simultaneously, carry out second heavy sealing to the connection position of framework and fan body, the sealed effect between framework and the fan body has been improved, simultaneously under the effect of the first thermal-insulated silver of first thermal-insulated frame inside and the thermal-insulated frame of second, the heat preservation effect at the connection position of framework and the fan body has also obtained the guarantee, thereby the heat preservation effect of whole heat preservation door has been improved, the practicality of this door has been improved.

Drawings

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

FIG. 2 is a schematic view of the structure of the middle door leaf mechanism of the present invention;

fig. 3 is a schematic structural view of the middle door frame mechanism of the present invention.

In the figure: 1. a first frame body; 2. a second frame body; 3. a first heat insulating strip; 4. a first insulating cavity; 5. mounting a bar; 6. a first mounting plate; 7. a first snap-fastener strip; 8. a first heat insulating frame; 9. a second snap strip; 10. a first fan body; 11. a second fan body; 12. a second insulating strip; 13. a second insulating cavity; 14. a second mounting plate; 15. a third snap strip; 16. a fourth snap strip; 17. a third mounting plate; 18. a limiting strip; 19. a second heat insulating frame; 20. a fifth snap strip; 21. a first thermally insulating pledget; 22. a second thermally insulating pledget; 23. supporting a steel lining; 24. a first adhesive tape; 25. a second adhesive tape; 26. supporting the cushion block; 27. insulating glass; 28. weather-resistant glue layer.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

Referring to fig. 1-3, the present invention provides a technical solution: a novel heat preservation door comprises a door frame mechanism and a door leaf mechanism.

The door frame mechanism comprises a first frame body 1 and a second frame body 2, wherein two first heat insulation strips 3 are transversely and fixedly connected between the rear end of the first frame body 1 and the front end of the second frame body 2, a first heat insulation cavity 4 is formed between the two first heat insulation strips 3 and the rear end surface of the first frame body 1 and the front end surface of the second frame body 2, the bottom ends of the first frame body 1 and the second frame body 2 are fixedly connected with mounting strips 5 along the length direction of the bottom ends, the front end of the upper surface of the first frame body 1 is vertically and fixedly connected with a first mounting plate 6 along the length direction of the front end, the top end of the rear side surface of the first mounting plate 6 is fixedly connected with a first buckle strip 7, the upper surface of the first frame body 1 is fixedly connected with a first heat insulation frame 8, and the rear end of the first heat insulation frame 8 is fixedly connected with a second buckle strip 9 along the length direction of the rear end;

the door leaf mechanism comprises a first fan body 10 and a second fan body 11, wherein two second heat insulation strips 12 are transversely and fixedly connected between the rear end of the first fan body 10 and the front end of the second fan body 11, a second heat insulation cavity 13 is formed between the two second heat insulation strips 12 and the rear end surface of the first fan body 10 and the front end surface of the second fan body 11, a second mounting plate 14 is vertically and fixedly connected to the rear end surface of the second fan body 11 along the length direction of the second fan body, a third buckling strip 15 is fixedly connected to the bottom end of the front side surface of the second mounting plate 14, a third mounting plate 17 is vertically and fixedly connected to the front end of the upper surface of the first fan body 10 along the length direction of the first fan body, fourth buckling strips 16 are fixedly connected to the top end of the rear side surface of the third mounting plate 17 and the top end of the front side surface of the second mounting plate 14, a second heat insulation frame 19 is fixedly connected to the bottom end of the second fan body 11 along the length direction of the second fan body, and a fifth buckling strip 20 corresponding to the second buckling strips 9 is fixedly connected to the front end surface of the second heat insulation frame 19 along the length direction of the second heat insulation frame.

A first insulating tampon 21 is detachably disposed in the first frame 1, the first insulating frame 8, the first sector 10 and the second insulating frame 19 along the length direction thereof.

The interior of the first insulated chamber 4 and the interior of the second insulated chamber 13 are each provided with a second insulated pledget 22 removably along their length.

The inside of the first fastener strip 7 and the inside of the third fastener strip 15 are both detachably provided with a first adhesive tape 24 along the length direction thereof, and the inside of the second fastener strip 9 and the inside of the fifth fastener strip 20 are both detachably provided with a second adhesive tape 25 along the length direction thereof.

In this embodiment, the first frame 1 and the second frame 11 in the door frame mechanism are connected to each other through two first heat insulating strips 3, the first heat insulating strips 3 have a heat insulating effect, so as to achieve the purpose of heat preservation, and at the same time, the first frame 1 and the second frame 2 are both hollow, and a first heat insulating cotton strip 21 can be inserted into the first frame 1 and the second frame 2, so as to further improve the heat preserving effect of the door frame mechanism.

The door leaf mechanism is the same, the first leaf body 10 and the second leaf body 11 are both hollow structures, and a first heat insulation cotton sliver 21 can be inserted into the first leaf body and the second leaf body, so that the heat insulation effect of the first leaf body and the second leaf body is improved.

The first insulating strips 3 and the second insulating strips 12 are made of the same material, and are not described herein for the prior art.

When the heat preservation door is closed, the first buckle strip 7 in the door frame mechanism is lapped on the front end of the first leaf body 10 in the door frame mechanism, the third buckle strip 15 in the door frame mechanism is lapped on the rear end of the second frame body 2 in the door frame mechanism, under the action of the first adhesive tape 24, the joint of the door frame mechanism and the door frame mechanism is sealed in a first-time mode, meanwhile, the rear end of the first heat insulation frame 8 is in contact with the second adhesive tape 25 on the front end of the second heat insulation frame 19, the joint of the door frame mechanism and the door frame mechanism is sealed in a second-time mode, meanwhile, the first heat insulation frame 8 and the second heat insulation frame 19 fill the cavity between the door frame mechanism and the door frame mechanism, under the action of the first heat insulation cotton sliver 21 inside the first heat insulation frame 8 and the second heat insulation frame 19, the heat preservation effect of the joint of the door frame mechanism and the door leaf mechanism is guaranteed, and therefore the heat preservation effect of the whole heat preservation door is improved.

Further, the inside of the second frame body 2 and the inside of the second sector body 11 are both detachably provided with support steel linings 23 along the length direction thereof.

In the present embodiment, the support steel lining 23 provides a support effect, and improves the strength of the door mechanism and the door frame mechanism.

Further, the heat insulating glass 27 is detachably disposed on the upper surfaces of the first fan body 10 and the second fan body 11 and between the two fourth fastening strips 16, and weather-resistant glue layers 28 are disposed between the two fourth fastening strips 16 and the front and back surfaces of the heat insulating glass 27.

A plurality of supporting cushion blocks 26 are arranged between the bottom end of the heat-insulating glass 27 and the upper surfaces of the first fan body 10 and the second fan body 11, and the upper surfaces of the first fan body 10 and the second fan body 11 are vertically and fixedly connected with limiting strips 18 along the length direction.

In the present embodiment, the insulating glass 27 is a conventional one, and will not be described herein.

The weather-resistant glue layer 28 has the effect of connection, can be with insulating glass 27 fixed mounting in the inside of door leaf mechanism, and spacing strip 18 plays spacing effect, makes insulating glass 27 can not produce the deviation when the installation, and the lip block 26 plays the supporting effect, makes insulating glass 27 and door leaf mechanism's surface can not direct contact, prevents that rigid collision from causing the damage to insulating glass 27.

The utility model discloses a theory of operation and use flow: the utility model discloses install the back, closing this heat preservation door after, make the junction between door frame mechanism and the door leaf mechanism obtain dual sealedly through two first adhesive tapes 24 and two second adhesive tapes 25, the sealed effect of junction has been improved, simultaneously through the first thermal-insulated frame 8 and the thermal-insulated frame 19 of second with the junction between door frame mechanism and the door leaf mechanism fill up, under the first thermal-insulated silver 21 effect of thermal-insulated frame 19 inside of first thermal-insulated frame 8 and second, the heat preservation effect of the junction of door frame mechanism and door leaf mechanism has also obtained the guarantee, thereby the heat preservation effect of whole door has been improved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not intended to limit the present invention, and any modifications, equivalents, improvements, etc. made within the spirit and principles of the present invention should be included within the scope of the present invention.

Claims (7)

1. A novel heat preservation door which characterized in that: comprises a doorframe mechanism and a door leaf mechanism;

the door frame mechanism comprises a first frame body (1) and a second frame body (2), wherein two first heat insulation strips (3) are transversely and fixedly connected between the rear end of the first frame body (1) and the front end of the second frame body (2), a first heat insulation cavity (4) is formed between the two first heat insulation strips (3) and the rear end surface of the first frame body (1) and the front end surface of the second frame body (2), the bottom ends of the first frame body (1) and the second frame body (2) are fixedly connected with mounting strips (5) along the length direction of the first frame body, the front end of the upper surface of the first frame body (1) is vertically and fixedly connected with a first mounting plate (6) along the length direction of the first frame body, the top end of the rear side surface of the first mounting plate (6) is fixedly connected with a first buckling strip (7), the upper surface of the first frame body (1) is fixedly connected with a first heat insulation frame (8), and the rear end of the first heat insulation frame (8) is fixedly connected with a second buckling strip (9) along the length direction of the first heat insulation frame body;

the door leaf mechanism comprises a first fan body (10) and a second fan body (11), wherein two second heat insulation strips (12) are transversely and fixedly connected between the rear end of the first fan body (10) and the front end of the second fan body (11), a second heat insulation cavity (13) is formed between the two second heat insulation strips (12) and the rear end surface of the first fan body (10) and the front end surface of the second fan body (11), a second mounting plate (14) is vertically and fixedly connected to the rear end surface of the second fan body (11) along the length direction of the second heat insulation strips, a third buckle strip (15) is fixedly connected to the bottom end of the front side surface of the second mounting plate (14), a third mounting plate (17) is vertically and fixedly connected to the front end of the upper surface of the first fan body (10) along the length direction of the first fan body, fourth buckle strips (16) are fixedly connected to the top ends of the rear side surface of the third mounting plate (17) and the front side surface of the second mounting plate (14), a fifth buckle strip (20) is fixedly connected to the bottom end of the second fan body (11) along the length direction of the second heat insulation frame (19), and a fifth buckle strip (20) are correspondingly connected to the heat insulation frame.

2. A novel thermal insulating door as claimed in claim 1, wherein: the first heat insulation cotton sliver (21) is detachably arranged in the first frame body (1), the first heat insulation frame (8), the first fan body (10) and the second heat insulation frame (19) along the length direction of the first heat insulation cotton sliver.

3. A novel thermal insulating door as claimed in claim 1, wherein: and a second heat insulation cotton strip (22) is detachably arranged in the first heat insulation cavity (4) and the second heat insulation cavity (13) along the length direction of the first heat insulation cavity and the second heat insulation cavity.

4. A novel thermal insulating door as claimed in claim 1, wherein: and supporting steel liners (23) are detachably arranged in the second frame body (2) and the second fan body (11) along the length direction of the second frame body and the second fan body.

5. A novel thermal insulating door as claimed in claim 1, wherein: the inside of the first buckle strip (7) and the inside of the third buckle strip (15) are detachably provided with a first adhesive tape (24) along the length direction, and the inside of the second buckle strip (9) and the inside of the fifth buckle strip (20) are detachably provided with a second adhesive tape (25) along the length direction.

6. A novel thermal insulating door as claimed in claim 1, wherein: the upper surface of the first fan body (10) and the second fan body (11) is located two heat-insulating glass (27) is detachably arranged between the fourth buckling strips (16), and weather-resistant glue layers (28) are arranged between the fourth buckling strips (16) and the front surface and the rear surface of the heat-insulating glass (27).

7. The new heat preservation door of claim 6, characterized in that: a plurality of supporting cushion blocks (26) are arranged between the bottom end of the heat-insulating glass (27) and the upper surfaces of the first fan body (10) and the second fan body (11), and the upper surfaces of the first fan body (10) and the second fan body (11) are vertically and fixedly connected with limiting strips (18) along the length direction of the upper surfaces.

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