CN213175331U - Energy-saving sliding door and window - Google Patents

Abstract

The utility model relates to an energy-saving sliding door and window, which comprises a window body and a window sash; the window sash is slidably arranged in the window body, and the window body comprises an outer frame and an inner frame; the window sashes comprise a first window sash and a second window sash; the upper part of the outer frame and the lower part of the outer frame are respectively provided with an outer frame sliding rail; the upper part of the inner frame and the lower part of the inner frame are respectively provided with an inner frame slide rail; the first window sash is embedded with the outer frame slide rail; the second window sash is embedded with the inner frame slide rail; sealing elements are arranged between the outer frame and the outer frame slide rails and between the inner frame and the inner frame slide rails; the sealing element penetrates through the outer frame and the inner frame; the outer frame and the smooth rabbet are sealed through a first adhesive tape; the inner frame and the smooth rabbet are sealed through a second adhesive tape; the outer frame and the hooked rabbet are sealed by a first hooked rabbet rubber strip; the inner frame and the hooked rabbet are sealed through a second hooked rabbet rubber strip; and a wind stopping block is arranged between the outer frame slide rail and the inner frame slide rail. The utility model discloses the gas tightness is high, the heat-proof quality is good.

Description

Energy-saving sliding door and window

Technical Field

The utility model relates to a building door and window technical field, in particular to energy-conserving sliding door.

Background

At present, China provinces and cities carry through national construction energy-saving policies. The heat loss of the door and window accounts for more than 40% of the total heat loss of the building, the energy saving of the door and window is the key of the energy saving of the building, and the door and window is a sensitive part for losing energy, so that higher requirements for the energy saving of the door and window are provided.

The casement window has the advantage that the leakproofness is good, but the partial space that will occupy indoor of inwardly opened window influences the (window) curtain and uses the screen window also inconvenient, and the outwardly opened window is opened and is will occupy a space outside the wall, easily impairs or even drops when blowing strong wind, has the potential safety hazard. The sliding window is convenient to open, does not occupy indoor space and the like, is more in line with living habits of southern people and is widely adopted by people.

However, sliding windows on the market generally have the phenomena of low air tightness and poor heat insulation performance. The reason that the existing sliding window is poor in energy-saving effect is as follows: 1. the reason for the material; the selected glass has poor energy-saving effect; 2. the energy-saving effect of the selected heat insulation strips cannot be met; 3. the structure is characterized in that the heat insulation lines of the window frame and the fan material are not in the same position, and the frame cold bridge always exists and cannot be considered, so that the energy-saving effect is greatly lower than that of a casement window in the same level; 4. the heat insulation performance of the hooked rabbet part of the sliding window is poor; 5. the top wool is selected as a sealing element, the sealing performance of the top wool is poor due to the self reason, the sealing effect is far better than that of an adhesive tape even if the top wool is siliconized and laminated, and the ethylene propylene diene monomer adhesive tape is soft in texture and easy to expand with heat and contract with cold.

In addition, in the past building engineering, in order to make the service life of the door and window match with that of the building, the door and window sash of the building are made of metal materials, but the door and window materials made of metal materials have the greatest defects of high heat transfer speed, energy conservation and temperature preservation of the metal materials. The existing energy-saving treatment method in the industry adopts a heat insulation metal material, and heat transfer of the heat insulation material is carried out through a heat insulation strip in the middle. The size of the middle heat insulation strip needs to be increased when good material heat insulation performance is needed, but the heat insulation strip material is composed of PA66 and glass fiber, the strength of the heat insulation strip material is limited, the integral mechanical performance of the metal material cannot reach the use effect of the door and window on a high layer when the size of the heat insulation strip material is too large, the heat insulation strip is in conflict with the hardware position for installing the door and window after the heat insulation strip is large, the heat insulation strip material is not firm, and the engineering cost is relatively high if special reinforcing materials are used.

In summary, there is a need for a sliding window with high air tightness and excellent heat insulation performance for market selection.

SUMMERY OF THE UTILITY MODEL

The utility model discloses an energy-conserving sliding door to the not enough of prior art.

The utility model discloses the technical scheme who adopts as follows:

an energy-saving sliding door and window comprises a window body and a window sash; the window sash is slidably arranged in the window body, and the window body comprises an outer frame and an inner frame; the window sashes comprise a first window sash and a second window sash; the upper part of the outer frame and the lower part of the outer frame are respectively provided with an outer frame sliding rail; the upper part of the inner frame and the lower part of the inner frame are respectively provided with an inner frame slide rail; the first window sash is embedded with the outer frame slide rail; the second window sash is embedded with the inner frame slide rail; sealing elements are arranged between the outer frame and the outer frame slide rails and between the inner frame and the inner frame slide rails; the sealing element penetrates through the outer frame and the inner frame; the outer frame and the smooth rabbet are sealed through a first adhesive tape; the inner frame and the smooth rabbet are sealed through a second adhesive tape; the outer frame and the hooked rabbet are sealed through a first hooked rabbet rubber strip; the inner frame and the hooked rabbet are sealed through a second hooked rabbet rubber strip; and a wind stopping block is arranged between the outer frame slide rail and the inner frame slide rail.

The method is further characterized in that: the outer frame sliding rail is provided with a first upper rail heat insulation strip and a first sash heat insulation strip; the inner frame sliding rail is provided with a second upper rail heat insulation strip and a second sash heat insulation strip; the first sash heat insulation strip and the second sash heat insulation strip are communicated.

The method is further characterized in that: a gap is formed between the first sash heat insulation strip and the second sash heat insulation strip; and injecting glue into the gap for filling.

The method is further characterized in that: the first window sash and the second window sash are provided with notches for mounting glass; a first leather strip is pressed into the notch of the first window sash for sealing; a second leather strip is pressed into the notch of the second sash for sealing;

the method is further characterized in that: and the first window sash and the second window sash are respectively provided with hollow glass.

The method is further characterized in that: the outer frame and the inner frame are respectively provided with an inner groove; wool tops are embedded in the inner grooves.

The utility model has the advantages as follows:

1. the utility model saves energy and raw materials, is favorable for environmental protection, reduces labor intensity and shortens the growth period.

2. The utility model provides high door and window's energy-conserving thermal insulation performance and air tightness performance promote the energy-conserving performance of whole building through the energy-conserving thermal insulation performance and the air tightness performance that improve door and window, have better heat-proof quality, prevent wind waterproof nature and leakproofness.

3. The utility model discloses under the condition of no longer single increase heat insulating strip size, through the heat insulating line of guaranteeing the window frame and casement in same position, it is obvious to effects such as energy-conservation, environmental protection, noise reduction of building.

Drawings

Fig. 1 is a front view of the present invention.

Fig. 2 is a cross-sectional view taken at a in fig. 1.

Fig. 3 is a cross-sectional view at B in fig. 1.

Fig. 4 is a cross-sectional view at C in fig. 1.

Fig. 5 is a cross-sectional view taken at D in fig. 1.

Fig. 6 is a cross-sectional view at E in fig. 1.

In the figure: 1. an outer frame; 2. a first sash; 3. an outer frame slide rail; 4. an inner frame; 5. an inner frame slide rail; 6. a second sash; 7. a seal member; 8. a smooth rabbet; 9. a first adhesive tape; 10. a second adhesive tape; 11. a hooked rabbet; 12. a first hooked rabbet rubber strip; 13. a second hooked rabbet rubber strip; 14. a first leather strip; 15. a second leather strip; 16. a wind stopping block; 17. a first upper rail heat insulation strip; 18. a first sash insulating strip; 19. a second upper rail heat insulation strip; 20. a second sash insulating strip; 21. and (5) wool tops.

Detailed Description

The foregoing and other features, aspects and utilities of the present invention will be apparent from the following detailed description of the embodiments, which is to be read in connection with the accompanying drawings. Directional terms as referred to in the following examples, for example: up, down, left, right, front or rear, etc., are simply directions with reference to the drawings. Therefore, the directional terminology used is for the purpose of description and is not intended to be limiting, and moreover, like reference numerals will be used to refer to like elements throughout.

The following describes a specific embodiment of the present embodiment with reference to the drawings.

Fig. 1 is a front view of the present invention, fig. 2 is a sectional view taken at a point a in fig. 1, fig. 3 is a sectional view taken at a point B in fig. 1, fig. 4 is a sectional view taken at a point C in fig. 1, fig. 5 is a sectional view taken at a point D in fig. 1, and fig. 6 is a sectional view taken at a point E in fig. 1. With reference to fig. 1 to 6, an energy-saving sliding door/window includes a window body and a window sash. The window sash is slidably arranged in the window body, and the window body comprises an outer frame 1 and an inner frame 4. Both the outer frame 1 and the inner frame 4 are made of profiles. The sash comprises a first sash 2 and a second sash 6. The upper part of the outer frame 1 and the lower part of the outer frame 1 are respectively provided with an outer frame slide rail 3. The upper part of the inner frame 4 and the lower part of the inner frame 4 are respectively provided with an inner frame slide rail 5. The first sash 2 is embedded with the outer frame slide rail 3. The second sash 6 is embedded with the inner frame slide rail 5.

Sealing elements 7 are arranged between the outer frame 1 and the outer frame slide rails 3 and between the inner frame 4 and the inner frame slide rails 5. The sealing member 7 penetrates the outer frame 1 and the inner frame 4. Preferably, the sealing element 7 is a soft and hard co-extrusion adhesive tape which has good elasticity and small flexibility, and the sealing performance of the energy-saving sliding door and window is improved. The sealing strip 7 is provided with a rubber strip capable of increasing air tightness, so that the indoor and outdoor air is prevented from passing through, and the air tightness is increased.

The outer frame 1 and the smooth rabbet 8 are sealed by a first adhesive tape 9. The inner frame 4 and the smooth rabbet 8 are sealed through a second adhesive tape 10. The first rubber strip 9 and the second rubber strip 10 improve the air tightness and the water tightness of the energy-saving sliding door and window. The outer frame 1 and the hooked rabbet 11 are sealed by a first hooked rabbet rubber strip 12. The inner frame 4 and the hooked rabbet 11 are sealed through a second hooked rabbet rubber strip 13. The first window sash 2 and the second window sash 6 are both provided with notches for mounting glass. The notch of the first sash 2 is sealed by pressing a first leather strip 14. The notch of the second sash 6 is sealed by pressing a second skin strip 15. And a wind stopping block 16 is arranged between the outer frame slide rail 3 and the inner frame slide rail 5. The air stop block 16 further improves the air tightness of the energy-saving sliding door and window.

The outer frame sliding rail 3 is provided with a first upper rail heat insulating strip 17 and a first sash heat insulating strip 18. The inner frame slide rail 5 is provided with a second upper rail insulating strip 19 and a second sash insulating strip 20. The first sash insulating strip 18 and the second sash insulating strip 20 are penetrated.

A gap is provided between the first sash insulating strip 18 and the second sash insulating strip 20. And injecting glue into the gap for filling. The glue injection filling plays a role in further heat insulation.

The first sash 2 and the second sash 6 are respectively provided with hollow glass. Specifically, the size of the notch of the first sash 2 and the size of the notch of the second sash 6 are 35mm, hollow glass can be installed, and the heat transfer coefficient Ug of the hollow glass is only 1.98W/(m)²K). The hollow glass is high-efficiency sound and heat insulating glass which is prepared by bonding two (or three) pieces of glass with a first sash 2 or a second sash 6 containing a drying agent by using a high-strength high-airtightness composite bonding agent.

The outer frame 1 and the inner frame 4 are respectively provided with an inner groove. Wool tops 21 are embedded in the inner groove. The wool tops 21 can be further fixed and sealed, and play a role in wind-proof and rain-proof sealing, fireproof and smoke-proof sealing, dustproof sealing, collision prevention and sound insulation sealing.

The utility model discloses an installation principle as follows:

the utility model discloses the cooperation attaches the use of working of plastics such as shelves and all seals up each corner of window form, forms a complete sealed system, and the austral window, sliding sash that sealed effect current relatively has matter promotes.

The utility model discloses be applicable to the push-and-pull door equally, select and adjust according to the design requirement by the technical personnel in the field.

In the description of the embodiments of the present invention, it should be further noted that unless explicitly stated or limited otherwise, the terms "disposed" and "connected" should be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The above description is for the purpose of explanation and not limitation of the invention, which is defined in the claims, and any modifications may be made without departing from the basic structure of the invention.

Claims (6)

1. An energy-saving sliding door and window comprises a window body and a window sash; the window sash is slidably arranged in the window body, and the window body comprises an outer frame (1) and an inner frame (4); the window sashes comprise a first window sash (2) and a second window sash (6); the upper part of the outer frame (1) and the lower part of the outer frame (1) are respectively provided with an outer frame sliding rail (3); the upper part of the inner frame (4) and the lower part of the inner frame (4) are respectively provided with an inner frame slide rail (5); the first window sash (2) is embedded with the outer frame sliding rail (3); the second window sash (6) is embedded with the inner frame sliding rail (5); the method is characterized in that: sealing elements (7) are arranged between the outer frame (1) and the outer frame slide rails (3) and between the inner frame (4) and the inner frame slide rails (5); the sealing element (7) penetrates through the outer frame (1) and the inner frame (4); the outer frame (1) and the smooth rabbet (8) are sealed through a first adhesive tape (9); the inner frame (4) and the smooth rabbet (8) are sealed through a second adhesive tape (10); the outer frame (1) and the hooked rabbet (11) are sealed through a first hooked rabbet rubber strip (12); the inner frame (4) and the hooked rabbet (11) are sealed through a second hooked rabbet rubber strip (13); and a wind stopping block (16) is arranged between the outer frame slide rail (3) and the inner frame slide rail (5).

2. The energy saving sliding door or window according to claim 1 wherein: the outer frame sliding rail (3) is provided with a first upper rail heat insulation strip (17) and a first sash heat insulation strip (18); the inner frame sliding rail (5) is provided with a second upper rail heat insulation strip (19) and a second sash heat insulation strip (20); the first sash heat insulating strip (18) and the second sash heat insulating strip (20) are communicated.

3. The energy saving sliding door or window according to claim 2, wherein: a gap is arranged between the first sash heat insulation strip (18) and the second sash heat insulation strip (20); and injecting glue into the gap for filling.

4. The energy saving sliding door or window according to claim 1 wherein: the first window sash (2) and the second window sash (6) are provided with notches for mounting glass; the notch of the first window sash (2) is pressed into a first leather strip (14) for sealing; and a notch of the second window sash (6) is pressed into a second leather strip (15) for sealing.

5. The energy saving sliding door or window according to claim 1 wherein: the first sash (2) and the second sash (6) are respectively provided with hollow glass.

6. The energy saving sliding door or window according to claim 1 wherein: the outer frame (1) and the inner frame (4) are respectively provided with inner grooves, and wool tops (21) are embedded in the inner grooves.

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