CN214145180U - High-cost-performance high-energy-saving aluminum alloy door and window - Google Patents

Abstract

The utility model relates to an aluminum alloy door and window of high price/performance ratio high energy-conservation, include window frame, well club, open window frame, glass, hardware, the window frame include L type bridge cut-off aluminum alloy ex-trusions, open window frame ex-trusions include Z type bridge cut-off aluminum alloy ex-trusions, well club ex-trusions include club bridge cut-off aluminum alloy ex-trusions in the T type, the utility model discloses adopt the mode that notch design and interference fit combined together to cut apart heat insulating strip middle part cavity in the middle of energy-conserving aluminum door and window heat insulating strip, use the PVC material to cut apart into the closed little cavity of several with the cavity, can make whole window reach energy-conserving coefficient 1.9[ W/(m) through software calculation².k)]The effect requirement of (1). The utility model adopts the skillful operationThe design of (2) satisfies energy-conserving and intensity's requirement, and the cost-push is little when having realized the performance improvement of door and window product, does benefit to the effect of marketing.

Description

High-cost-performance high-energy-saving aluminum alloy door and window

Technical Field

The utility model relates to a building trade technical field, concretely relates to energy-conserving al-alloy door & window of high cost performance ratio.

Background

With the continuous improvement of the building energy-saving requirement, the requirement of the door and window industry is the water rising ship height. The existing plastic doors and windows and aluminum alloy doors and windows in the market can meet the energy-saving requirement, but the cost performance difference is large. Aluminum alloy doors and windows utilize the continuous increase of heat insulating strips to meet the energy-saving requirement, and plastic steel doors and windows continuously increase the section size and the number of closed chambers to meet the market requirement, but the cost increase is obvious. The cost of the plastic steel window is increased by about 8% -20%, and the cost of the aluminum alloy window is increased by more than 12%.

SUMMERY OF THE UTILITY MODEL

The utility model discloses provide an aluminum alloy door and window of high performance-price ratio high energy-conservation to this problem, can satisfy the requirement of energy-conservation and intensity, can not increase a lot of economic cost again, very necessary.

The technical solution of the utility model is that: the utility model provides an aluminum alloy door and window of high-performance price ratio high energy-saving, includes window frame, well club, opens window frame, glass, hardware, four window frames about the door and window outer frame is including from top to bottom, window frame section bar includes L type bridge cut-off aluminum alloy ex-trusions, and two window frames about the club is connected to horizontal being equipped with one on the upper side in the middle of the outer frame is inside, and the bottom window frame is connected to vertical being equipped with one well club in the middle of horizontal well club, well club section bar includes T type bridge cut-off aluminum alloy ex-trusions, from this door and window is divided into the triplex, goes up fixed window, and the window is opened on the right side, opens the window on a left side, installs glass in the window respectively, open the window and form by four upper and lower left and right sides opening window frame connections, open the window frame section bar and include Z type bridge cut-off aluminum alloy ex-situ, open the window and pass through the hardware with the window frame and be connected.

The L-shaped bridge-cut-off aluminum alloy profile comprises an aluminum alloy profile A, an aluminum alloy profile B, heat insulation strips C and a latticed plastic-steel profile, wherein one side of the aluminum alloy profile A is provided with a bayonet E3, a bayonet F1 and a bayonet E1 from top to bottom, the aluminum alloy profile B is provided with a bayonet E4, a bayonet F2 and a bayonet E2 from top to bottom at corresponding positions, the heat insulation strips C are arranged between the bayonet E3 and the bayonet E4, the heat insulation strips C are arranged between the bayonet E1 and the bayonet E2, the aluminum alloy profile A, the aluminum alloy profile B and the two heat insulation strips C form a closed space, and the latticed plastic-steel profile is arranged in the space through the bayonet F1 and the bayonet F2.

The Z-shaped bridge-cut-off aluminum alloy profile comprises an aluminum alloy profile A1, an aluminum alloy profile B1, a heat insulation strip C1 and a latticed plastic steel profile, wherein one side of the aluminum alloy profile A1 is provided with a bayonet E3, a bayonet F1 and a bayonet E1 from top to bottom, the aluminum alloy profile B1 is provided with a bayonet E4, a bayonet F2 and a bayonet E2 from top to bottom at corresponding positions, the heat insulation strip C is arranged between the bayonet E3 and the bayonet E4, the heat insulation strip C1 is arranged between the bayonet E1 and the bayonet E2, the aluminum alloy profile A1, the aluminum alloy profile B1, the heat insulation strip C and the heat insulation strip C1 form a closed space, and the latticed plastic steel profile is arranged in the plastic steel space through the bayonet F1 and the bayonet F2.

The T-shaped mullion broken bridge aluminum alloy profile comprises an aluminum alloy profile A2, an aluminum alloy profile B2, a heat insulation strip C and a latticed plastic steel profile, wherein one side of the aluminum alloy profile A2 is provided with a bayonet E3, a bayonet F1 and a bayonet E1 from top to bottom, the aluminum alloy profile B2 is provided with a bayonet E4, a bayonet F2 and a bayonet E2 from top to bottom at corresponding positions, the heat insulation strip C is arranged between the bayonet E3 and the bayonet E4, the heat insulation strip C is arranged between the bayonet E1 and the bayonet E2, the aluminum alloy profile A2, the aluminum alloy profile B2 and the two heat insulation strips C form a closed space, and the latticed plastic steel profile is arranged in the space through the bayonet F1 and the bayonet F2.

Deviation under the heat insulation strips C is not more than 0.05 +/-0.01 mm.

Deviation under the heat insulation strips C1 is not more than 0.05 +/-0.01 mm.

The deviation on the latticed plastic steel section is not more than 0.05 +/-0.01 mm.

The utility model discloses adopt the mode that notch design and interference fit combined together to cut apart thermal-insulated strip middle part cavity in the middle of energy-conserving aluminium door and window thermal-insulated strip, use the PVC material to cut apart into the closed little cavity of several with the cavity, calculate through software and can make whole window reach energy-conserving coefficient 1.9[ W/(m) m².k)]The effect requirement of (1). The beneficial effects of the utility model are that do not change current processing equipment, adopt ingenious design, solved the heat insulating strip specification of constantly increasing and the door and window cost-push that leads to, satisfy the requirement of energy-conservation and intensity, can not increase a lot of economy againThe cost is increased slightly while the performance of the door and window product is improved, and the door and window product is beneficial to market popularization.

Drawings

FIG. 1 is a schematic view of the structure of the present invention

FIG. 2 is a sectional view taken along line A-A of FIG. 1

FIG. 3 is a sectional view taken along line B-B of FIG. 1

FIG. 4 is a partial enlarged view of the L-shaped bridge-cut aluminum alloy section of the present invention

FIG. 5 is a partial enlarged view of the Z-shaped bridge-cut aluminum alloy section of the present invention

Fig. 6 is a partial enlarged view of the T-shaped mullion bridge-cut-off aluminum alloy profile of the present invention.

Detailed Description

In order to make the utility model realize technical means, creation characteristics, reach purpose and efficiency and easily understand, combine specific figure below, further explain the utility model.

The following description "upper, lower, left and right" parts are expressed by using a picture as an object, where the upper part is an upper part displayed by the picture, and the lower part is a lower part displayed by the picture, where the left part is a left part displayed by the picture and the right part is a right part displayed by the picture, and are used for description only.

Referring to fig. 1, an aluminum alloy door and window with high cost performance and energy saving performance comprises window frames 1, mullions 2, opening window frames 3, glass 22 and hardware 23, wherein the door and window outer frame comprises an upper window frame, a lower window frame, a left window frame, a right window frame, a left window frame, a bottom window frame, a right mullion, a T-shaped mullion bridge-cut aluminum alloy section 21, a mullion 2, three parts of the door and window, an upper fixed window, a right fixed window, a left opening window, glass 22 respectively installed in the window, the opening window is formed by connecting the upper opening window frame, the right opening window frame and the left opening window frame 3, the opening window frame 3 section comprises a Z-shaped bridge-shaped aluminum alloy section 20, the opening window is connected with the window frame 1 through hardware 23.

As shown in fig. 4, the L-shaped bridge-cut aluminum alloy profile 19 includes an aluminum alloy profile A4, an aluminum alloy profile B5, a heat insulation strip C16, and a grid-shaped plastic-steel profile 17, wherein a bayonet E312, a bayonet F114, and a bayonet E110 are disposed on one side of the aluminum alloy profile A4 from top to bottom, a bayonet E413, a bayonet F215, and a bayonet E211 are disposed on the aluminum alloy profile B5 from top to bottom at corresponding positions, the heat insulation strip C16 is disposed between the bayonet E312 and the bayonet E413, the heat insulation strip C16 is disposed between the bayonet E110 and the bayonet E211, the aluminum alloy profile A4, the aluminum alloy profile B5, and the two heat insulation strips C16 form a closed space, and the grid-shaped plastic-steel profile 17 is disposed in the closed space through the bayonet F114 and the bayonet F215. When the method is implemented, the molded latticed plastic-steel section 17 is firstly inserted into the bayonets F114 and F215 at the middle positions of the aluminum alloy section A4 and the aluminum alloy section B5, and can linearly slide without being fastened. And then, a mature heat insulation strip C16 penetrating process is used, an upper heat insulation strip C16 and a lower heat insulation strip C16 penetrate into the corresponding bayonets E110, E211, E312 and E413, the heat insulation heads of the bayonets E110, E211, E312 and E413 are pressed by rollers through a composite process, the aluminum profile at the part generates local deformation, the penetrated heat insulation strips C16 are pressed, and meanwhile, the latticed plastic steel profile 17, the aluminum alloy profile A4 and the aluminum alloy profile B5 are also pressed, so that the combination of the profiles is realized.

As shown in fig. 5, the Z-shaped bridge-cut-off aluminum alloy profile 20 includes an aluminum alloy profile a16, an aluminum alloy profile B17, a heat insulation strip C16, a heat insulation strip C118, and a grid-shaped plastic steel profile 17, wherein one side of the aluminum alloy profile a16 is provided with a bayonet E312, a bayonet F114, and a bayonet E110 from top to bottom, the aluminum alloy profile B17 is provided with a bayonet E413, a bayonet F215, and a bayonet E211 from top to bottom at corresponding positions, the heat insulation strip C16 is arranged between the bayonet E312 and the bayonet E413, the heat insulation strip C18 is arranged between the bayonet E110 and the bayonet E211, the aluminum alloy profile a 14, the aluminum alloy profile B15, the heat insulation strip C16, and the heat insulation strip C118 form a closed space, and the grid-shaped plastic steel profile 17 is arranged. In the implementation, the molded latticed plastic-steel profile 17 is firstly inserted into the bayonets F114 and F215 at the middle positions of the aluminum alloy profile A16 and the aluminum alloy profile B17, and can linearly slide without being fastened. And then, a mature heat insulation strip C16 and a mature heat insulation strip C118 penetrating process is used, the heat insulation strip C16 and the heat insulation strip C118 penetrate into corresponding bayonets E110, E211, E312 and E413, pressure is applied to heat insulation heads of the bayonets E110, E211, E312 and E413 through a roller in a compounding process, aluminum profiles at the part are locally deformed, the penetrated heat insulation strip C16 and the heat insulation strip C118 are compressed, and meanwhile, the latticed plastic steel profiles 17, the aluminum alloy profiles A16 and the aluminum alloy profiles B17 are also combined to realize the combination of the profiles.

As shown in fig. 6, the T-shaped muntin bridge-cut-off aluminum alloy section 21 includes an aluminum alloy section a 28, an aluminum alloy section B29, a heat insulation strip C16, and a grid-shaped plastic-steel section 17, wherein one side of the aluminum alloy section a 28 is provided with a bayonet E312, a bayonet F114, and a bayonet E110 from top to bottom, the aluminum alloy section B29 is provided with a bayonet E413, a bayonet F215, and a bayonet E211 at corresponding positions from top to bottom, the heat insulation strip C16 is provided between the bayonet E312 and the bayonet E413, the heat insulation strip C16 is provided between the bayonet E110 and the bayonet E211, the aluminum alloy section a 28, the aluminum alloy section B29, and the two heat insulation strips C16 form a closed space, and the grid-shaped plastic-steel section 17 is disposed in the space through. In the implementation, the molded latticed plastic-steel profile 17 is firstly inserted into the bayonets F114 and F215 at the middle positions of the aluminum alloy profile A28 and the aluminum alloy profile B29, and can linearly slide without being fastened. And then, a mature heat insulation strip C16 penetrating process is used, an upper heat insulation strip C16 and a lower heat insulation strip C16 penetrate into the corresponding bayonets E110, E211, E312 and E413, the heat insulation heads of the bayonets E110, E211, E312 and E413 are pressed by rollers through a compounding process, the aluminum profile at the part generates local deformation, the penetrated heat insulation strips C16 are pressed, and meanwhile, the latticed plastic steel profile 17, the aluminum alloy profile A28 and the aluminum alloy profile B29 are pressed, so that the combination of the profiles is realized.

When a purchasing standard is established, the lengths of the heat insulation bars C16 and C118 are purchased according to the lower deviation of 0.05 mm, the length of the latticed plastic-steel section bar 17 is purchased according to the upper deviation of 0.05 mm, and after the latticed plastic-steel section bar 17 is matched with the upper deviation of 0.05 mm, the latticed plastic-steel section bar has interference fit of about 0.1 mm, and the interference fit can ensure the firm connection of the latticed plastic-steel section bar 17 and the aluminum alloy section bar A4 \ aluminum alloy section bar B5, the aluminum alloy section bar A16\ aluminum alloy section bar B17 and the aluminum alloy section bar A28 \ aluminum alloy section bar B29.

The utility model discloses creatively utilize bayonet socket F114 and bayonet socket F215 and roll-in technology to fix latticed plastic steel section bar 17 to the cavity in, cut apart into a plurality of little closed cavitys with the big cavity of heat insulating strip C16, heat insulating strip C118 middle part, play energy-conserving heat retaining effect. The plastic steel section is one third of the cost of the nylon heat insulation strip material, the heat insulation effect is slightly better than that of the nylon material, the cost of the finished window is influenced by about 1% by adopting the latticed plastic steel section 17 for the finished window with the same heat insulation coefficient, and the cost is improved by about 10% by adopting the nylon heat insulation strip for the finished window. On the premise of meeting the national building energy-saving requirement, the bridge-cut-off aluminum alloy window adopting the latticed plastic-steel section 17 is more favorable for the requirements of common people and is more suitable for large-area popularization.

The basic principles and the main features of the present invention and the advantages of the present invention have been described above. It should be understood by those skilled in the art that the present invention is not limited to the above embodiments, and the description of the above embodiments and the description is only for illustrating the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the present invention, and these changes and modifications fall within the scope of the present invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (7)

1. The utility model provides an aluminum alloy door and window of high performance-price ratio high energy-saving, includes outer frame of door and window, window frame (1), well club (2), opens window frame (3), glass (22), hardware (23), its characterized in that: four window frames (1) about the door and window outer frame is including from top to bottom, window frame (1) section bar includes L type bridge cut-off aluminium alloy (19), and two window frames (1) about connecting are transversely equipped with one in the middle of the outer frame inside on the upper side to club (2), and bottom window frame (1) is connected in the middle of horizontal well club (2) vertical being equipped with one in club (2), well club (2) section bar includes club bridge cut-off aluminium alloy (21) in the T type, from this door and window is divided into the triplex, including last fixed window, the fixed window in the right side, open the window on a left side, install glass (22) respectively in the window, open the window and open window frame (3) by four about from top to bottom and connect and form, open window frame (3) section bar and include Z type bridge cut-off aluminium alloy (20), open the window and pass through hardware (23) with window frame (1) and be connected.

2. The al-alloy door & window of claim 1, wherein: the L-shaped bridge cut-off aluminum alloy section (19) comprises an aluminum alloy section A (4), an aluminum alloy section B (5), a heat insulation strip C (16) and a latticed plastic steel section (17), one side of the aluminum alloy section A (4) is provided with a bayonet E3(12), a bayonet F1(14) and a bayonet E1(10) from top to bottom, the aluminum alloy section B (5) is provided with a bayonet E4(13), a bayonet F2(15) and a bayonet E2(11) from top to bottom at corresponding positions, a heat insulation strip C (16) is arranged between the bayonet E3(12) and the bayonet E4(13), and a heat insulation strip C (16) is arranged between the bayonet E1(10) and the bayonet E2(11), the aluminum alloy section A (4), the aluminum alloy section B (5) and the two heat insulation strips C (16) form a closed space, and the grid-shaped plastic-steel section (17) is arranged in the space through the bayonet F1(14) and the bayonet F2 (15).

3. The al-alloy door & window of claim 1, wherein: the Z-shaped bridge-cut-off aluminum alloy section (20) comprises an aluminum alloy section A1(6), an aluminum alloy section B1(7), a heat insulation strip C (16), a heat insulation strip C1(18) and a latticed plastic-steel section (17), one side of the aluminum alloy section A1(6) is provided with a bayonet E3(12), a bayonet F1(14) and a bayonet E1(10) from top to bottom, the aluminum alloy section B1(7) is provided with a bayonet E4(13), a bayonet F2(15) and a bayonet E2(11) from top to bottom at corresponding positions, a heat insulation strip C (16) is arranged between the bayonet E3(12) and the bayonet E4(13), a heat insulation strip C1(18) is arranged between the bayonet E1(10) and the bayonet E2(11), an aluminum alloy section A1(6), an aluminum alloy section B1(7), a heat insulation strip C (16) and a heat insulation strip C1(18) form a closed space, and the grid-shaped plastic steel section (17) is arranged in the closed space through the bayonet F1(14) and the bayonet F2 (15).

4. The al-alloy door & window of claim 1, wherein: the T-shaped mullion bridge-cut-off aluminum alloy section (21) comprises an aluminum alloy section A2(8), an aluminum alloy section B2(9), a heat insulation strip C (16) and a latticed plastic steel section (17), one side of the aluminum alloy section A2(8) is provided with a bayonet E3(12), a bayonet F1(14) and a bayonet E1(10) from top to bottom, the aluminum alloy section B2(9) is provided with a bayonet E4(13), a bayonet F2(15) and a bayonet E2(11) from top to bottom at corresponding positions, a heat insulation strip C (16) is arranged between the bayonet E3(12) and the bayonet E4(13), a heat insulation strip C (16) is arranged between the bayonet E1(10) and the bayonet E2(11), an aluminum alloy section A2(8), an aluminum alloy section B2(9) and two heat insulation strips C (16) form a closed space, and a grid-shaped plastic steel section (17) is arranged in the space through a bayonet F1(14) and a bayonet F2 (15).

5. A cost effective energy efficient aluminum alloy door and window according to claim 2 or 3 or 4 wherein: the deviation under the heat insulation strip C (16) is not more than 0.05 +/-0.01 mm.

6. The aluminum alloy door and window with high cost performance and energy saving performance of claim 3, wherein: the deviation under the heat insulation strips C1(18) is not more than 0.05 +/-0.01 mm.

7. A cost effective energy efficient aluminum alloy door and window according to claim 2 or 3 or 4 wherein: the deviation of the latticed plastic steel section (17) is not more than 0.05 +/-0.01 mm.

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