CN117108169A - Ultralow energy consumption window suitable for prefabricated integrated concrete wallboard in cold area - Google Patents

Abstract

The application discloses an ultralow energy consumption window suitable for prefabricating an integrated concrete wallboard in a cold area, belongs to the field of assembled buildings, and is used for assembled buildings, and further comprises a leveling and anchoring two-in-one assembly which is integrally cast with the prefabricated wallboard, wherein the leveling and anchoring two-in-one assembly is connected with an FRN glass fiber reinforced nylon corner bracket, the FRN glass fiber reinforced nylon corner bracket is connected with a frame of the glass bridge cut-off aluminum alloy window through a bolt structure, a polyurethane foam gasket is arranged at the connecting position of the FRN glass fiber reinforced nylon corner bracket and the glass bridge cut-off aluminum alloy window, a composite waterproof and vapor-barrier membrane with an anchor bolt is further arranged on the prefabricated wallboard at the inner side of the glass bridge cut-off aluminum alloy window, and the composite waterproof and vapor-barrier membrane with the anchor bolt is a Kong Nilong plate which is cast in the prefabricated wallboard through an anchor bolt and is compounded with a waterproof vapor-barrier membrane.

Description

Ultralow energy consumption window suitable for prefabricated integrated concrete wallboard in cold area

Technical Field

The application belongs to the field of assembled buildings, and particularly relates to an ultralow energy consumption window suitable for prefabricated integrated concrete wallboards in cold areas.

Background

China is one of countries with large world building body, and is continuously innovated in the field of building construction, and assembled buildings and ultra-low energy consumption buildings are gradually raised, so that the markets of assembled prefabricated wallboards and ultra-low energy consumption windows are expanded. For the current construction flow of the assembled concrete wallboard, the wallboard needs to be installed firstly, and the window is installed after the wallboard is hoisted up and installed, but the construction flow faces higher construction requirements in cold areas and mainly comprises the following aspects:

1. the passive building in the cold area has higher requirements on the heat insulation performance of the window, has higher construction requirements during on-site installation, has more and more complicated window installation nodes, and is easy to form a cold bridge once the window is not processed in place, thereby seriously affecting the performance of the window.

2. The passive window used by the passive building in the cold area has heavier weight, and the installation process is more complicated compared with the traditional window, so that the construction cost of the construction site is higher.

3. Because the passive window needs to be transported to a construction site through a transport vehicle after factory processing is finished, and needs to be discharged, stored, hoisted (by adopting construction equipment such as a tower crane or an aerial ladder) to an upstairs construction position and the like, the construction process needs a plurality of mechanical equipment (vehicles) to participate, so that more potential safety hazards (risk sources) exist on the construction site.

4. The prior inner window mould of the precast concrete wallboard is generally made of steel, the manufacturing cost is high, the inner window mould needs to be coated with a special release agent, and the release agent causes a certain harm to the surrounding environment of a construction site and the physical health of constructors.

Disclosure of Invention

The application aims to provide an ultralow energy consumption window suitable for prefabricating integrated concrete wallboards in cold areas, which can solve the problems in the prior art.

In order to achieve the above purpose, the application is realized by the following technical scheme:

the application discloses an ultralow energy consumption window suitable for a prefabricated integrated concrete wallboard in a cold area, which comprises a glass broken bridge aluminum alloy window, and further comprises a leveling and anchoring two-in-one assembly which is integrally cast with the prefabricated wallboard, wherein the leveling and anchoring two-in-one assembly is connected with an FRN glass fiber reinforced nylon corner bracket, the FRN glass fiber reinforced nylon corner bracket is connected with a frame of the glass broken bridge aluminum alloy window through a bolt structure, a polyurethane foaming gasket is arranged at the connecting position of the FRN glass fiber reinforced nylon corner bracket and the glass broken bridge aluminum alloy window, a composite waterproof and vapor-barrier membrane with an anchor bolt is further arranged on the prefabricated wallboard at the inner side of the glass broken bridge aluminum alloy window, and the composite waterproof and vapor-barrier membrane with the anchor bolt is a perforated nylon plate which is cast in the prefabricated wallboard through an anchor bolt and is compounded with a waterproof vapor-barrier membrane.

As one of the preferable technical schemes, the heat transfer coefficient of the glass bridge cut-off aluminum alloy window is 0.528W/m.k;

as one of the preferable technical schemes of the application, the nylon plate with holes in the composite waterproof vapor barrier with the anchoring bolts comprises a rectangular plate body, a plurality of ventilation holes are distributed on the rectangular plate body in a matrix form, the ventilation holes are circular through holes, and nylon anchoring nails are arranged on the nylon plate with holes between the adjacent ventilation holes on the same column.

As one of the preferable technical schemes of the application, the leveling and anchoring two-in-one assembly comprises a rectangular plate body, and the corner position of the rectangular plate body is connected with a leveling and anchoring bolt through a through hole.

As one of the preferable technical schemes of the application, the FRN glass fiber reinforced nylon corner brace is an L-shaped plate body.

Compared with the prior art, the application has the beneficial effects that:

1. the application adopts the leveling and anchoring two-in-one assembly, the position of the glass-broken bridge aluminum alloy window is adjusted when the glass-broken aluminum alloy window is pre-buried and installed, and the glass-broken bridge aluminum alloy window and the concrete can be anchored into a whole through bolts after concrete is poured.

2. According to the application, the waterproof vapor barrier is compounded by the anchoring bolt, the cloth-shaped waterproof vapor barrier and the perforated nylon plate are compounded into a whole, a good anchoring effect is formed after concrete is poured by the anchor bolts on the perforated nylon plate, and the aluminum square tube which is used in a turnover manner can be added in the concrete pouring stage to serve as a window mold.

3. The FRN glass fiber reinforced nylon corner connector has the advantages of low heat conductivity coefficient and high strength, and can be matched with a leveling and anchoring two-in-one component to realize connection and fixation with the glass bridge-cut-off aluminum alloy window.

4. The glass bridge-cut-off aluminum alloy window adopted by the application is used as a window main body, and the heat transfer coefficient is 0.528W/m.k.

Drawings

Fig. 1 is a schematic structural view of the present application.

Figure 2 is a schematic view of the structure of the tape Kong Nilong plate of the present application.

FIG. 3 is a schematic view of the FRN glass fiber reinforced nylon corner bracket and leveling and anchoring two-in-one assembly according to the present application.

In the figure: 1. prefabricating wallboard; 2. FRN glass fiber reinforced nylon corner connector; 3. a polyurethane foam gasket; 4. composite waterproof steam barrier film with anchoring bolt; 5. glass bridge cut-off aluminum alloy window; 6. leveling and anchoring two-in-one components; 7. ventilation holes; 8. a strap Kong Nilong plate; 9. nylon anchoring nails.

Detailed Description

The technical scheme of the application is further described and illustrated below with reference to the accompanying drawings and the embodiments. It should be noted that, the terms possibly related to the following paragraphs include, but are not limited to, "up, down, left, right, front, back" and the like, and the directions according to which the terms are all visual directions shown in the drawings of the corresponding specification, which should not be construed as limiting the scope of protection of the present technical solution, but are only for facilitating the understanding of the technical solution described in the specification by those skilled in the art.

In the description of the following paragraphs, unless expressly specified and limited otherwise, the terms "mounted," "connected," and the like are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art in view of the specific circumstances in combination with common general knowledge in the art, design specifications, standard documents, etc.

Example 1

Referring to fig. 1 to 3, an ultralow energy consumption window suitable for prefabricated integrated concrete wallboard in cold areas comprises a glass broken bridge aluminum alloy window 5, wherein the frame of the glass broken bridge aluminum alloy window 5 is integrally cast with a leveling and anchoring two-in-one assembly 6 and a prefabricated wallboard 1 through an FRN glass fiber reinforced nylon corner bracket 2, a polyurethane foaming gasket 3 is arranged at the connecting position between the FRN glass fiber reinforced nylon corner bracket 2 and the frame of the glass broken bridge aluminum alloy window 5, an anchoring bolt composite waterproof steam barrier 4 is arranged on the inner side of the prefabricated wallboard 1, which is positioned on the glass broken bridge aluminum alloy window 5, the anchoring bolt composite waterproof steam barrier 4 comprises a perforated nylon plate 8, a plurality of ventilation holes 7 are distributed on the perforated nylon plate 8 in a matrix, nylon anchoring nails 9 are arranged on the perforated nylon plate 8 between the adjacent ventilation holes 7 in a longitudinal column, and the nylon anchoring nails 9 are integrally cast with the prefabricated wallboard 1. The cloth-shaped waterproof steam barrier in the composite waterproof steam barrier with anchor bolts 4 is in line with the nylon plate 8 with holes. The heat transfer coefficient of the glass bridge cut-off aluminum alloy window 5 is 0.528W/m.k, the FRN glass fiber reinforced nylon corner connector 2 is of an L-shaped plate body structure, a through hole connected with the leveling and anchoring two-in-one component 6 is formed in the corner position of the FRN glass fiber reinforced nylon corner connector, the leveling and anchoring two-in-one component 6 comprises a rectangular plate body, and a through hole connected with a bolt buried in the prefabricated wallboard 1 is formed in the corner position of the rectangular plate body.

On the basis of the above embodiments, the technical features involved therein and the functions and roles that the technical features play in the technical solution are described in detail using the following paragraphs so as to help those skilled in the art to fully understand the technical solution and reproduce it.

The method comprises the steps of firstly, assembling all components in the prefabricated wallboard 1 in a factory, assembling a die of the prefabricated wallboard 1, binding reinforcing steel bars, then placing the glass bridge-cut aluminum alloy window 5 in the prefabricated wallboard 1 into the die, adopting a horizontally placed die table for production when producing the prefabricated wallboard 1, and adjusting the position of the glass bridge-cut aluminum alloy window 5 through a leveling and anchoring two-in-one assembly 6; then the turnover aluminum square tube is placed at the outer side of the composite waterproof steam barrier film 4 with the anchor bolt, and is temporarily fixed, and temporary film pasting protection is carried out on the glass bridge cut-off aluminum alloy window 5 and the window frame; removing the temporarily fixed aluminum square tube after the strength of the poured concrete reaches the requirement of removing the mould; and (3) sending the prefabricated wallboard 1 after the glass bridge cut-off aluminum alloy window 5 is installed to a construction site, and hoisting to a designated position for installation.

The application can ensure that the prefabricated wallboard 1 and the broken bridge aluminum alloy window are produced at one time, avoid the transportation and storage of the window, reduce the procedures of on-site installation, reduce the number of on-site construction people, reduce the installation cost, effectively avoid climbing operation and reduce the safety risk existing on site.

The application omits the procedure of installing the window on site and avoids the damage of the bridge cut-off aluminum alloy window on site to the decoration surface of the prefabricated wallboard.

Finally, although the description has been described in terms of embodiments, not every embodiment is intended to include only a single embodiment, and such description is for clarity only, as one skilled in the art will recognize that the embodiments of the disclosure may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (5)

1. The utility model provides an ultra-low energy consumption window suitable for prefabricated integration concrete wall board in cold district, includes glass bridge cut-off aluminum alloy window, still includes leveling and two unification subassemblies of anchor as an organic whole with prefabricated wallboard pouring, and leveling and two unification subassemblies of anchor are connected with FRN glass fiber reinforcement nylon angle sign indicating number, and FRN glass fiber reinforcement nylon angle sign indicating number passes through the bolt structure and is connected with the frame of glass bridge cut-off aluminum alloy window, just the connection position department of FRN glass fiber reinforcement nylon angle sign indicating number and glass bridge cut-off aluminum alloy window is provided with polyurethane foaming gasket, still be provided with on the prefabricated wallboard of glass bridge cut-off aluminum alloy window inboard and take the compound waterproof vapor barrier of anchor bolt, take the compound waterproof vapor barrier of anchor bolt to be the compound foraminiferous nylon plate that has waterproof vapor barrier through the crab-bolt pouring in prefabricated wallboard.

2. An ultra-low energy window adapted for prefabricated integrated concrete wall panels in cold areas as claimed in claim 1 wherein: the heat transfer coefficient of the glass bridge cut-off aluminum alloy window is 0.528W/m.k.

3. An ultra-low energy window adapted for prefabricated integrated concrete wall panels in cold areas as claimed in claim 2, wherein: the nylon plate with holes in the composite waterproof vapor barrier with the anchoring bolts comprises a rectangular plate body, a plurality of air holes are distributed on the rectangular plate body in a matrix form, the air holes are round through holes, and nylon anchoring nails are arranged on the nylon plate with holes between adjacent air holes on the same row.

4. An ultra-low energy window adapted for prefabricated integrated concrete wall panels in cold areas as claimed in claim 3, wherein: the leveling and anchoring two-in-one assembly comprises a rectangular plate body, and leveling and anchoring bolts are connected to the corner positions of the rectangular plate body through holes.

5. An ultra-low energy window adapted for prefabricated integrated concrete wall panels in cold areas as defined in claim 4 wherein: the FRN glass fiber reinforced nylon corner connector is an L-shaped board body.