CN111633801A - Modularized ultra-low energy consumption external wall panel for assembly type building and manufacturing method thereof - Google Patents

Abstract

An assembled modular ultra-low energy consumption external wall panel for buildings. The external wall panel is a sandwich structure consisting of a ribbed inner wall, a composite heat-insulating layer and a facing layer, wherein the facing layer can be any one of large-format stone, ceramic tiles, external wall calcium silicate boards and the like for dry hanging of an external wall facing; the composite heat insulation layer is 80-230 mm thick and comprises any two of a PUR heat insulation plate, an EPS heat insulation plate and a vacuum heat insulation plate. The external wall panel has the advantages of simple structure, good heat insulation performance and waterproof performance and wide application range. The invention also discloses a manufacturing method of the modular ultra-low energy consumption external wall panel for the fabricated building, which has the advantages of simple process and small difficulty.

Description

Modularized ultra-low energy consumption external wall panel for assembly type building and manufacturing method thereof

Technical Field

The invention relates to an external wall panel of a building prefabricated component and a manufacturing method thereof, in particular to a modular ultra-low energy consumption external wall panel for an assembly type building and a manufacturing method thereof.

Background

The common prefabricated concrete member for the prefabricated building is manufactured on an indoor formwork, the defects of complex process and high difficulty exist in the prior art, the manufactured external wall panel has low performances of heat preservation, heat insulation, water resistance, air tightness and the like, the use in certain specific places is not satisfied, and the application range is small.

Disclosure of Invention

The invention aims to solve the technical problem of overcoming the defects in the prior art and providing the modular ultra-low energy consumption external wall panel for the fabricated building, which has a simpler structure and better heat insulation performance and waterproof performance.

The invention further aims to solve the technical problem of overcoming the defects in the prior art and provide a manufacturing method of the modular ultra-low energy consumption external wall panel for the fabricated building, which has the advantages of simple process and low difficulty.

The technical scheme adopted by the invention for solving the technical problems is as follows: the modular ultra-low energy consumption external wall panel for the fabricated building is of a sandwich structure consisting of a ribbed inner leaf wall, a composite heat-insulating layer and a facing layer, wherein the facing layer can be any one of large-width stone, ceramic tiles, an external wall calcium silicate board and the like for dry hanging of an external wall facing; the composite heat-insulating layer is composed of at least any two of a PUR heat-insulating plate, an EPS heat-insulating plate and a vacuum heat-insulating plate.

Further, the thickness of the composite heat-insulating layer is 80-230 mm.

Furthermore, the width modulus of the external wall panel is 610 x n-10mm, wherein n is a positive integer.

Furthermore, the lower end of the ribbed inner leaf wall of the external wall panel is provided with a pre-embedded threaded sleeve and a tongue-and-groove, the two sides of the wall panel are provided with grooves, the inner side surface of the wall panel is provided with a polyurethane foam filling hole, and the composite heat-insulating layer forms an integral seamless structure after being filled with a polyurethane foaming agent.

Furthermore, cast-in-place concrete gaps are formed in two sides of the external wall panel, a cavity of the concrete bearing column free of a template is formed after adjacent wall bodies are combined, and an integral bearing structure is formed with the inner leaf wall after concrete is poured.

Further, the external wall panel adopts a reverse-beating production process, the inner leaf wall faces upwards, and the decorative surface layer is attached to the die table top, or adopts a forward-beating production process, the inner leaf wall is attached to the die table top, and the decorative surface layer faces upwards. During production, materials such as the wire box of the inner facing, the ceramic tile of the outer facing, the decorating part and the like can be paved at one time.

Furthermore, the ribbed inner leaf wall, the heat-insulating layer and the facing layer of the external wall panel are fixed through a heat-insulating connecting piece with low thermal conductivity, one end of the external wall panel is fixed with the facing layer through a back bolt screw, and the other end of the external wall panel is fixed in the concrete of the inner leaf wall.

Further, the heat-insulation connecting piece comprises an L-shaped plate type heat-insulation connecting piece and an L-shaped plug-in type heat-insulation connecting piece, wherein the L-shaped plate type heat-insulation connecting piece is formed by punching and bending a stainless steel plate, the thickness of the plate is 2-4 mm, and the plate is used for a reverse beating process, namely a facing layer is attached to the table top of a mold, and an inner leaf wall is upward; the L-shaped plug-in type heat-insulation connecting piece adopts 2-3 stainless steel wires, is bent into 90 degrees, an insertion head is bent into a corrugated shape, and the stainless steel wires are wound and coated by high-strength basalt fibers and vinyl resin to be fixed, so that the L-shaped plug-in type heat-insulation connecting piece is formed in a composite shaping mode.

Further, the door and window opening in the external wall panel is made of a wood-plastic PVC multi-cavity section, polyurethane foam heat-insulation materials are filled in the wood-plastic PVC multi-cavity section, and the wood-plastic PVC multi-cavity section is combined with a heat-insulation bridge-breaking piece made of basalt fiber composite ribs.

The invention further solves the technical problem and adopts the technical scheme that: a manufacturing method of modular ultra-low energy consumption external wall panel for fabricated building comprises the following steps:

s1: any one of stone, ceramic tiles or calcium silicate boards is selected to manufacture a facing layer, back bolt screw fixing holes are formed in the back of the facing layer, and then the L-shaped heat preservation connecting piece is fixed through back bolt screws;

s2: putting the decorative surface layer into a special mould for the wallboard, coating an adhesive on the decorative surface layer, adhering a PUR heat-insulating layer, and injecting polyurethane foaming glue into a splicing seam of the PUR heat-insulating layer and an L-shaped heat-insulating connecting piece penetrating hole to enable the PUR heat-insulating layer to form a whole;

s3: coating an adhesive on the PUR heat-insulating layer and sticking an EPS heat-insulating layer, and injecting polyurethane foaming glue into the abutted seams of the EPS heat-insulating layer and the L-shaped heat-insulating connecting piece penetrating holes to enable the EPS heat-insulating layer to form a whole;

s4: paving reinforcing steel bars on the EPS heat-insulating layer, and binding the reinforcing steel bars;

s5: and fixing a pre-buried threaded sleeve on the die, and reserving a plate-to-plate connector on the inner leaf wallboard and a die assembly tool of the groove of the inner leaf wallboard.

S6: and pouring concrete of the ribbed inner leaf wallboard.

Compared with the prior art, the external wall panel has the advantages of simple structure, better heat insulation performance and waterproof performance and wider application range; the manufacturing method of the external wall panel has the advantages of simple process and low difficulty.

Drawings

FIG. 1 is a diagram of an integrated thermal insulation wallboard component in example 1 of the present invention;

FIG. 2 is a schematic cross-sectional view of the thermal insulation integrated wallboard in the embodiment 1 shown in FIG. 1;

FIG. 3 is a schematic view of the construction of the heat-insulating integrated wall panel in embodiment 1 of FIG. 1;

FIG. 4 is a diagram of an integrated heat-insulating wall panel with a window according to example 2 of the present invention;

FIG. 5 is a schematic cross-sectional view of the heat-insulating integrated wall panel with a window in the embodiment 2 shown in FIG. 4;

FIG. 6 is a schematic view of the inside structure of a window board of the heat-insulating integrated wall board with a window;

FIG. 7 is a schematic view of the exterior of a window sill of an insulated integrated wall panel with a window;

FIG. 8 is a schematic view of the inside structure of a window lintel plate of the integrated insulation wall panel with a window;

FIG. 9 is a schematic view of the external structure of a window lintel plate of the integrated thermal insulation wallboard with window;

FIG. 10 is a schematic structural view of a door/window opening heat insulation bridge-cut-off member according to an embodiment of the present invention;

FIG. 11 is a schematic view of the installation of the door/window opening heat insulation bridge-cut-off member;

FIG. 12 is a schematic structural view of an L-shaped plate type thermal insulation connector according to an embodiment of the present invention;

FIG. 13 is a schematic structural view of an L-shaped male thermal connector according to an embodiment of the present invention;

in the figure: 1. the heat-insulation composite wall comprises a decorative surface layer, 2, a PUR heat-insulation layer, 3, an EPS heat-insulation layer, 4, a ribbed inner leaf wall, 5, an L-shaped plate heat-insulation connecting piece, 6, an L-shaped plug-in heat-insulation connecting piece, 501, a steel bar penetrating hole, 7, a rear plug-in heat-insulation layer tongue-and-groove, 502, a back bolt hole, 8, a door and window hole heat-insulation broken bridge piece, 9, a door and window hole decoration line, 10, a back bolt screw, 11, a transversely-inserted composite heat-insulation layer, 12, a vertically-inserted composite heat-insulation layer, 13, an inner leaf wallboard connecting port, 14, an inner leaf wall groove, 15, a hoisting threaded sleeve, 16, a supporting threaded sleeve, 17, an inclined supporting threaded sleeve, 18, a bottom positioning threaded sleeve and a polyurethane glue injection hole, 19, a positioning threaded sleeve, 20, a door and window hole side column fixing threaded sleeve, 21.

Detailed Description

The invention is described in further detail below with reference to the figures and the embodiments.

As shown in fig. 1-3 and 12-13, the external wall panel in this embodiment is a sandwich structure composed of a ribbed inner leaf wall 4, a PUR insulation board 2, an EPS insulation board 3, and a facing layer 1, and the facing layer 1 is a large-breadth stone for dry hanging of an external wall facing; the thickness of the composite heat-insulating layer is 150 mm.

In the embodiment, the width of the external wall panel is 610mm, the upper end and the lower end of the ribbed inner leaf wall 4 of the external wall panel are both provided with embedded threaded sleeves and tongue-and-grooves, both sides of the external wall panel are both provided with grooves, the inner side surface of the external wall panel is provided with polyurethane foam pouring holes, and the composite heat-insulating layer forms an integral seamless structure after a polyurethane foaming agent is poured; the cast-in-place concrete gaps are formed in two sides of the external wall panel, the adjacent wall bodies are combined to form a cavity of the concrete bearing column free of a template, and the concrete is poured to form an integral bearing structure with the inner leaf wall.

The outer wall board adopts a reverse-beating production process, the inner leaf wall faces upwards, and the decorative surface layer is attached to the die table top, or adopts a forward-beating production process, the inner leaf wall is attached to the die table top, and the decorative surface layer faces upwards. During production, materials such as the wire box of the inner facing, the ceramic tile of the outer facing, the decorating part and the like can be paved at one time.

The ribbed inner leaf wall 4, the composite heat-insulating layer and the facing layer 1 of the external wall panel are fixed by a heat-insulating connecting piece with low thermal conductivity, one end of the heat-insulating connecting piece is fixed with the facing layer by a back bolt screw, and the other end of the heat-insulating connecting piece is fixed in the concrete of the inner leaf wall.

In this embodiment, the heat insulating connector passes through the PUR heat insulating layer 2 and the EPS heat insulating layer 3, and the heat insulating layer tongue-and-groove 7 is inserted after the upper and lower and left and right outside of the EPS heat insulating layer 3 are reserved.

The heat-insulation connecting piece is an L-shaped heat-insulation connecting piece and comprises an L-shaped plate type heat-insulation connecting piece 5 and an L-shaped plug-in heat-insulation connecting piece 6, wherein the L-shaped plate type heat-insulation connecting piece 5 is formed by punching and bending a stainless steel plate, the thickness of the plate is 3mm, the plate is used for a reverse beating process, namely a facing layer is attached to a die table surface, and an inner leaf wall faces upwards. The upper 5 of the L-shaped plate type heat-insulating connecting piece is provided with a reinforcing steel bar penetrating hole 501 and a back bolt screw hole 502, the reinforcing steel bar penetrating hole 501 at the upper end of the L-shaped plate type heat-insulating connecting piece penetrates the reinforcing steel bar and then is anchored in the reinforcing steel bar of the ribbed inner leaf wall 4, and then polyurethane foaming adhesive is injected into the reinforcing steel bar penetrating hole 501.

The L-shaped plug-in heat-insulation connecting piece 6 is formed by bending 3 stainless steel wires into 90 degrees, the inserting head is bent into a corrugated shape, the stainless steel wires are wound and coated and fixed by high-strength basalt fibers and vinyl resin, the composite forming is in an L shape, the thermal conductivity coefficient is lower, both a positive beating and a negative beating process can be used, the corrugated part of the stainless steel wire at one end is exposed, and the corrugated stainless steel wire on the L-shaped plug-in heat-insulation connecting piece 6 is placed into the reinforcing steel bars of the ribbed inner leaf wall 4.

In this embodiment, reserve interior leaf inter-wall board connector 13, interior leaf wall recess 14 on the ribbed interior leaf wall 4, threaded sleeve 15, threaded sleeve 16, oblique bracing threaded sleeve 17, bottom location threaded sleeve and polyurethane glue-injection hole 18, location threaded sleeve 19 and door and window entrance to a cave side column fixed threaded sleeve 20 for pre-buried hoist and mount.

A manufacturing method of modular ultra-low energy consumption external wall panel for fabricated building comprises the following steps:

s1: any one of stone, ceramic tile or calcium silicate board is selected to manufacture the facing layer, back bolt screw fixing holes are arranged on the back of the facing layer 1, and then the L-shaped heat preservation connecting piece is fixed by back bolt screws;

s2: placing the facing layer 1 into a special mould for the wallboard, coating an adhesive on the facing layer 1 and adhering a PUR heat-insulating layer 2, and injecting polyurethane foaming adhesive into the abutted seams of the PUR heat-insulating layer 2 and the L-shaped heat-insulating connecting piece penetrating holes (namely the reinforcing steel bar penetrating holes 501) to enable the PUR heat-insulating layer 2 to form a whole;

s3: coating an adhesive on the PUR heat-insulating layer 2 and sticking an EPS heat-insulating layer 3, and injecting polyurethane foaming adhesive into the abutted seams of the EPS heat-insulating layer 3 and the L-shaped heat-insulating connecting piece penetrating holes to enable the EPS heat-insulating layer 3 to form a whole;

s4: paving reinforcing steel bars on the EPS heat-insulating layer 3, and binding the reinforcing steel bars;

s5: and fixing a pre-buried threaded sleeve on the die, and reserving a connector between the inner leaf wall plates and a die assembly tool of the inner leaf wall groove.

S6: concrete for the ribbed inner leaf wall 4 is poured.

Example 2:

as shown in fig. 4-9, a method for manufacturing an assembled modular ultra-low energy consumption external wall panel with a door/window opening for a building includes a method for manufacturing an assembled modular ultra-low energy consumption external wall panel for a building, wherein a prefabricated door/window opening decoration line 9 is placed in a mold before step S2, then a proper amount of concrete is poured on the door/window opening decoration line 9 before step S4, and then a door/window opening thermal insulation bridge-cut-off member 8 is placed and fixed in the concrete.

As shown in fig. 10-11, the door and window opening heat insulation broken bridge member 8 is composed of a wood-plastic PVC multi-cavity section and basalt fiber composite ribs, and a PUR heat insulation layer is filled in a cavity of the wood-plastic PVC multi-cavity section.

The above examples 1 and 2 both adopt the reverse beating production process, i.e. the facing layer sticking mould table board, and also the above examples can be manufactured according to the forward beating production process, i.e. the ribbed inner leaf wall sticking mould table board.

It should be noted that: the horizontally inserted composite heat-insulating layer 11 and the vertically inserted composite heat-insulating layer 12 are inserted in the installation process, and polyurethane foaming adhesive is injected through the polyurethane adhesive injection hole at the bottom after the installation is finished, so that the integrity and the sealing performance of the composite heat-insulating layer can be better ensured.

Various modifications and variations of the present invention may be made by those skilled in the art, and they are also within the scope of the present invention provided they are within the scope of the claims of the present invention and their equivalents.

What is not described in detail in the specification is prior art that is well known to those skilled in the art.

Claims (10)

1. The utility model provides an assembled for building modularization ultra-low energy consumption side fascia which characterized in that: the external wall panel is a sandwich structure consisting of a ribbed inner wall, a composite heat-insulating layer and a facing layer, wherein the facing layer can be any one of large-format stone, ceramic tiles, external wall calcium silicate boards and the like for dry hanging of an external wall facing; the composite heat-insulating layer is composed of at least any two of a PUR heat-insulating plate, an EPS heat-insulating plate and a vacuum heat-insulating plate.

2. The modular ultra-low energy consumption external wall panel for fabricated building of claim 1, wherein: the thickness of the composite heat-insulating layer is 80-230 mm.

3. The modular ultra-low energy consumption external wall panel for prefabricated building of claim 1 or 2, wherein: the width modulus of the external wall panel is 610 x n-10 mm.

4. The modular ultra-low energy consumption external wall panel for prefabricated building of claim 1 or 2, wherein: the lower end of the ribbed inner leaf wall of the outer wall panel is provided with a pre-embedded threaded sleeve and a tongue-and-groove, the two sides of the outer wall panel are provided with grooves, the inner side surface of the outer wall panel is provided with a polyurethane foam filling hole, and the composite heat-insulating layer forms an integral seamless structure after a polyurethane foaming agent is filled.

5. The modular ultra-low energy consumption external wall panel for prefabricated building as claimed in any one of claims 1-4, wherein: the side fascia both sides are equipped with cast in situ concrete breach, form the cavity that the concrete heel post exempted from the template after the adjacent wall body combination, form whole bearing structure with interior leaf wall after the pouring concrete.

6. The modular ultra-low energy consumption external wall panel for prefabricated building as claimed in any one of claims 1-5, wherein: the outer wall board adopts a reverse-beating production process, the inner leaf wall faces upwards, and the decorative surface layer is attached to the die table top, or adopts a forward-beating production process, the inner leaf wall is attached to the die table top, and the decorative surface layer faces upwards.

7. The modular ultra-low energy consumption external wall panel for prefabricated building of claim 1 or 2, wherein: the ribbed inner leaf wall, the heat-insulating layer and the finish coat of the external wall panel are fixed through a heat-insulating connecting piece with low thermal conductivity coefficient, one end of the external wall panel is fixed with the finish coat through a back bolt screw, and the other end of the external wall panel is fixed in the concrete of the inner leaf wall.

8. The modular ultra-low energy consumption external wall panel for fabricated building of claim 6, wherein: the heat-insulating connecting piece is an L-shaped plate type stainless steel heat-insulating connecting piece and an L-shaped plug-in type heat-insulating connecting piece.

9. The modular ultra-low energy consumption external wall panel for fabricated building of claim 1, wherein: the door and window opening in the external wall panel adopts a wood-plastic PVC multi-cavity profile, polyurethane foam heat-preservation materials are filled in the profile, and the profile is combined with a heat-insulation bridge-cut-off piece of basalt fiber composite ribs.

10. The method for manufacturing modular ultra-low energy consumption external wall panel for prefabricated building as claimed in claim 1, wherein: the method comprises the following steps:

s1: any one of stone, ceramic tile or calcium silicate board is selected to manufacture a veneer layer, a back bolt screw fixing blind hole is arranged on the back of the veneer layer, and then an L-shaped heat preservation connecting piece is fixed by a back bolt screw;

s2: putting the decorative surface layer into a special mould for the wallboard, coating an adhesive on the decorative surface layer, adhering a PUR heat-insulating layer, and injecting polyurethane foaming glue into a splicing seam of the PUR heat-insulating layer and an L-shaped heat-insulating connecting piece penetrating hole to enable the PUR heat-insulating layer to form a whole;

s3: coating an adhesive on the PUR heat-insulating layer and sticking an EPS heat-insulating layer, and injecting polyurethane foaming glue into the abutted seams of the EPS heat-insulating layer and the L-shaped heat-insulating connecting piece penetrating holes to enable the EPS heat-insulating layer to form a whole;

s4: paving reinforcing steel bars on the EPS heat-insulating layer for binding the reinforcing steel bars;

s5: fixing a pre-buried threaded sleeve on the die, and reserving a die assembly tool for an inter-plate connector and an inner leaf wallboard groove on the inner leaf wallboard;

s6: and pouring concrete of the ribbed inner leaf wallboard.

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