CN112443104A - Built-in internal thermal insulation wall - Google Patents

Abstract

The invention discloses a built-in inner heat-insulation wall body which comprises an original wall body, wherein a heat-insulation layer is arranged on the outer surface of the original wall body, the heat-insulation layer comprises heat-insulation rock wool and vertically arranged heat-insulation strips, the heat-insulation strips are uniformly arranged on the outer surface of the original wall body at intervals, the heat-insulation rock wool is uniformly filled in gaps of the heat-insulation strips, a plurality of decorative panels are further arranged on the outer surface of the heat-insulation layer, strip grooves are formed in the two sides of each decorative panel along the length direction, I-shaped parts are embedded between the two adjacent strip grooves, the two adjacent decorative panels are detachably connected through the I-shaped parts, and the I-shaped parts are detachably connected with the heat-insulation. According to the built-in internal thermal insulation wall provided by the invention, the wall surface thermal insulation problem is solved through the mode of the wall surface stone-plastic keel and the thermal insulation rock wool, and the effect of wall body sound insulation can be effectively solved. Wherein, the keel graph is changed, and the solid wall surface is thickened, so that higher sound insulation effect can be achieved.

Description

Built-in internal thermal insulation wall

Technical Field

The invention relates to the field of industrial assembly type decoration, in particular to a built-in inner heat insulation wall.

Background

Building energy conservation development is made up to now by various policies and standards, and building wall heat preservation is a trend. The heat-insulating layer is additionally arranged on the inner layer or the outer layer of the outer wall, so that the heat loss is avoided, and the heat-insulating effect is the most common heat-insulating system.

At present, the external wall external heat insulation installation modes on the market are more, but external heat insulation is not available on some existing buildings, the building energy consumption is larger, and if the existing buildings are transformed, an internal heat insulation mode can be selected. The inner heat preservation installation is mostly fixed by adopting a sticking and anchoring piece mode, various process treatments are needed after the heat preservation layer is manufactured, and finally, a veneer is installed. But the inner heat preservation adopts a gluing mode, so that the working procedures are more, the operation is inconvenient, the quality is not easy to control, and the like. Which comprises a keel rock wool heat preservation system. The keel rock wool heat preservation system is one of heat preservation systems in the outer wall, however, the light steel keel and the heat preservation cotton which are commonly used in the market can solve the problems of pasting of the heat preservation cotton and the like, but a heat bridge is easy to generate after the keel is installed on the wall, the heat loss is large, so the heat preservation purpose cannot be achieved, when a fire disaster happens, the temperature of the back fire surface of the wall can be rapidly increased, thereby the fire resistance limit of the wall is reduced, the heat preservation and energy saving performance of the wall is reduced, the wall condensation phenomenon is easy to occur in cold and severe cold areas, and the application of the light steel keel wall in the cold and severe cold areas is limited. The trompil fossil fragments rock wool outer wall that appears recently sets up the crisscross slot hole of multirow on the web of fossil fragments, and aim at extension heat transfer route improves light gauge steel composite wall's thermal insulation performance, nevertheless because lack deep research and application to the specification and the size of trompil, each trompil parameter collocation of current trompil fossil fragments rock wool outer wall trompil design is unreasonable, and the web percent opening is too big or the undersize, and wall body bearing capacity and rigidity are showing to be reduced after the web trompil, can not compromise the thermal insulation performance and the mechanical properties of wall body.

Disclosure of Invention

The invention aims to provide an internally-installed internal thermal insulation wall, relates to a harmless thermal bridge internal thermal insulation technology, and solves the problem of wall surface thermal insulation in a wall surface stone-plastic keel and thermal insulation rock wool mode. The heat conductivity coefficient of the stone-plastic keel is very low, about 0.7, which is 0.01 times of that of the light steel keel, thereby being very beneficial to heat preservation and improving the heat preservation performance of the keel system.

In order to achieve the purpose, the invention provides the following technical scheme, and the invention provides an internally-installed inner heat-insulation wall which comprises an original wall body and is characterized in that a heat-insulation layer is arranged on the outer surface of the original wall body, the heat-insulation layer comprises heat-insulation rock wool and vertically-arranged heat-insulation strips, the heat-insulation strips are uniformly arranged on the outer surface of the original wall body at intervals, the heat-insulation rock wool is uniformly filled in gaps of the heat-insulation strips, a plurality of decorative panels are further arranged on the outer surface of the heat-insulation layer, strip-shaped grooves are formed in the two sides of each decorative panel along the length direction, I-shaped pieces are embedded between every two adjacent strip-shaped grooves, the two adjacent decorative panels are detachably connected through the I-shaped pieces, and the I-shaped pieces are detachably.

Further, fossil fragments structure includes fossil fragments are moulded to stone, fossil fragments fastener, leveling screw, fossil fragments with heat preservation strip size looks adaptation can superpose together, the heat preservation strip has first round hole along the even interval arrangement of length direction, be provided with on the fossil fragments with the corresponding second round hole of first round hole, fossil fragments fastener one end can imbed the inside stable structure that forms of second round hole, the fossil fragments fastener is hollow structure and inside and is equipped with the internal thread, leveling screw one end with during fossil fragments fastener internal thread spiro union, the leveling screw other end can also imbed inside the first round hole, make the fossil fragments fastener with heat preservation strip keeps relatively fixed.

Further, fossil fragments both sides are moulded along length direction and are equipped with the recess, be equipped with on the fossil fragments fastener with the screens piece of recess looks adaptation, fossil fragments fastener embedding during the round hole is inside, the screens piece can be embedded form stable structure in the recess.

Further, the I-shaped piece is connected with the stone-plastic keel in an adhesive mode.

Furthermore, the stone-plastic keel is of a porous hollow structure.

Furthermore, the leveling screw rod is internally provided with a hollow structure, and the leveling screw rod can be rotated by twisting the internal hollow structure.

Furthermore, adjacent decorative boards arranged at the corners of the original wall body are detachably connected through the internal corner pieces.

Furthermore, heat preservation rock wool is evenly laid between keel structure distance furred ceiling vacancy fissure of displacement.

Further, the installation method of the built-in inner heat insulation wall body specifically comprises the following steps:

s1, uniformly arranging the heat preservation strips on the outer surface of the original wall at intervals, and mounting and leveling the keel structure on the heat preservation strips after the assembly is finished;

s2, filling heat preservation rock wool between the adjacent keel structures;

s3, filling the heat-preservation rock wool between the keel structure and the ceiling gap;

s4, splicing the plurality of veneers together through the I-shaped pieces, splicing two adjacent veneers at the corner by the internal corner pieces, then installing the veneers outside the heat-preservation rock wool layer, and bonding the I-shaped pieces and the keel structures together to complete the fixation of the veneers.

The invention has the beneficial effects that:

1. according to the internally-installed internal heat insulation wall provided by the invention, the wall surface heat insulation problem is solved through the wall surface stone-plastic keel and the heat insulation rock wool, the sound insulation effect of the wall body can be effectively solved, the sound insulation performance is excellent, and the sound absorption performance is stronger. Wherein, the higher sound insulation effect can be achieved by changing the keel graph (increasing the inner interlayer and thickening) and thickening the solid wall surface.

2. The heat-insulating wall body with the built-in inner heat-insulating layer, provided by the invention, has the advantages that the heat conductivity coefficient of the stone-plastic keel is very low, about 0.7, which is 0.01 times that of the light steel keel, the heat insulation is very facilitated, and the heat-insulating property of the keel system can be improved in response. And the heat preservation strip is arranged behind the stone-plastic keel, so that the effect of compact heat preservation of the internal heat preservation system is further improved.

3. According to the built-in internal thermal insulation wall provided by the invention, the anti-seismic strength of the wall plate structure formed by the keel system and the decorative wall plate can be the same as that of a building, and the wall plate structure has stronger anti-seismic capacity and can be safely and securely used.

4. The built-in inner heat insulation wall provided by the invention has the advantages of time saving, fast progress, clean construction site, easy management, no harm of gypsum powder and harmful flying dust to constructors and no pollution in the field of construction due to product composition and wallboard building construction.

5. According to the interior-installed interior-insulation wall body provided by the invention, the outer-layer decorative panel can be leveled by adjusting the height of the keel structure, so that the surface of the whole wall board is seamless, the flatness is high, and no seam crack occurs.

6. The built-in inner heat insulation wall body provided by the invention has the advantages that the wall body is simple in structure and long in service life, the I-shaped parts are easy to assemble and disassemble, and the I-shaped parts are convenient to replace and process after being used for a long time.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and together with the description, serve to explain the principles of the invention. In the drawings, like reference numerals are used to indicate like elements. The drawings in the following description are directed to some, but not all embodiments of the invention. For a person skilled in the art, other figures can be derived from these figures without inventive effort.

FIG. 1 is a schematic perspective view of an exploded structure of an interior thermal insulation wall according to an embodiment of the present invention;

FIG. 2 is a schematic top view of an interior thermal insulation wall according to an embodiment of the present invention;

FIG. 3 is a schematic perspective view of a keel structure for installing an interior thermal insulation wall according to an embodiment of the invention;

FIG. 4 is a schematic top view of a keel structure for an interior thermal insulation wall according to an embodiment of the invention;

FIG. 5 is a schematic structural view of a keel structure and an insulating strip for an interior thermal insulation wall according to an embodiment of the invention;

FIG. 6 is a schematic top view of a female corner fitting for use with an interior insulated wall according to an embodiment of the present invention;

fig. 7 is a schematic axial view of a three-dimensional structural system for the interior of an insulated wall according to an embodiment of the present invention.

In the figure: 1. an original wall body; 2. a heat-insulating layer; 3. heat preservation rock wool; 4. a heat-insulating strip; 5. a veneer; 6. a work piece; 7. a keel structure; 8. a strip-shaped groove; 9. a female corner fitting; 71. stone-plastic keel; 72. a keel fastener; 73. leveling screw rods; 74. a first circular hole; 75. a second circular hole; 76. a groove; 77. and (7) a clamping block.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention and the technical solutions in the prior art, the following description will be made with reference to the accompanying drawings. It is obvious that the drawings in the following description are only some examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be derived from them without inventive effort. The designation of the design orientation merely indicates the relative positional relationship between the respective members, not the absolute positional relationship.

Referring to fig. 1 and 2, in an embodiment of the present invention, an interior thermal insulation wall includes an original wall 1, a thermal insulation layer 2 is disposed on an outer surface of the original wall 1, the thermal insulation layer 2 includes thermal insulation rock wool 3 and vertically disposed thermal insulation strips 4, the thermal insulation strips 4 are uniformly arranged on the outer surface of the original wall 1 at intervals, the thermal insulation rock wool 3 is uniformly filled in gaps between the thermal insulation strips 4, wherein the thermal insulation rock wool 3 mainly plays a role in thermal insulation, and the thermal insulation strips 4 can play a role in thermal insulation and sealing the gaps, so as to prevent heat from being lost from the gaps, and further improve a thermal insulation effect of the thermal insulation layer 2.

Referring to fig. 1 and 2, the outer surface of the insulating layer 2 is further provided with a plurality of veneers 5, two sides of each veneer 5 are provided with a strip-shaped groove 8 along the length direction, an i-shaped member 6 is embedded between two adjacent strip-shaped grooves 8, and the two adjacent veneers 5 are detachably connected through an i-shaped member 6, specifically, the plurality of veneers 5 are connected in a staggered manner through the i-shaped members 6 to form a complete plane, wherein two adjacent veneers 5 arranged at the corners of the original wall 1 are detachably connected through an internal corner member 9, so that the veneers on the surfaces of all the walls can form a complete continuous plane structure. The I-shaped piece 6 is detachably connected with the heat preservation strip 4 through a keel structure 7. The H-shaped element 6 can be aligned flatly by adjusting the height of the keel structure 7, so that the veneer 5 is aligned flatly, and the aesthetic property and the integrity of the wall body can be ensured.

Further, referring to fig. 3, 4, 5 and 6, in the embodiment of the present invention, the keel structure 7 includes a stone-plastic keel 71, a keel fastener 72 and a leveling screw 73, the stone-plastic keel 71 and the heat preservation strip 4 can be overlapped together in a size matching way, the heat preservation strip 4 is evenly provided with first round holes 74 at intervals along the length direction, the stone-plastic keel 71 is provided with a second round hole 75 corresponding to the first round hole 74, one end of the keel fastener 72 can be inserted into the second circular hole 75 to form a stable structure, the keel fastener 72 is of a hollow structure, internal threads are arranged inside the keel fastener, when one end of the leveling screw 73 is in threaded connection with the internal threads of the keel fastener 72, the other end of the leveling screw 73 can also be embedded into the first round hole 74, so that the keel fastener 72 and the heat preservation strip 4 are kept relatively fixed. Wherein, fossil fragments 71 both sides are moulded along length direction and are equipped with recess 76, be equipped with on the fossil fragments fastener 72 with the screens piece 77 of recess 76 looks adaptation, fossil fragments fastener 72 embedding during the inside of second round hole 75, screens piece 77 can be embedded in form stable structure in the recess 76. Specifically, one end of the leveling screw 73 is screwed into the keel fastener 72 through threads, the keel fastener 72 is inserted into the second circular hole 75, the clamping block 77 can be embedded into the groove 76 to form a stable structure, the keel fastener 72 is fixed relative to the stone-plastic keel 71, the other end of the leveling screw 73 exposed outside is inserted into the first circular hole 74 to form a stable structure, and the stone-plastic keel 71 is fixed relative to the heat preservation bar 4.

Further, referring to fig. 6, in the embodiment of the present invention, the leveling screw 73 has a hollow structure inside, and the leveling screw 73 can be rotated by twisting the hollow structure inside. Specifically, when the leveling screw 73 is twisted, the keel fastener 72 can be driven to move back and forth in the thread direction, so that the stone-plastic keel 71 is adjusted to move back and forth, and the leveling arrangement of the whole stone-plastic keel 71 can be realized through comprehensive adjustment of the leveling screws 73.

Referring to fig. 3 again, the i-shaped member 6 is bonded to the stone-plastic keel 71. Specifically, after the stone-plastic keel 71 and the heat preservation strip 4 are fixed, the i-shaped member 6 can be fixedly bonded to the stone-plastic keel 71, so that the i-shaped member 6 is fixed on the outer surface of the original wall 1.

Further, referring to fig. 5 again, in the embodiment of the present invention, the stone-plastic keel 71 is a porous hollow structure. The stone-plastic keel 71 is provided with three hollow structures penetrating through the whole keel, the gravity of the stone-plastic keel 71 can be effectively reduced through the hollow structures, the light weight of materials is guaranteed, and the rigidity and the integrity of the keel cannot be damaged through the hollow structures, so that the keel still has strong compressive resistance. In some embodiments, the stone-plastic keel 71 may also be provided with a plurality of through hollow structures without affecting the integrity and rigidity of the keel.

Further, referring to fig. 1 and 2 again, in the embodiment of the present invention, heat preservation rock wool 3 is uniformly laid between the keel structure 7 and the staggered joint of the ceiling gap. Specifically, 7 length of keel structure with 1 highly different of original wall body, make 7 top of keel structure apart from one section distance in addition between the furred ceiling, this section space can directly be laid heat preservation rock wool 3, above is laid heat preservation rock wool 3 with the heat preservation rock wool 3 that 7 both sides of keel structure were laid forms complete sealed heat preservation, can realize high density heat preservation effect to the wall body.

Further, the installation method of the built-in inner heat insulation wall body specifically comprises the following steps:

s1, arranging the heat preservation strips 4 on the outer surface of the original wall body 1 at even intervals, assembling the keel structure 7, installing the keel structure on the heat preservation strips 4, and leveling, wherein the concrete process is as follows: screwing one end of a leveling screw 73 into the keel fastener 72 through threads, then inserting the keel fastener 72 into the second round hole 75, enabling a clamping block 77 to be embedded into the groove 76 to form a stable structure, enabling the keel fastener 72 and the stone-plastic keel 71 to be relatively fixed, then inserting the other end, exposed out of the leveling screw 73, of the leveling screw 73 into the first round hole 74 to form a stable structure, further enabling the stone-plastic keel 71 and the heat preservation strip 4 to be relatively fixed, and finally leveling the keel structure 7 by twisting the leveling screw 73;

s2, filling the heat preservation rock wool 3 between the adjacent keel structures 7;

s3, filling the heat preservation rock wool 3 between the keel structure 7 and the ceiling gap, and sealing the heat preservation rock wool 3 and the heat preservation strips to form a sealed heat preservation layer;

s4, splicing a plurality of veneers 5 together through I-shaped pieces 6, splicing two adjacent veneers 5 at the wall corners by using internal corner pieces 9, then installing the veneers on the outer side of the 3 layers of the heat-preservation rock wool, and bonding and connecting the I-shaped pieces 6 and the keel structures 7 together to complete the fixation of the veneers 5, namely completing the installation of the heat-preservation wall.

The above-described aspects may be implemented individually or in various combinations, and such variations are within the scope of the present invention.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The foregoing is a more detailed description of the invention in connection with specific preferred embodiments and it is not intended that the specific embodiments of the invention be limited to these descriptions. For those skilled in the art to which the invention pertains, several simple deductions or substitutions can be made without departing from the spirit of the invention, and all shall be considered as belonging to the protection scope of the invention.

Claims (9)

1. A wall body with built-in internal heat insulation comprises an original wall body (1) and is characterized in that the outer surface of the original wall body (1) is provided with a heat insulation layer (2), the heat-insulating layer (2) comprises heat-insulating rock wool (3) and a vertically arranged heat-insulating strip (4), the heat preservation strips (4) are uniformly arranged on the outer surface of the original wall body (1) at intervals, the heat preservation rock wool (3) is uniformly filled in the gaps of the heat preservation strips (4), the outer surface of the heat preservation layer (2) is also provided with a plurality of veneers (5), two sides of each veneer (5) are provided with strip grooves (8) along the length direction, an I-shaped piece (6) is embedded between every two adjacent strip grooves (8), the two adjacent veneers (5) are detachably connected through an I-shaped piece (6), the I-shaped piece (6) is detachably connected with the heat preservation strip (4) through a keel structure (7).

2. The built-in inner heat-insulation wall body according to claim 1, wherein the keel structure (7) comprises a stone-plastic keel (71), keel fasteners (72) and leveling screws (73), the stone-plastic keel (71) and the heat-insulation bar (4) are matched in size and can be stacked together, the heat-insulation bar (4) is uniformly provided with first round holes (74) at intervals along the length direction, the stone-plastic keel (71) is provided with second round holes (75) corresponding to the first round holes (74), one end of each keel fastener (72) can be embedded into the corresponding second round hole (75) to form a stable structure, each keel fastener (72) is a hollow structure and is internally provided with an internal thread, when one end of each leveling screw (73) is in threaded connection with the corresponding keel fastener (72), the other end of each leveling screw (73) can be further embedded into the corresponding first round hole (74), so that the keel fastener (72) and the heat preservation strip (4) are kept relatively fixed.

3. An interior thermal insulation wall according to claim 2, wherein grooves (76) are formed in the two sides of the stone-plastic keel (71) along the length direction, clamping blocks (77) matched with the grooves (76) are arranged on the keel fasteners (72), and when the keel fasteners (72) are embedded into the second round holes (75), the clamping blocks (77) can be embedded into the grooves (76) to form a stable structure.

4. An interior insulated wall according to claim 2, characterised in that the I-shaped element (6) is adhesively bonded to the stone-plastic keel (71).

5. An interior insulated wall according to claim 2, characterised in that the stone-plastic keel (71) is of a porous hollow structure.

6. An internally installed insulated wall according to claim 2, wherein the leveling screw (73) is internally hollow, and the leveling screw (73) can be rotated by twisting the internal hollow.

7. An internal thermal insulation wall according to claim 1, wherein adjacent facing panels (5) provided at the corners of the original wall (1) are detachably connected by female corner fittings (9).

8. An internally installed heat insulating wall according to claim 1, wherein the heat insulating rock wool (3) is uniformly laid between the keel structure (7) and the staggered joints of the ceiling cavity.

9. The method of installing an interior thermal insulation wall according to any one of claims 1 to 8, comprising the steps of:

s1, arranging the heat preservation strips (4) on the outer surface of the original wall body (1) at uniform intervals, and mounting and leveling the keel structure (7) on the heat preservation strips (4) after the assembly is finished;

s2, filling the heat-preservation rock wool (3) between the adjacent keel structures (7);

s3, filling the heat-preservation rock wool (3) in the gap between the keel structure (7) and the ceiling;

s4, splicing the multiple veneers (5) together through the I-shaped pieces (6), splicing two adjacent veneers (5) at the wall corners by using internal corner pieces (9), then installing the veneers on the outer side of the heat-preservation rock wool layer (3), and bonding and connecting the I-shaped pieces (6) and the keel structures (7) together to complete the fixation of the veneers (5).

Images