KR102332221B1 - Interior finishing structures for buildings - Google Patents

Abstract

Disclosed is an interior finishing structure for a building, which can use a multi-layer structure and a vibration-proof structure, thereby preventing deformation and damage, maximizing insulation, fire protection, cushioning, and sound absorption performance, and maximizing the utilization of indoor space. The interior finishing structure for a building comprises: a first insulation assembly installed on the inner wall of a building; a second insulation assembly spaced apart from the first insulation assembly; a third insulation assembly spaced apart from the second insulation assembly, and having one surface exposed to an indoor space; a first vibration-proof assembly for elastically supporting the first and second insulation assemblies; a second vibration-proof assembly for elastically supporting the second insulation assembly and the third insulation assembly; and a variable insulation assembly for adjusting the size of the indoor space.

Description

Interior finishing structures for buildings

The present invention relates to an interior finishing structure for a building.

In general, a thermal insulation panel in the form of compressed Styrofoam is attached to the inner wall of a building made of a concrete material.

However, as the insulation panel attached to the inner wall of a building is formed in a single-layer structure, it is not only vulnerable to heat insulation, but also has a problem of being separated from the inner wall due to expansion and contraction deformation according to a change in temperature. Accordingly, there is a problem that dew condensation occurs between the inner wall and the heat insulating panel depending on the temperature difference between the inside and outside.

In addition, in the prior art, the wall construction was completed by attaching a paper finish to the outer surface of the insulation panel or directly applying a paint to the outer surface of the insulation panel.

Accordingly, when an impact is applied to the insulation panel from the inside or vibration is transmitted, the insulation panel is easily damaged or deformed because the finishing material or the paint layer attached to the outer surface of the insulation panel does not disperse and attenuate the external force. .

In addition, in the prior art, there was a problem in that the insulation panel attached to the inner wall of the building and the finishing material attached to the outer surface of the insulation panel are vulnerable to fire and sound insulation.

On the other hand, in the prior art, as the indoor space of a building has a limited size and structure, it is impossible to direct the space according to the user's needs, and there is a problem in that the utilization of the space is lowered.

Registered Patent Publication No. 10-1287987

The present invention has been devised to solve the above problems, and an object of the present invention is to apply a multilayer structure and a dustproof structure to prevent deformation and damage, as well as maximize insulation, fire protection, buffering and sound absorption performance, and It is to provide an interior finishing structure for buildings that can maximize the utilization of space.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The interior finishing structure for a building according to an embodiment of the present invention for solving the above problems is a first insulation assembly installed on the inner wall of the building; a second thermal insulation assembly spaced apart from the first thermal insulation assembly; a third thermal insulation assembly spaced apart from the second thermal insulation assembly and having one surface exposed to the indoor space; disposed between the first heat insulation assembly and the second heat insulation assembly, and configured to elastically support the first heat insulation assembly and the second heat insulation assembly in a direction in which the first heat insulation assembly and the second heat insulation assembly are spaced apart a first anti-vibration assembly; disposed between the second thermal insulation assembly and the third thermal insulation assembly, configured to elastically support the second thermal insulation assembly and the third thermal insulation assembly in a direction in which the second thermal insulation assembly and the third thermal insulation assembly are spaced apart a second anti-vibration assembly; and a variable heat insulation assembly configured to adjust the size of the indoor space while moving along the outer surface of the third heat insulation assembly. includes

The first heat insulating assembly may include: a 1-1 heat insulating panel installed on the inner wall, having a plurality of heat insulating layers in a laminated structure, and made of a compressed Styrofoam material; a plurality of metal panel supports arranged on one surface of the 1-1 insulation panel along the height direction of the inner wall and configured to press the 1-1 insulation panel toward the inner wall; a 1-2 heat insulating panel made of an elastic material disposed on one surface of the 1-1 heat insulating panel while pressing the panel supports; and a rock wool 1-3 heat insulation panel disposed on one surface of the 1-2 heat insulation panel and supported by the first vibration-proof assembly. may include.

The second heat insulation assembly may include: a 2-1 heat insulation panel made of a fire-resistant wood material that is disposed opposite the first heat insulation assembly with the first vibration insulation assembly interposed therebetween and is supported by the first vibration insulation assembly; a 2-2 heat-insulating panel made of rock wool disposed on one surface of the 2-1 heat-insulating panel; a 2-3rd heat insulation panel having a concave-convex structure coupled to the 2-2 heat insulation panel and supported on one surface of the 2-2 heat insulation panel; a plurality of fastening aids coupled to the second-third thermal insulation panel; While passing through the plurality of fastening aids and sequentially coupled to the 2-2 heat-insulating panel and the 2-1 heat-insulating panel, the plurality of fastening aids and the 2-3-th heat-insulating panel are moved toward the 2-2 heat-insulating panel. a plurality of fasteners configured to pressurize; 2-4 heat insulating panels made of a metal material coupled to and supported by the plurality of fastening aids; a plurality of heat-insulating bars made of a compressed Styrofoam material press-fitted between the 2-3rd heat-insulating panel and the 2-4th heat-insulating panel; a 2-5 heat-insulating panel made of an elastic material disposed on one surface of the 2-4 heat-insulating panel; and 2-6 heat insulating panels made of rock wool supported on one surface of the 2-5 heat insulation panel and disposed opposite the third heat insulation assembly with the second vibration isolation assembly interposed therebetween and supported by the second vibration isolation assembly. wherein the 2-3th heat insulation panel comprises: a panel part having a depression supported on one surface of the 2-2 heat insulation panel and a protrusion spaced apart from the one surface of the 2-2nd heat insulation panel; and a wedge-shaped press-fitting part configured to be supported by being caught by the 2-2 heat-insulating panel while being press-fitted into the 2-2 heat-insulating panel. including, wherein the plurality of fastening aids include: a 'C'-shaped bracket supported by the protrusion and configured to accommodate a portion of the plurality of fastening aids and a part of the second-fourth heat insulating panel therein; and a fixing part supported by the protrusion through the protrusion and configured to pass through the plurality of fastening aids therein. Including, wherein the 2-4 heat insulation panel, a support part in the form of a flat plate for supporting the plurality of heat insulation bars; and a ring portion accommodated in the bracket portion and configured to be supported by the bracket portion; may include.

The third heat insulation assembly may include: assembly panels configured to be coupled to each other along a width direction and a height direction of the inner wall; and coupling magnets individually inserted into the assembly panels and configured to be coupled to each other by magnetic force when the assembly panels are coupled. Including, wherein the assembly panel comprises: a panel body; a plurality of locking protrusions disposed at an end of the panel body along the circumference of the panel body and having a hook structure protruding from the end of the panel body to the outside of the panel body; and a plurality of locking grooves disposed at an end of the panel body along the circumference of the panel body, recessed from the end of the panel body to the inside of the panel body, and having a hook structure corresponding to the locking protrusion, The panel body may include a first body portion disposed to face the indoor space; a second body portion disposed to face the second heat insulation assembly and supported by the second vibration-proof assembly; a buffer cell disposed between the first body part and the second body part, the fluid being filled therein; It is disposed between the first body part and the second body part and communicates with the buffer cell, and is compressed in the axial direction when the assembly panels are combined to open an internal flow path to mutually connect the buffer cells accommodated in the assembly panels to each other. a sealing tube made of an elastic material configured to communicate; a first magnetic body accommodated in the first body portion; and a second magnetic body accommodated in the second body portion and configured to be coupled to the first magnetic body through a magnetic force. may include.

The first anti-vibration assembly may include: a 1-1 support panel attached to and fixedly disposed on the first heat insulation assembly; a first-second support panel spaced apart from the first-first support panel to support the second heat-insulating assembly and flow together with the second heat-insulating assembly; a guide shaft disposed between the 1-1 support panel and the 1-2 support panel; a fixture fixedly disposed on one side of the guide shaft along the axial direction of the guide shaft; a moving member disposed on the other side of the guide shaft along the axial direction of the guide shaft and slidably movable along the outer surface of the guide shaft; A first scissor link disposed between the 1-1 support panel and the guide shaft, one side rotatably coupled to the 1-1 support panel, and the other side rotatably coupled to the fixture and the moving member assembly; A second scissor link disposed between the 1-2 support panel and the guide shaft, one side rotatably coupled to the fixture and the moving member, and the other side rotatably coupled to the 1-2 support panel assembly; and a plurality of elastic connectors disposed around the guide shaft to connect the moving member and the fixture to each other, and configured to elastically support the moving member when the moving member is moved away from the fixture; may include.

The second vibration-proof assembly may include: a 2-1 support panel attached to the second insulation assembly and flowing together with the second insulation assembly; a 2-2 support panel attached to the third insulation assembly and flowing together with the third insulation assembly; a core spring having a spiral structure disposed at the center between the 2-1 th support panel and the 2-2 th support panel to elastically support the 2-1 th support panel and the 2-2 th support panel; first sub-springs spaced apart from the core spring along a radial direction of the core spring and elastically supporting the 2-1 th support panel and the 2-2 th support panel at a plurality of positions; second sub-springs spaced apart from the first sub-springs along the radial direction of the core spring and elastically supporting the second-first support panel and the second-second support panel at a plurality of positions; and tubular vibration-proof spheres spaced apart from the second sub-springs along a radial direction of the core spring and elastically supporting the second-first support panel and the second-second support panel at a plurality of positions. may include.

The variable heat insulation assembly may include: a screw shaft disposed on an outer surface of the third heat insulation assembly disposed on one side of the inner wall; a plurality of support units disposed on the outer surface of the third heat insulation assembly along the longitudinal direction of the screw shaft to rotatably support the screw shaft; a shaft drive actuator configured to rotate the screw shaft; a guide rail disposed on an outer surface of the third heat insulation assembly disposed on the other side of the inner wall; It is disposed in the indoor space, a part is coupled to the screw shaft, and the other part is coupled to the guide rail, and when the screw shaft is rotated, the screw shaft and the guide rail are moved along each axial direction of the indoor space. a temporary wall configured to partition the space into a plurality of spaces; and an opening and closing door disposed on the temporary wall and configured to selectively open and close the temporary wall to selectively communicate a plurality of spaces partitioned by the temporary wall.

According to an embodiment of the present invention, as the insulation assemblies have a multi-layer structure, and vibration-proof assemblies are disposed between the insulation assemblies, deformation and damage can be prevented even when the external environment changes and an impact is applied from the outside. Of course, it is possible to maximize the insulation, fire protection, cushioning and sound absorption performance.

In addition, according to the present invention, the indoor space can be partitioned as needed, and the size of the indoor space can be selectively adjusted, so that various presentations are possible according to the needs of the user, thereby maximizing the use of the space.

The effect according to the present invention is not limited by the contents exemplified above, and more various effects are included in the present invention.

1 is a view schematically showing a state in which an indoor finishing structure for a building according to an embodiment of the present invention is installed in a building.
2 is a view schematically showing a cross-section of a first insulation assembly of an indoor finishing structure for a building according to an embodiment of the present invention.
3 is a view schematically showing a cross-section of a second heat insulation assembly of an indoor finishing structure for a building according to an embodiment of the present invention.
4 is a front view illustrating a third heat insulation assembly of an indoor finishing structure for a building according to an embodiment of the present invention.
5 is an enlarged view of an enlarged portion "A" of FIG.
FIG. 6 is a view schematically showing a cross-section of a portion "B" of FIG. 4 .
7 is a view schematically showing a portion in which the assembly panels of the indoor finishing structure for a building are coupled according to an embodiment of the present invention.
8 is a view schematically showing a part of a cross section of an assembly panel of an indoor finishing structure for a building according to an embodiment of the present invention.
9 is a view schematically illustrating a state in which the first vibration-proof assembly of the indoor finishing structure for a building according to an embodiment of the present invention is disposed between the first heat-insulating assembly and the second heat-insulating assembly.
10 is a front view schematically showing a second anti-vibration assembly of an indoor finishing structure for a building according to an embodiment of the present invention.

Hereinafter, various embodiments will be described in more detail with reference to the accompanying drawings. The embodiments described herein may be variously modified. Certain embodiments may be depicted in the drawings and described in detail in the detailed description. However, the specific embodiments disclosed in the accompanying drawings are only for easy understanding of various embodiments. Therefore, the technical spirit is not limited by the specific embodiments disclosed in the accompanying drawings, and it should be understood to include all equivalents or substitutes included in the spirit and scope of the invention.

Terms including an ordinal number, such as first, second, etc., may be used to describe various elements, but these elements are not limited by the above-described terms. The above terminology is used only for the purpose of distinguishing one component from another component.

In this specification, terms such as "comprises" or "have" are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof. When a component is referred to as being “connected” or “connected” to another component, it is understood that the other component may be directly connected or connected to the other component, but other components may exist in between. it should be On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that no other element is present in the middle.

Meanwhile, as used herein, a “module” or “unit” for a component performs at least one function or operation. And “module” or “unit” may perform a function or operation by hardware, software, or a combination of hardware and software. In addition, a plurality of “modules” or a plurality of “units” other than a “module” or “unit” that must be performed in specific hardware or are executed in at least one processor may be integrated into at least one module. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In addition, in describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be abbreviated or omitted.

1 is a view schematically showing a state in which an indoor finishing structure for a building according to an embodiment of the present invention is installed in a building, and FIG. 2 is a cross-section of the first insulation assembly of the indoor finishing structure for a building according to an embodiment of the present invention It is a schematic drawing.

1 and 2 , the interior finishing structure 1 for a building according to an embodiment of the present invention (hereinafter referred to as 'interior finishing structure for a building (1)') includes a first heat insulation assembly 10 and a second and a thermal insulation assembly 20 , a third thermal insulation assembly 30 , a first vibration-proof assembly 40 , a second vibration-proof assembly 50 , and a deformable thermal insulation assembly 60 .

The first heat insulation assembly 10 is installed on the inner wall W of the building B, and has a multi-layer structure.

The first thermal insulation assembly 10 may include a 1-1 insulation panel 11 , panel supports 12 , a 1-2 insulation panel 13 , and a 1-3 insulation panel 14 .

The 1-1 heat insulation panel 11 is formed of a compressed Styrofoam material, is installed on the inner wall W, and may have a plurality of heat insulation layers 111 having a laminated structure.

The panel supports 12 are formed of a metal material, and are arranged in plurality on one surface of the 1-1 heat insulation panel 11 along the height direction of the inner wall W to attach the 1-1 heat insulation panel 11 to the inner wall ( W) can be configured to press to the side.

The 1-2 heat insulation panel 13 may be formed of an elastic material, and may be disposed on one surface of the 1-1 heat insulation panel 11 while pressing the panel supports 12 .

The 1-3 heat insulation panel 14 is formed of a rock wool material, is disposed on one surface of the 1-2 heat insulation panel 13 , and may be supported by the first anti-vibration assembly 40 .

3 is a view schematically showing a cross-section of a second heat insulation assembly of an indoor finishing structure for a building according to an embodiment of the present invention.

2 and 3 , the second thermal insulation assembly 20 is spaced apart from the first thermal insulation assembly 10 and has a multi-layered structure.

The second thermal insulation assembly 20 is disposed opposite to the first thermal insulation assembly 10 with the first vibration-proof assembly 40 interposed therebetween, and the second thermal insulation of fire-resistant wood material supported by the first vibration-proof assembly 40 is provided. It may include a panel 21 and a 2-2nd heat insulation panel 22 made of rock wool, which is disposed on one surface of the 2-1th heat insulation panel 21 .

In addition, the second heat insulation assembly 20 is coupled to the 2-2 heat insulation panel 22 and is supported on one surface of the 2-2 heat insulation panel 22, the second heat insulation panel 23 having a concave-convex structure; It may include a plurality of fastening aids 24 coupled to the 2-3th heat insulation panel 23 .

Here, the 2-3 th heat insulation panel 23 may include a panel part 231 and a press-fit part 232 .

The panel part 231 may include a recessed part 2311 supported on one surface of the 2-2nd heat insulation panel 22 and a protrusion part 2312 spaced apart from the one surface of the 2-2nd heat insulation panel 22 . have.

The press-fitting portion 232 may be formed in a wedge structure configured to be supported by the 2-2 heat-insulating panel 22 while being press-fitted into the 2-2 heat-insulating panel 22 .

The plurality of fastening aids 24 may include a bracket part 241 and a fixing part 242 .

The bracket part 241 is supported by the protrusion part 2312 , and a part of the plurality of fastening aids 24 and a part of the second-fourth insulation panel 26 to be described later may be accommodated therein. For example, the bracket part 241 may be formed in a rail structure having a 'C' shape in cross section.

The fixing part 242 penetrates the protrusion 2312 and is supported by being caught on the protrusion 2312 , and may be configured such that a plurality of fastening aids 24 penetrate therein.

In addition, the second heat insulation assembly 20 passes through the plurality of fastening aids 24 and is sequentially coupled to the 2-2 heat insulation panel 22 and the 2-1 heat insulation panel 21, and a plurality of fastening aids (24) and a plurality of fasteners 25 configured to press the 2-3rd heat insulation panel 23 toward the 2-2 heat insulation panel 22, and a plurality of fastening aids 24 coupled and supported The 2-4th heat insulation panel 26 made of a metal material may be included.

Here, the 2-4 heat insulating panel 26 is accommodated in a flat support part 261 supporting the plurality of heat insulating bars 27 and the bracket part 241 and is configured to be supported by the bracket part 241 . It may include a ring portion 262.

In addition, the second heat insulation assembly 20 includes a plurality of heat insulation bars 27 made of a compressed Styrofoam material press-fitted between the 2-3th heat insulation panel 23 and the 2-4th heat insulation panel 26, and the 2-4th heat insulation panel. 2-5 heat-insulating panel 28 of an elastic material disposed on one side of the heat-insulating panel 26, and supported on one side of the 2-5 heat-insulating panel 28, with the second anti-vibration assembly 50 interposed therebetween The second heat insulating panel 29 of rock wool is disposed opposite to the third heat insulating assembly 30 and supported by the second anti-vibration assembly 50 .

FIG. 4 is a front view showing a third heat insulation assembly of an indoor finishing structure for a building according to an embodiment of the present invention, and FIG. 5 is an enlarged view of an enlarged portion "A" of FIG. 4 .

4 and 5 , the third heat insulation assembly 30 is spaced apart from the second heat insulation assembly 20 so that one surface is exposed to the indoor space S, and has a structure that can be assembled or disassembled.

The third thermal insulation assembly 30 may include assembly panels 31 and coupling magnets 32 .

The assembly panels 31 may be configured to be coupled to each other along the width direction and the height direction of the inner wall (W).

The coupling magnets 32 may be individually inserted into the assembly panels 31 , and may be configured to be coupled to each other by magnetic force when the assembly panels 31 are coupled.

6 is a view schematically showing a cross-section of part "B" of FIG. 4, and FIG. 7 is a view schematically showing a part in which the assembly panels of the interior finishing structure for a building according to an embodiment of the present invention are combined, and FIG. is a view schematically showing a part of a cross section of an assembly panel of an indoor finishing structure for a building according to an embodiment of the present invention.

4 and 6 to 8 , the assembly panel 31 may include a flat panel body 311 , a locking protrusion 312 , and a locking groove 313 .

The panel body 311 includes a first body portion 3111 disposed to face the indoor space S, and a second heat insulating assembly 20 disposed to face the second anti-vibration assembly 50 . It may include a body part 3112 .

In addition, the panel body 311 is disposed between the first body portion 3111 and the second body portion 3112, and a buffer cell 3113 filled with a fluid F therein, and the first body portion 3111 ) and the second body part 3112 are disposed between the buffer cell 3113 and communicate with the assembly panels 31 while being compressed in the axial direction when the assembly panels 31 are combined to open the flow path P inside the assembly panels 31 ) may include a sealing tube 3114 of an elastic material configured to communicate with each other the buffer cells 3113 accommodated in the.

In addition, the panel body 311 is accommodated in the first magnetic body 3115 accommodated in the first body part 3111 and the second body part 3112, and is configured to be coupled to the first magnetic body 3115 through a magnetic force. A second magnetic material 3116 may be included.

A plurality of locking protrusions 312 are disposed at an end of the panel body 311 along the circumference of the panel body 311 , and have a hook structure that protrudes from the end of the panel body 311 to the outside of the panel body 311 . can be

A plurality of locking grooves 313 are disposed at the ends of the panel body 311 along the circumference of the panel body 311, and are recessed from the ends of the panel body 311 to the inside of the panel body 311, and the locking protrusions ( 312) may be formed in a hook structure corresponding to the structure.

9 is a view schematically showing a state in which the first vibration-proof assembly of the indoor finishing structure for a building according to an embodiment of the present invention is disposed between the first heat-insulating assembly and the second heat-insulating assembly.

2 and 9 , the first anti-vibration assembly 40 is disposed between the first heat insulation assembly 10 and the second heat insulation assembly 20, and the first heat insulation assembly 10 and the second heat insulation assembly ( 20 is configured to elastically support the first thermal insulation assembly 10 and the second thermal insulation assembly 20 in a spaced apart direction.

The first vibration-proof assembly 40 includes a 1-1 support panel 41 attached and fixedly disposed to the first insulation assembly 10 , and a second insulation assembly 20 spaced apart from the 1-1 support panel 41 . ) and a 1-2 support panel 42 flowing together with the second heat insulation assembly 20, and disposed between the 1-1 support panel 41 and the 1-2 support panel 42 It may include a guide shaft 43 .

In addition, the first anti-vibration assembly 40 includes a fixture 44 fixedly disposed on one side of the guide shaft 43 along the axial direction of the guide shaft 43 and the guide shaft along the axial direction of the guide shaft 43 . It is disposed on the other side of (43), it may include a movable member (45) slidable along the outer surface of the guide shaft (43).

In addition, the first vibration-proof assembly 40 is disposed between the 1-1 support panel 41 and the guide shaft 43, one side is rotatably coupled to the 1-1 support panel 41, and the other side It is disposed between the first scissor link assembly 46 rotatably coupled to the fixture 44 and the moving member 45 and the 1-2 support panel 42 and the guide shaft 43, one side of the fixture ( 44) and a second scissor link assembly 47 that is rotatably coupled to the moving member 45 and the other side is rotatably coupled to the 1-2 second support panel 42 .

In addition, the first anti-vibration assembly 40 is disposed on the periphery of the guide shaft 43 in plurality to connect the moving member 45 and the fixture 44 to each other, and the moving member 45 is far from the fixture 44 . It may include a plurality of elastic connecting body 48 configured to elastically support the moving member 45 when it is moved.

10 is a front view schematically showing the second vibration-proof assembly of the indoor finishing structure for a building according to an embodiment of the present invention.

2 and 10 , the second vibration-proof assembly 50 is disposed in plurality between the second heat insulation assembly 20 and the third heat insulation assembly 30 , and the second heat insulation assembly 20 and the third heat insulation assembly 20 . The assembly 30 is configured to elastically support the second thermal insulation assembly 20 and the third thermal insulation assembly 30 in spaced apart directions.

The second anti-vibration assembly 50 is attached to the second heat insulation assembly 20 and is attached to the 2-1 support panel 51 that flows together with the second heat insulation assembly 20 and the third heat insulation assembly 30 . It may include a 2-2 support panel 52 that flows together with the third thermal insulation assembly 30 .

In addition, the second anti-vibration assembly 50 is disposed at the center between the 2-1 th support panel 51 and the 2-2 nd support panel 52 , and the 2-1 th support panel 51 and the 2-2 th support panel 52 . It may include a core spring 53 having a spiral structure that elastically supports the support panel 52 .

In addition, the second vibration-proof assembly 50 is spaced apart from the core spring 53 along the radial direction of the core spring 53, and the 2-1 support panel 51 and the 2-2 support panel at a plurality of positions. The first sub springs 54 elastically supporting the 52 and the first sub springs 54 along the radial direction of the core spring 53 are spaced apart from the first sub springs 54 at a plurality of positions 2-1 The support panel 51 and the second sub springs 55 elastically supporting the 2-2 support panel 52 may be included.

In addition, the second vibration-proof assembly 50 is spaced apart from the second sub-springs 55 along the radial direction of the core spring 53, and the second-first support panel 51 and the second-second support panel 51 at a plurality of positions. 2 It may include tubular anti-vibration spheres 56 that elastically support the support panel 52 .

Referring to FIG. 1 , the variable heat insulation assembly 60 is configured to adjust the size of the indoor space S while moving along the outer surface of the third heat insulation assembly 30 .

The variable heat insulation assembly 60 includes a screw shaft 61 disposed on an outer surface of the third heat insulation assembly 30 disposed on one side of the inner wall W, and a third heat insulation assembly along the longitudinal direction of the screw shaft 61 . A plurality of support units 62 are disposed on the outer surface of the 30 to rotatably support the screw shaft 61 may be included.

In addition, the variable heat insulation assembly 60 includes a shaft driving actuator 63 configured to rotate the screw shaft 61, and the third heat insulation assembly 30 disposed on the other side of the inner wall W. It is disposed on the outer surface A guide rail 64 may be included.

In addition, the variable heat insulation assembly 60 is disposed in the indoor space S, a part is coupled to the screw shaft 61 , and the other part is coupled to the guide rail 64 , and a screw when the screw shaft 61 is rotated. It may include a temporary wall 65 configured to partition the indoor space (S) into a plurality of spaces while moving along each axial direction of the shaft 61 and the guide rail 64 .

In addition, the deformable heat insulation assembly 60 is disposed on the temporary wall 65 and selectively opens and closes the temporary wall 65 to selectively communicate a plurality of spaces partitioned by the temporary wall 65. An opening/closing door configured to communicate (66) may be included.

As such, according to the embodiment of the present invention, the heat insulation assemblies 10, 20, 30 have a multi-layer structure, and the vibration-proof assemblies 40 and 50 are disposed between the heat insulation assemblies 10, 20, 30. Accordingly, it is possible to prevent deformation and damage even when a change in the external environment and an impact from the outside are applied, as well as maximize insulation, fire prevention, buffering and sound absorption performance.

In addition, according to the present invention, the indoor space (S) can be partitioned as needed, and the size of the indoor space (S) can be selectively adjusted, so that various presentations are possible according to the needs of the user, thereby utilizing the space. can be maximized.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and it is common in the technical field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Various modifications are possible by those having the knowledge of, of course, these modifications should not be individually understood from the technical spirit or prospect of the present invention.

1. Interior finishing structures
10. First Insulation Assembly
11. Article 1-1 Insulation Panel
111. Multiple Insulation Layers
12. Panel supports
13. Section 1-2 Insulation Panel
14. Section 1-3 Insulation Panel
20. Second Insulation Assembly
21. Article 2-1 Insulation panel
22. Section 2-2 Insulation Panel
23. Section 2-3 Insulation Panel
231. Panel part
2311. Depression
2312. Overhang
232. Press-fit
24. Multiple Fastening Aids
241. Bracket
242. Fixed part
25. Multiple fasteners
26. No. 2-4 Insulation Panel
261. Support
262. Goribu
27. Multiple Insulation Bars
28. No. 2-5 insulation panel
29. Section 2-6 Insulation Panel
30. Third Insulation Assembly
31. Assembly panels, assembly panels
311. Panel body
3111. First body part
3112. Second body part
3113. Buffer Cells, Buffer Cells
F. Fluid
3114. Sealing tube
P. Euro
3115. First magnetic body
3116. Second magnetic body
312. Locking Protrusion
313. Locking groove
32. Bonding Magnets
40. First anti-vibration assembly
41. Article 1-1 Support Panel
42. Section 1-2 support panel
43. Guide shaft
44. Fixture
45. Lee Dong-gu
46. First scissor link assembly
47. Second scissor link assembly
48. A plurality of resilient connectors
50. Second anti-vibration assembly
51. Article 2-1 Support Panel
52. 2-2 support panel
53. Core Spring
54. First sub springs
55. Second sub springs
56. Dustproofs
60. Variable Insulation Assemblies
61. screw shaft
62. Multiple Support Units
63. Shaft Drive Actuator
64. Guide rail
65. Temporary wall
66. Opening and closing door
B. Architecture
S. Indoor space
W. inner wall

Claims (7)

A first insulation assembly installed on the inner wall of the building;
a second thermal insulation assembly spaced apart from the first thermal insulation assembly;
a third thermal insulation assembly spaced apart from the second thermal insulation assembly and having one surface exposed to the indoor space;
disposed between the first heat insulation assembly and the second heat insulation assembly, and configured to elastically support the first heat insulation assembly and the second heat insulation assembly in a direction in which the first heat insulation assembly and the second heat insulation assembly are spaced apart a first anti-vibration assembly;
disposed between the second thermal insulation assembly and the third thermal insulation assembly, configured to elastically support the second thermal insulation assembly and the third thermal insulation assembly in a direction in which the second thermal insulation assembly and the third thermal insulation assembly are spaced apart a second anti-vibration assembly; and
a variable heat insulation assembly configured to adjust the size of the indoor space while moving along an outer surface of the third heat insulation assembly; including,
The first thermal insulation assembly,
a 1-1 heat insulating panel installed on the inner wall, having a plurality of heat insulating layers in a laminated structure, and made of a compressed Styrofoam material;
a plurality of metal panel supports arranged on one surface of the 1-1 insulation panel along the height direction of the inner wall and configured to press the 1-1 insulation panel toward the inner wall;
a 1-2 heat insulating panel made of an elastic material disposed on one surface of the 1-1 heat insulating panel while pressing the panel supports; and
a rock wool 1-3 heat insulation panel disposed on one surface of the 1-2 heat insulation panel and supported by the first vibration-proof assembly; includes,
The second thermal insulation assembly,
a 2-1 heat insulating panel made of a fireproof wood material disposed opposite to the first heat insulating assembly with the first anti-vibration assembly interposed therebetween and supported by the first anti-vibration assembly;
a 2-2 heat-insulating panel made of rock wool disposed on one surface of the 2-1 heat-insulating panel;
a 2-3rd heat insulation panel having a concave-convex structure coupled to the 2-2 heat insulation panel and supported on one surface of the 2-2 heat insulation panel;
a plurality of fastening aids coupled to the second-third thermal insulation panel;
While passing through the plurality of fastening aids and sequentially coupled to the 2-2 heat-insulating panel and the 2-1 heat-insulating panel, the plurality of fastening aids and the 2-3-th heat-insulating panel are moved toward the 2-2 heat-insulating panel. a plurality of fasteners configured to pressurize;
2-4 heat insulating panels made of a metal material coupled to and supported by the plurality of fastening aids;
a plurality of heat-insulating bars made of a compressed Styrofoam material press-fitted between the 2-3rd heat-insulating panel and the 2-4th heat-insulating panel;
a 2-5 heat-insulating panel made of an elastic material disposed on one surface of the 2-4 heat-insulating panel; and
a 2-6th insulation panel made of rock wool supported on one surface of the 2-5 insulation panel and disposed opposite the third insulation assembly with the second vibration insulation assembly interposed therebetween and supported by the second vibration insulation assembly; including,
The 2-3 heat insulation panel,
a panel part having a depression supported on one surface of the 2-2 heat insulation panel and a protrusion spaced apart from one surface of the 2-2 heat insulation panel; and
a press-fitting portion having a wedge structure configured to be supported by being caught by the 2-2 heat-insulating panel while being press-fitted into the 2-2 heat-insulating panel; includes,
The plurality of fastening aids,
a 'C'-shaped bracket supported by the protrusion and configured to accommodate a portion of the plurality of fastening aids and a portion of the 2-4th heat insulation panel therein; and
a fixing part that penetrates through the protrusion and is supported by the protrusion, and configured so that the plurality of fastening aids penetrate therein; including,
The 2-4 heat insulation panel,
a support part in the form of a flat plate for supporting the plurality of heat insulating bars; and
a ring portion accommodated in the bracket portion and configured to be supported by the bracket portion; including,
The third thermal insulation assembly,
assembly panels configured to be coupled to each other along a width direction and a height direction of the inner wall; and
coupling magnets individually inserted into the assembly panels and configured to be coupled to each other by magnetic force when the assembly panels are coupled; including,
The assembly panel,
panel body;
a plurality of locking protrusions disposed at an end of the panel body along the circumference of the panel body and having a hook structure protruding from the end of the panel body to the outside of the panel body; and
a plurality of locking grooves disposed at an end of the panel body along the circumference of the panel body, recessed from the end of the panel body to the inside of the panel body, and having a hook structure corresponding to the locking protrusion;
The panel body,
a first body portion disposed to face the indoor space;
a second body portion disposed to face the second heat insulation assembly and supported by the second vibration-proof assembly;
a buffer cell disposed between the first body part and the second body part, the fluid being filled therein;
It is disposed between the first body part and the second body part and communicates with the buffer cell, and is compressed in the axial direction when the assembly panels are combined to open an internal flow path to mutually connect the buffer cells accommodated in the assembly panels to each other. a sealing tube made of an elastic material configured to communicate;
a first magnetic body accommodated in the first body portion; and
a second magnetic body accommodated in the second body portion and configured to be coupled to the first magnetic body through a magnetic force; Including, interior finishing structures for buildings. delete delete delete According to claim 1,
The first anti-vibration assembly,
a 1-1 support panel attached to and fixedly disposed on the first heat insulation assembly;
a first-second support panel spaced apart from the first-first support panel to support the second heat-insulating assembly and flow together with the second heat-insulating assembly;
a guide shaft disposed between the 1-1 support panel and the 1-2 support panel;
a fixture fixedly disposed on one side of the guide shaft along the axial direction of the guide shaft;
a moving member disposed on the other side of the guide shaft along the axial direction of the guide shaft and slidably movable along the outer surface of the guide shaft;
A first scissor link disposed between the 1-1 support panel and the guide shaft, one side rotatably coupled to the 1-1 support panel, and the other side rotatably coupled to the fixture and the moving member assembly;
A second scissor link disposed between the 1-2 support panel and the guide shaft, one side rotatably coupled to the fixture and the moving member, and the other side rotatably coupled to the 1-2 support panel assembly; and
a plurality of elastic connectors disposed around the guide shaft, connecting the moving member and the fixture to each other, and configured to elastically support the moving member when the moving member is moved away from the fixture; Including, interior finishing structures for buildings. According to claim 1,
The second anti-vibration assembly,
a 2-1 support panel attached to the second insulation assembly and flowing together with the second insulation assembly;
a 2-2 support panel attached to the third insulation assembly and flowing together with the third insulation assembly;
a core spring having a spiral structure disposed in the center between the 2-1 support panel and the 2-2 support panel and elastically supporting the 2-1 support panel and the 2-2 support panel;
first sub-springs spaced apart from the core spring in a radial direction of the core spring and elastically supporting the 2-1 th support panel and the 2-2 th support panel at a plurality of positions;
second sub-springs spaced apart from the first sub-springs along a radial direction of the core spring and elastically supporting the second-first support panel and the second-second support panel at a plurality of positions; and
tubular vibration-proof spheres spaced apart from the second sub-springs along the radial direction of the core spring and elastically supporting the second-first support panel and the second-second support panel at a plurality of positions; Including, interior finishing structures for buildings. A first insulation assembly installed on the inner wall of the building;
a second thermal insulation assembly spaced apart from the first thermal insulation assembly;
a third thermal insulation assembly spaced apart from the second thermal insulation assembly and having one surface exposed to the indoor space;
disposed between the first heat insulation assembly and the second heat insulation assembly, and configured to elastically support the first heat insulation assembly and the second heat insulation assembly in a direction in which the first heat insulation assembly and the second heat insulation assembly are spaced apart a first anti-vibration assembly;
disposed between the second thermal insulation assembly and the third thermal insulation assembly, configured to elastically support the second thermal insulation assembly and the third thermal insulation assembly in a direction in which the second thermal insulation assembly and the third thermal insulation assembly are spaced apart a second anti-vibration assembly; and
a variable heat insulation assembly configured to adjust the size of the indoor space while moving along an outer surface of the third heat insulation assembly; including,
The first thermal insulation assembly,
a 1-1 heat insulating panel installed on the inner wall, having a plurality of heat insulating layers in a laminated structure, and made of a compressed Styrofoam material;
a plurality of metal panel supports arranged on one surface of the 1-1 insulation panel along the height direction of the inner wall and configured to press the 1-1 insulation panel toward the inner wall;
a 1-2 heat insulating panel made of an elastic material disposed on one surface of the 1-1 heat insulating panel while pressing the panel supports; and
a rock wool 1-3 heat insulation panel disposed on one surface of the 1-2 heat insulation panel and supported by the first vibration-proof assembly; includes,
The second thermal insulation assembly,
a 2-1 heat insulating panel made of a fireproof wood material disposed opposite to the first heat insulating assembly with the first anti-vibration assembly interposed therebetween and supported by the first anti-vibration assembly;
a 2-2 heat-insulating panel made of rock wool disposed on one surface of the 2-1 heat-insulating panel;
a 2-3rd heat insulation panel having a concave-convex structure coupled to the 2-2 heat insulation panel and supported on one surface of the 2-2 heat insulation panel;
a plurality of fastening aids coupled to the second-third thermal insulation panel;
While passing through the plurality of fastening aids and sequentially coupled to the 2-2 heat-insulating panel and the 2-1 heat-insulating panel, the plurality of fastening aids and the 2-3-th heat-insulating panel are moved toward the 2-2 heat-insulating panel. a plurality of fasteners configured to pressurize;
2-4 heat insulating panels made of a metal material coupled to and supported by the plurality of fastening aids;
a plurality of heat-insulating bars made of a compressed Styrofoam material press-fitted between the 2-3rd heat-insulating panel and the 2-4th heat-insulating panel;
a 2-5 heat-insulating panel made of an elastic material disposed on one surface of the 2-4 heat-insulating panel; and
a 2-6th insulation panel made of rock wool supported on one surface of the 2-5 insulation panel and disposed opposite the third insulation assembly with the second vibration insulation assembly interposed therebetween and supported by the second vibration insulation assembly; including,
The 2-3 heat insulation panel,
a panel part having a depression supported on one surface of the 2-2 heat insulation panel and a protrusion spaced apart from one surface of the 2-2 heat insulation panel; and
a press-fitting portion having a wedge structure configured to be supported by being caught by the 2-2 heat-insulating panel while being press-fitted into the 2-2 heat-insulating panel; includes,
The plurality of fastening aids,
a 'C'-shaped bracket supported by the protrusion and configured to accommodate a portion of the plurality of fastening aids and a portion of the 2-4th heat insulation panel therein; and
a fixing part that penetrates through the protrusion and is supported by the protrusion, and configured so that the plurality of fastening aids penetrate therein; including,
The 2-4 heat insulation panel,
a support part in the form of a flat plate for supporting the plurality of heat insulating bars; and
a ring portion accommodated in the bracket portion and configured to be supported by the bracket portion; including,
The variable insulation assembly,
a screw shaft disposed on an outer surface of the third heat insulation assembly disposed on one side of the inner wall;
a plurality of support units disposed on the outer surface of the third heat insulation assembly along the longitudinal direction of the screw shaft to rotatably support the screw shaft;
a shaft drive actuator configured to rotate the screw shaft;
a guide rail disposed on an outer surface of the third heat insulation assembly disposed on the other side of the inner wall;
It is disposed in the indoor space, a part is coupled to the screw shaft, and the other part is coupled to the guide rail, and when the screw shaft is rotated, the screw shaft and the guide rail are moved along each axial direction of the indoor space. a temporary wall configured to partition the space into a plurality of spaces; and
and an opening/closing door disposed on the temporary wall and configured to selectively open and close the temporary wall to selectively communicate a plurality of spaces partitioned by the temporary wall.

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