KR20140000599U - Drywall insulation structure - Google Patents

Abstract

In addition, the present invention provides a heat insulating material panel (an inserting space is formed on an upper longitudinal side of the heat insulating panel part, and at least one supporting bar is inserted into the inserting space so as to partition the inserting space into a plurality of inserting spaces); And vacuum insulators each having a size corresponding to the partitioned insertion space and inserted into the partitioned insertion space, wherein inner side surfaces of the insertion space each have a first fixed And a second fixing groove facing the first fixing groove is formed in each of the side surfaces of the supporting bar, and each of the opposite side portions of the vacuum insulating member is formed in the first fixing groove and the second fixing groove, And is fixedly inserted into the heat insulating structure. Such a dry wall insulation structure can be easily assembled and installed on the wall surface while protecting the vacuum insulator part. The dimensional error of the vacuum insulator part can be compensated while keeping the vacuum insulator part fixed in the insulator panel part, Thereby improving thermal insulation performance by preventing thermal bridging phenomenon.

Description

{DRYWALL INSULATION STRUCTURE}

The present invention relates to a drywall insulation structure, and more particularly, to a drywall insulation structure capable of easily installing a vacuum insulation material while protecting the vacuum insulation material and improving the heat insulation performance.

Oil prices are steadily rising and greenhouse gas emissions are increasing. As a result, attempts have been made to improve energy efficiency. In particular, the need for energy saving in buildings has been emphasized from an economic point of view. In this situation, a vacuum insulation material having a performance 10 times better than that of the existing insulation material has been developed.

In addition, the vacuum insulator is attached to the concrete wall surface after the adhesive is applied to the back surface. In addition, the outer surface of the vacuum insulation is provided with a finishing material coupled to the C-shaped stud or additional insulation.

However, there is a possibility that the vacuum insulation material is separated from the concrete wall when the application is performed in a state where the adhesive amount is insufficient or the temperature is relatively high, such as during the summer season. Also, when the above-mentioned vacuum insulation material is applied to the wall surface, an external impact is applied to the surface of the vacuum insulation material, thereby damaging the vacuum insulation material. As a result, there is a problem that the heat insulation efficiency is lowered even if the vacuum insulation material is applied to the wall surface.

The present invention provides a drywall insulation structure that can be easily installed on a wall without damaging the vacuum insulation.

The present invention also aims to provide a drywall insulation structure that can be easily assembled and stably accommodate a vacuum insulator.

In addition, the present invention aims to provide a drywall insulation structure capable of preventing heat bridging phenomenon and improving the heat insulation performance.

In addition, the present invention has a heat insulating panel portion (an inserting space is formed on an upper longitudinal side surface of the heat insulating panel portion); And a vacuum insulator which has a size corresponding to the insertion space and is inserted into the insertion space, wherein a fixing groove is formed in the inner side surfaces of the insertion space along the inner side surface of the insertion space, And each of both side portions of the heat insulating portion is inserted and fixed in the fixing groove.

In addition, the present invention provides a heat insulating material panel (an inserting space is formed on an upper longitudinal side of the heat insulating panel part, and at least one supporting bar is inserted into the inserting space so as to partition the inserting space into a plurality of inserting spaces); And vacuum insulators each having a size corresponding to the partitioned insertion space and inserted into the partitioned insertion space, wherein inner side surfaces of the insertion space each have a first fixed And a second fixing groove facing the first fixing groove is formed in each of the side surfaces of the supporting bar, and each of the opposite side portions of the vacuum insulating member is formed in the first fixing groove and the second fixing groove, And is fixedly inserted into the heat insulating structure.

The upper longitudinal side surface of the vacuum insulator inserted into the insertion space is positioned below the upper longitudinal side surface of the heat insulating panel part. The heat insulating panel part protrudes from the lower longitudinal side surface of the heat insulating panel part, and corresponds to the cross- Wherein the heat insulating structure further comprises an engaging projection having a transverse cross-section.

The heat insulating panel part may include: a side coupling groove formed on one longitudinal side surface of the heat insulating panel part; And a side coupling protrusion formed on the other longitudinal side surface of the heat insulating panel part and having a shape corresponding to the side coupling groove.

Further, the thermal insulating panel part further includes boundary parts formed on one side of at least the thermal insulation panel part along both longitudinal side surfaces of the vacuum thermal insulator part.

The drywall insulation structure according to the present invention has the following effects.

(1) The drywall insulation structure according to the present invention includes a heat insulating panel part and a vacuum thermal insulating part, and the vacuum thermal insulating part is inserted into the inserting space of the heat insulating panel part. That is, the vacuum insulator portion can be installed on the wall surface while being protected by the heat insulating panel portion. Therefore, the drywall thermal insulation structure according to the present invention has an effect of being easily assembled and being installed on the wall surface while protecting the vacuum thermal insulating part.

(2) Fixing grooves are formed in the heat insulating panel part of the drywall insulation according to the present invention. Both side portions of the vacuum insulator portion inserted into the insertion space are inserted into the fixing grooves, respectively. At this time, the vacuum insulator portion remains fixed in the insertion space. Therefore, the drywall insulation structure according to the present invention has an effect that the vacuum insulation panel portion is kept fixed in the inside of the heat insulation panel portion and the dimensional error of the vacuum insulation panel portion is compensated.

(3) In the heat insulating panel portion of the drywall insulation according to the present invention, a coupling projection, a side coupling groove and a side coupling projection are formed. The coupling protrusions are inserted into the insertion space of the drywall insulation structure located at the lower side to couple the drywall insulation structures and the side coupling protrusions are inserted into the side coupling grooves of the adjacent drywall insulation structure in the right and left arrangement to join the drywall insulation structure do. At this time, the thermal perfusion value between the drywall insulation structures is reduced. Therefore, the drywall thermal insulation structure according to the present invention has an effect of preventing thermal bridging phenomenon and improving the heat insulating performance.

(4) Boundaries are formed on the heat insulation panel portion of the drywall insulation according to the present invention. The position of the vacuum insulator inserted into the interior of the heat insulating panel part through the boundaries can be confirmed. Therefore, the drywall insulation structure can be installed on the wall surface in consideration of the position of the vacuum insulator. Therefore, the drywall insulation structure according to the present invention has an effect of preventing the damage of the vacuum insulator in the process of being installed on the wall.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a dry wall insulation structure according to a preferred embodiment of the present invention. FIG.
FIG. 2 is a perspective view showing a part of the drywall insulation structure shown in FIG. 1 in an assembled state.
FIG. 3 is a plan view showing a state in which the drywall insulation structure shown in FIG. 1 is coupled.
FIG. 4 is a longitudinal sectional view showing a state in which the drywall insulation structure shown in FIG. 1 is coupled.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 is a perspective view of a dry wall insulation structure 100 according to a preferred embodiment of the present invention. FIG. 2 is a cross-sectional view of a dry wall insulation structure 100 shown in FIG. FIG. 3 is a plan view showing a state in which the drywall thermal insulation structure 100 shown in FIG. 1 is coupled, and FIG. 4 is a perspective view showing a state in which the drywall thermal insulating structure 100 shown in FIG. .

1 to 4, another drywall insulation structure 100 according to a preferred embodiment of the present invention includes a heat insulation panel portion 101 and a vacuum insulation panel portion 102, So as to function as a heat insulating material of the building.

An insertion space 101a is formed in an upper longitudinal section of the heat insulating panel part 101 and a supporting bar 111 is inserted in the insertion space 101a. As a result, the support bar 111 divides the insertion space 101a into a plurality of parts. At this time, the supporting bar 111 is also inserted into the insertion space 101a during the manufacturing process of the heat insulating panel part 101. [ Generally, the heat insulating panel portion 101 is formed in a plate shape.

A first fixing groove 101b is formed in the inner side surfaces of the insertion space 101a and a second fixing groove 111a is formed in the side surfaces of the supporting bar 111 respectively. At this time, the first fixing groove 101b and the second fixing groove 111a face each other. Further, the heat insulating panel portion 101 can be made of various materials, for example, foamed polystyrene and the like.

In the present embodiment, one support bar 111 is inserted into the insertion space 101a to divide the insertion space 101a into two, but the present invention is not limited thereto, and the support bars 111 The insertion space 101a can be inserted into the insertion space 101a in various numbers in parallel to divide the insertion space 101a into various numbers. Further, the support bar 111 may not be inserted into the insertion space 101a.

The vacuum insulator portions 102 are inserted into the insertion spaces 101a partitioned by the support bars 111, respectively. In addition, the vacuum insulator portions 102 have a number corresponding to the number of divided spaces of the insertion space 101a, and have a size corresponding to the divided size of the insertion space 101a. On the other hand, when the insertion space 101a is not partitioned by the support bar 111, only one vacuum insulator 102 corresponding to the insertion space 101a is required.

Both side portions of the vacuum insulator 102 inserted into the insertion space 101a are inserted and fixed in the first fixing groove 101b and the second fixing groove 111a, respectively. At this time, the first fixing groove 101b and the second fixing groove 111a are equal in size to each other, and preferably correspond to the thickness of the vacuum insulator 102. The vacuum insulator 102 is stably inserted into the insertion space 101a in the insertion space 101a and can be protected by the heat insulator panel 101. [ In addition, the dimensional error of the vacuum insulator 102 with respect to the insertion space 101a can be compensated.

The upper vertical side surface of the vacuum thermal insulator 102 inserted into the insertion space 101a is located below the upper vertical side surface of the heat insulating panel part 101. [ The upper vertical side surface of the support bar 111 is located on the upper side or in the same plane as the upper vertical side surface of the vacuum thermal insulator 102 inserted in the insertion space 101a and is located below the upper vertical side surface of the heat insulating panel part 101 Positioned or coplanar.

The vacuum insulator 102 as described above is manufactured by enclosing a plurality of thin films on the outside of the porous core material and sealing the inside of the porous insulation material to reduce the pressure therein, and is formed into a plate shape. The vacuum insulator portion 102 is made of a soft material and can be easily deformed.

Meanwhile, a coupling protrusion 113 is formed on the heat insulating panel part 101 of the drywall thermal insulation structure 100 of the present invention. The engaging projection 113 protrudes from the lower longitudinal side surface of the heat insulating panel portion 101 and has a cross section corresponding to the cross section of the insertion space 101a. In the state where the drywall insulation structures 100 are arranged in the vertical direction, the engagement protrusions 113 of the drywall insulation structure 100 located on the upper side are inserted into the insertion spaces 101a of the drywall insulation structure 100 positioned below As shown in Fig. At this time, the support bar 111 and vacuum insulator portions 102 of the drywall insulation structure located at the lower side are closed, and the gaps between the drywall insulation structures 100 are also closed. This allows the drywall insulation structures 100 to remain stably coupled to each other and prevent heat from flowing intensely between the drywall thermal insulation structures 100. [

Further, the heat insulating panel portion 101 further includes a side coupling groove 115 and a side coupling protrusion 117. [ The side coupling grooves 115 are recessed at one longitudinal end face of the heat insulating panel part 101 and the side coupling protrusions 117 are protruded at the other longitudinal end face of the heat insulating material panel part 101. The side coupling moles 115 and the side coupling protrusions 117 are of mutually corresponding shapes and can be engaged with each other. The side wall coupling protrusions 117 of the drywall thermal insulation structure 100 are inserted into the side coupling grooves 115 of the adjacent drywall thermal insulation structure 100 with the drywall thermal insulation structures 100 arranged in the left- So that the drywall insulation structures 100 can be stably coupled to each other. In addition, the gaps between the drywall insulation structures 100 can be closed, preventing heat from flowing intensely between the drywall thermal insulation structures 100.

Simulation of the heat conduction rate of the dry wall insulation structure was performed to confirm the heat insulating performance of the side wall engaging groove 115 and the side wall engaging protrusion 117 of the heat insulating panel part 101. The embodiment is an example of combining the drywall insulation structures 100 to which the side coupling grooves 115 and the side coupling projections 117 are applied to the heat insulating panel portion 101. The comparative example is an example in which the side coupling grooves 115, And the drywall insulation structures 100 in which the side wall coupling projections 117 and the side wall coupling projections 117 are not applied. In order to evaluate the heat insulating performance according to the examples and the comparative examples, the heat conduction rates of the respective examples were measured. Here, heat flow refers to a phenomenon in which heat is transferred from the air layer to the air layer through a solid such as a wall, and the heat conduction rate means a heat amount flowing when the cross-sectional area of 1 m 2 is at a temperature difference of 1 K per unit time. The results of the simulation of the heat transfer rate are shown in Table 1.

Thermal Permeability (W / ㎡K) Example (side engagement groove and side engagement projection are applied) 0.161 Comparative Example (side engagement groove and side engagement projection are not applied) 0.181

According to Table 1, the comparative example in which the side coupling grooves 115 and the side coupling projections 117 are not applied has a heat conduction rate of 0.181 W / m < 2 > K while the side coupling grooves 115 and the side coupling projections 117, Has a heat conduction rate of 0.161 W / m < 2 > K. If the value for the heat conduction rate is small, it means that the adiabatic performance is relatively good. Accordingly, the drywall thermal insulation structure 100 according to the present invention, in which the drywall thermal insulation structures 100 are coupled using the side coupling grooves 115 and the side coupling projections 117, Improves the ability to block.

In addition, boundary portions 119 are formed in the heat insulation panel portion 101 of the drywall insulation structure 100 of the present invention. The boundary portions 119 are formed along both longitudinal side surfaces of the vacuum insulator portion 102 inserted into the insertion space 101a on one surface of the heat insulating panel portion 101. [ At this time, the positions of the vacuum insulator parts 102 can be confirmed inside the heat insulating material panel part 101. Accordingly, when the drywall thermal insulation structure 100 is installed on the wall surface, various additional materials such as screws, nails, and the like can be coupled to the heat insulating panel portion 101 while being spaced from the vacuum thermal insulating portions 102. That is, damage of the vacuum insulator 102 due to the accessory material can be prevented in the process of installing the drywall insulation 100 on the wall. The boundary portion 119 may be formed on the heat insulating panel portion 101 in the form of a groove, a projection, a mark, or the like.

While the present invention has been described in connection with certain exemplary embodiments, it will be understood by those skilled in the art that various changes may be made without departing from the scope of the present invention. In addition, the description in the parentheses in the description of the utility model registration claim is intended to prevent the ambiguity of the description, and the scope of the right of utility model registration claim should be interpreted to include all the items in parentheses.

100: Drywall insulation
101: Insulation panel section
101a: Insertion space
101b: a first fixing groove
111: support bar
111a: second fixing groove
113: engaging projection
115: side coupling groove
117: Side coupling projection
119:
102: vacuum insulator part

Claims (5)

An insulator panel portion (an inserting space is formed on an upper longitudinal side surface of the heat insulating panel portion); And
A vacuum insulator having a size corresponding to the insertion space and inserted into the insertion space,
Fixing grooves are formed in the inner side surfaces of the insertion space, respectively, along the inner side of the insertion space, each of the both sides of the vacuum insulator portion is a drywall insulating structure, characterized in that the insertion groove is fixed.
An insulator panel portion (an inserting space is formed on an upper longitudinal side of the heat insulating panel portion, and at least one supporting bar is inserted into the inserting space so as to partition the inserting space into a plurality of inserting spaces); And
And vacuum insulator portions having a size corresponding to the partitioned insertion space and inserted into the partitioned insertion spaces, respectively,
A first fixing groove is formed in the inner side surfaces of the insertion space along an inner side surface of the insertion space, and a second fixing groove, which faces the first fixing groove, ,
Each of the both sides of the vacuum insulator portion is a drywall insulating structure, characterized in that inserted into and fixed to the first fixing groove and the second fixing groove.
3. The method according to claim 1 or 2,
The upper longitudinal side surface of the vacuum insulator portion inserted into the insertion space is positioned below the upper longitudinal side surface of the heat insulating panel portion,
The heat insulation panel part,
And a coupling protrusion protruding from a lower longitudinal section of the insulation panel and having a cross section corresponding to a cross section of the insertion space.
The heat insulating panel unit according to claim 1 or 2,
A side coupling groove formed on one longitudinal side surface of the heat insulating panel part; And
Further comprising a side coupling protrusion protruding from the other longitudinal side surface of the heat insulating panel part and having a shape corresponding to the side coupling groove.
The heat insulating panel unit according to claim 1 or 2,
Further comprising boundary portions formed along both longitudinal side surfaces of the vacuum thermal insulator portion on at least one surface of the heat insulating panel portion.

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