KR101469147B1 - V.I.Pin - Google Patents

Abstract

The present invention provides a method for manufacturing a Vipin and a Vipin comprising a Vipin, a Vipin bottom cover and a pressing cover, a Vipin corner bracket, and a Vipin cap for attaching a vacuum insulating material to a structure of a building, V-Ipin is a subsidiary material developed to enable vacuum insulation to be applied at the construction site, so that standardized vacuum insulation adheres to the structure and can be easily installed without damaging the skin, ultimately contributing to energy savings by using vacuum insulation. . This Vipin is applied to the standard construction method of vacuum insulation material, so that vacuum insulation material has been developed so that it can be widely applied as a built-in insulation material in a construction site.

Description

V.I.Pin}

The present invention relates to a vacuum insulated pin (VIPin) for fixing a vacuum insulation material to a building structure.

Efforts are underway to reduce carbon emissions in order to preserve the environment of the earth, and various measures for reducing energy related to carbon emission reduction in Korea are being studied. These energy saving measures are being studied in various fields. In the construction field, various energy saving houses or buildings such as Green Energy House, Zero Energy House, and Passive House are planned in accordance with government policies.

There are many ways to save energy in a house or a building. However, it is a common practice to reduce energy by minimizing internal and external thermal bridges in buildings using high-efficiency insulation. Among the heat insulation materials developed so far, vacuum insulation Since the thermal conductivity coefficient of the gas is almost zero, it can be said that the heat insulating effect is the most excellent. However, since the vacuum insulation material is manufactured / manufactured and shipped to a certain standard in a factory that produces the insulation material, it is very difficult to construct the vacuum insulation material because it is impossible to process or cut according to the conditions of the site. Considering the characteristics of the vacuum insulation material, the present invention is intended to make the vacuum insulation material widely used by developing subsidiary materials so that the vacuum insulation material can be more easily applied in the field. The main prior art documents related to vacuum insulator fixtures are as follows. Korean Patent Registration No. 10-2006-0042558 (May. 15, 2006) Insulation Wall Fixture, Korea Practical Registration No. 2004481230000 (2010.3.10.) Binder for wall plate, Korea Practical Registration No. 2004544640000 (June 29, 2011) Insulation fixture.

Since vacuum insulation is produced to maintain vacuum, it can not be processed, cut, etc. after it is produced in a certain standard in the factory. In addition, special finishing materials are used to maintain the vacuum of the insulation, but the adhesive that can be used for the finishing material (skin) of the vacuum insulation is very limited. Because of these vulnerabilities, it was very difficult to use them universally in the construction sites of various construction sites.

Accordingly, a problem to be solved by the present invention is to develop an auxiliary material which can be adhered to a construction surface to be insulated without processing or cutting the vacuum insulation material produced in a certain standard in the field, and another problem is to develop a vacuum insulation material To develop a subsidiary material capable of supporting the finishing material without using a direct adhesive.

The present invention provides a method for bonding a V-pin, a V-pin, a V-pin bottom cover and a pressing cover, a V-pin corner bracket, and a V-pin cap for attaching a vacuum insulation material to a structure of a building.

This V-Ipin is a subsidiary material developed to make vacuum insulation more easily at the construction site. It can attach the standardized vacuum insulation to the surface to be installed and attach the finishing material to the surface of the vacuum insulation without using the adhesive directly. So that the vacuum insulation material can be used in a general manner so that the vacuum insulation material can be fully utilized. Therefore, this V-Ipn is applied to the standard construction method of vacuum insulation material, so that vacuum insulation material can be widely applied as a built-in insulation material in a construction site.

BRIEF DESCRIPTION OF THE DRAWINGS Fig.
Fig. 2 is a perspective view of a V-neck padded cover and a push cover according to the present invention.
Fig. 3 is a perspective view of the Vipipin corner bracket according to the present invention.
Fig. 4 is a diagram showing the stereoscopic view of the V-
FIG. 5 is a graph showing the relationship between the volume

The Via Ipin of the present invention is an auxiliary material for attaching a vacuum insulation material to a building structure and includes a Via pin bottom plate 20 and a strut 10, a bottom cover 40 and a push cover 30, a corner bracket 50, And a cap 60. Each of the constituent elements will be described concretely with reference to Figs. 1 to 4, respectively, as follows.

The Vipin bottom plate 20 and the spigot 10 of the present invention are characterized in that the vacuum insulator is fixed by attaching the square insulator or the rectangular insulator to the square corners of the vacuum insulator so as to be closely attached thereto, to be. The bottom plate of the present invention can be modified into various shapes in accordance with the characteristics of the structural components of the building and the components of the adhesive.

The Vipin bottom plate 20 and the support platform 10 are supported by the bottom plate portion 21, the rib fins 16, the lower column 15, the binding key 14, the column 13, the tapered head 12, And a head 11. The V-shaped bottom plate 20 is a bottom portion for allowing the adhesive to harden through a plurality of through holes to attach a vacuum pin to a structure such as a concrete wall of a building. The bottom portion includes a bottom plate portion 21, And an adhesive passage hole formed in the plate portion. The shape of the bottom plate 21 and the shape of the through hole may be variously modified in accordance with the components of the adhesive, the amount of the adhesive used, and the like. V Ipin Ribsall (16) is the part to reinforce the bending of the vacuum pin column and bottom plate. The Vipin pillars 10 are connected and fixed to the bottom plate portion 21 by ribs 16 formed on the lower column 15 as a portion for fixing the vacuum insulation material, A binding key 14 to which the lid 40 is bound is formed. The Vipin column 13 is a part where the vacuum insulation is joined, and the column of the vacuum insulation panel is formed in a " + " . A portion of the tape head 12 is placed on the top of the " + " type column to reinforce the adhesion between the Vipin cap 60 and the vacuum insulation cap 30. The Vipin tape head 12 is a part for enhancing the adhesion while the Vipin cap 60 is tied and the Vipin head 11 is a part where the Vipin cap 60 is bonded. In addition, the V-Ipin head facilitates bonding with the Vipin cap 60, and constitutes a groove and a rim ring for preventing the Vipin cap 60 from falling off.

In the V-Ipin bottom cover 40 and the push-cover 30, the bottom cover 40 prevents the bond, which has hardened through the V-pin bottom plate 20, from damaging the surface of the vacuum insulator, and a vacuum insulator And the pressing cover 30 is arranged so as to be able to secure the vacuum insulation material by the binding force of the vacuum pin cap 60 so as not to be detached (conducted) without damaging the surface of the vacuum insulation material placed on the V- .

The Vipin bottom cover 40 and the push cover 30 are composed of a rib flesh 31, an outer rim 32, a keyhole 41, and a center hole 42. The Vipin bottom cover 40 is designed to be coupled to the vacuum fin bottom plate 20 with the inner space facing downward to serve as a protective cover for protecting the vacuum insulation material. The bottom cover 40 has an outer edge Prevents the bottom cover from being warped, and prevents the adhesive that has passed through the Vipin bottom plate from being excessively diffused. The ribs 16 are reinforced to prevent the bottom cover 40 and the push cover 30 from being bent and the outer frame 32 prevents the adhesive from spreading and is in close contact with the bottom plate 20 or the cap 60. [ And the keyhole 41 is a part coupled to the Vipin lower binding key 14 and the bottom cover passing through the Vipin pillars is made to be easily attached to the binding key at the lower end of the Vipin pillars. The center hole 42 is a portion through which the V-shaped pillars 13 can pass.

The Vipin Ion corner bracket 50 is formed in a state in which the Vipin bottom plate, the support bar, and the cap 60 are attached to the curved corner portion, the corner portion, the opening portion, and the like of the Vipin pin, It is a configuration that performs a role.

The Vipin corner bracket 50 is constituted by a bracket cap 51, a pushing lid 52, a column plate 53, a bottom lid 54, a bottom post 55 and a bottom plate 56, 51 is a cap part to which the built-in finishing material can be attached, the structure of which is the same as that of the Vipin cap 60. The pressing cover 52 is a lid part for preventing fall of the vacuum insulation material, The bottom cover 54 is a lower end portion in which the vacuum insulation is placed and the bottom column 55 is a bottom portion of the bottom cover 54 and the bottom plate 56 And the bottom plate 56 is a bottom portion for allowing the adhesive to harden through the plurality of through holes to attach the vacuum pin to the concrete wall. A bottom cover 54 is placed to protect the vacuum insulation from the adhesive that has passed through the corner bracket bottom plate 56. Three bottom posts 55 are provided to allow the adhesive to solidify and prevent the bottom cover from sinking I have. The number of floor pillars can be varied depending on the type of V Ipin material and the structure of the building to which it is attached. It is preferable that the column plate 53 corresponding to the vacuum pin column portion is constructed in a plate shape so as to continuously support the bottom lid 54 and the press lid 52 for the performance and construction of the corner bracket, The cap 60 may be formed in a semicircular shape in consideration of the fact that it is used for corner portions and corner portions of a curved portion.

The BIPPIN cap (60) of the present invention is configured to bind to the Vipin head (11), press the vacuum insulation cover (30), and hold the vacuum insulation.

The VF cap 60 of the present invention is constituted by a bond hole 61, a key plate portion 62, an elastic piece 63, a rib 64 and an outer ring 65. The elastic piece 63 is connected to the vacuum pin head 11 (see FIG. 1). The elastic pin 63 is connected to the vacuum pin head 11 4 to 10 elastic pieces 63 are provided so that they can be attached to each other, and the cap 60 is designed so as not to fall off during the binding. The number of the resilient pieces 63 can be varied according to the kind of the material of the BIPPIN. The rib 64 is a portion reinforced so that the vacuum pin cap 60 is not bent, and the outer ring 65 is a structure for retaining the shape and preventing warpage of the vacuum pin cap.

The Vipin cap 60 is constructed so that the binding is easy due to the Vipin head and the elastic piece 63, and the binding is not removed afterwards. The Vipin cap 60 is configured to be adhered within the thickness of the Vipin cap 60 to minimize the gap between the vacuum insulation material and the built-in finishing material first applied to the building structure, and the bond hole 61, the key plate part 62, The ring 65 can be appropriately modified within the range of the functions and actions of each constitution.

The physical properties of the Vpi according to the present invention include polypropylene (PP), poly ethylene (PE), high density poly ethylene (HDPE), low density poly ethylene (LDPE), polyvinyl chloride (PVC) ABS (Acrylonitrile Butadiene Styrene) and other materials that can exhibit a certain strength or more can be used. Therefore, it can be manufactured using general thermoplastic resin material. By the curing of the vacuum insulation material construction structure and the bonding agent of the building, It is not limited to plastics, but can be adopted.

As the adhesive used for bonding the V-pin of the present invention to the vacuum insulation panel construction structure of the building, a known adhesive capable of bonding the V-pin to the structure may be used. As the preferable adhesive, a vinyl acetate liquid resin adhesive or an epoxy bond Can be used. The preferred adhesive of the present invention is preferably 2 to 3 days with a proper hardness. However, it is possible to select an appropriate adhesive according to the type of concrete structure such as wall, floor, ceiling, and outside of the building.

The technical structure of the V-pin installation method of the present invention will be described with reference to FIG. First, the Vipin of the present invention bonds the bottom plate 21 to the building structure on which the vacuum insulation material is installed by using an adhesive.

The one-step coupling is the step of joining the Vipin bottom plate 20 and the Vipin bottom cover 40 together. The bottom cover 40 is covered with the V-shaped pillars 10 to which the bottom plate 20 is bonded. The bottom cover 40 serves to prevent the adhesive material, which has risen through the adhesive passage hole formed in the bottom plate portion, from coming into contact with the vacuum insulation material. The two-step bonding is a step of placing the vacuum insulation material on the bottom cover 40 after the one-step bonding and then joining the Vipin and the push cover 30 together. A vacuum insulator is positioned between the bottom cover 40 and the push cover 30. The three-step coupling is the step of binding the Vipin and Vipin cap 60 together. The step of bonding the I / F in one to three steps is as shown in FIG.

(10)
(11) Head
(12) Tapered head
(13) Columns
(14) Binding key
(15) Lower column
(16) Liv
(17)
(20)
(21)
(30)
(31) Rib live
(32) Outer frame
(40) Floor cover
(41) Keyhole
(42) center hole
(50) Corner bracket
(51) Bracket cap
(52)
(53)
(54) floor cover
(55) Floor column
(56)
(60) Vipin cap
(61) Bond hole
(62)
(63)
(64) rib
(65) Outer ring
Ⅰ. Combine 1 step
Ⅱ. Two-step combination
Ⅲ. Combine three steps

Claims (10)

A bottom plate 20 attached to a concrete wall structure of a building using an adhesive, a vacuum insulation material being adhered and fixed to the bottom plate 20 while being connected and fixed, a bottom cover 40, The support frame 10 for fixing the pressing cover 30 is coupled with the vacuum fin bottom plate 20 through the support bar 10 with the inner space facing downward and has an outer frame to prevent warpage, A push cover 30 passing through the support column 10 with its inner space facing upward to prevent the vacuum insulation from being dropped off on the bottom cover 40; And a cap 60 for pressing the pressing lid 30 by binding the vacuum pin head 11 with the resilient piece 63. The vacuum insulation material is attached to the building structure. The support column (10) according to claim 1, wherein the support column (10) comprises a vacuum pin column (13) and a rib plate (16) for reinforcing the bending of the bottom plate (20) And a vacuum pin bottom cover 40. The vacuum punch 14 is formed on the lower pillar 15 and the vacuum fin bottom cover 40 is fixed to the bottom pillar 15. The pillar peripheral slope faces the pit And a head 11 to which a tapered head 12 and a Vipin cap 60 are coupled to reinforce the adhesion between the Vipin cap 60 and the vacuum insulation cap 30. V Ipin attaches vacuum insulation to building structures. The floor cover (40) according to claim 1, wherein the bottom cover (40) comprises a keyhole (41) coupled with the Vipin lower binding key (14) and a central hole (42) through which the Vipin pillars (13) Wherein the vacuum insulating material is securely placed on the top surface of the bottom cover (40) so that the hardened bond passing through the portion (21) does not damage the surface of the vacuum insulating material. The presser foot according to claim 1, characterized in that the presser lid (30) comprises a rib (31) reinforced to prevent the presser lid (30) from being bent and an outer rim (32) And the vacuum insulator is caught by the binding force of the vacuum pin cap (60) so as not to be detached without damaging the surface of the vacuum insulation material placed on the V-Ipin bottom cover (40) I-pin. A Vipinpin corner bracket (50) for applying a Vipin pin according to claim 1 to a curved corner part, a corner part and an opening part of a wall, comprising: a bracket cap (51) to which a built-in finishing material can be attached; A bottom plate 54 for holding the vacuum insulation material thereon and a bottom plate 55 for maintaining the gap between the bottom plate 54 and the bottom plate 56 ), A bottom plate (56) for hardening the adhesive through a plurality of through holes to attach a vacuum pin to the concrete wall, and a Vipin cap is semicircular so as to be used for corner portions and corner portions. V Ipin corner bracket attaching vacuum insulation to building structure. The cap (60) according to claim 1, wherein the cap (60) comprises: a bond hole (61) for allowing the gypsum bond to penetrate and harden; a key plate (62) formed to have a larger area than the ribs to prevent the hardened gypsum bond from falling off; A resilient piece 63 that is easy to insert on the head and prevents the cap from falling off during binding, a rib 64 that is reinforced so that the vacuum pin cap 60 is not bent, And an outer ring (65). The elastic piece (63) is provided with 4 to 10 elastic pieces so as to be easily attached to the vacuum pin head (11) so that the vacuum insulator can be attached to the building structure V Ipin to. Claim 2 is characterized in that the pillar (13) is formed in a " + " shape with respect to a front view of the pillar (13) To the V-pin.
The method of any one of claims 1 to 7, wherein the Vipin is selected from the group consisting of Polypropylene (PP), Poly Ethylene (PE), High Density Poly Ethylene (HDPE), Low Density Poly Ethylene (LDPE), Poly Vinyl Chloride ), PC (Poly Carbonate), ABS (Acrylonitrile Butadiene Styrene), which attaches vacuum insulation to a building structure. A first structure for bonding a Vipin bottom plate 20 and a Vipin bottom cover 40 to each other by adhering a Vipin bottom plate 20 to a concrete wall structure of a building using an adhesive to a building structure on which a vacuum insulation material is installed, A second step of placing the vacuum insulation material on the bottom cover 40 after the first step and then joining the push cover through the V-shaped pillars 13 connected to the bottom plate 20, And a third step of attaching a vacuum insulator to a building structure The method according to claim 9, wherein the adhesive is a vinyl acetate-based liquid resin adhesive, and attaching the vacuum insulator to a building structure.

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