KR102107549B1 - Container with vacuum insulation panel - Google Patents

Abstract

The present invention provides an insulated container comprising: a body consisting of an outer body (110) and an inner body (120); and a lid provided on the upper side of the body. The outer body and the inner body have a hexahedral shape with an upper surface open. The inner body is disposed inside the outer body. Each side of the inner body and the outer body is spaced apart by a first interval (D1) to form a side space (S1), and each bottom of the inner body and the outer body is spaced apart by a second gap (D2) to form a bottom space (S2). The upper end of the inner body is placed in contact with the upper end of the outer body, and a vacuum insulation material is disposed in the side space (S1) and the bottom space (S2).

Description

Insulation container with built-in vacuum insulation material {CONTAINER WITH VACUUM INSULATION PANEL}

The present invention relates to an insulated container incorporating a vacuum insulation material, and relates to a container box that has a heat-insulating or heat-insulating sealed space by blocking heat transfer between inside and outside using a vacuum insulation material, and specifically, It relates to an insulating container that maximizes the internal and external insulation effect by separating it to the outside and then placing a vacuum insulation material between these walls.

With the development of distribution technology, the logistics industry that transports or transports goods over a long distance develops, and the demand for transport of various goods is increasing. Refrigerated or frozen products, such as food, aquatic products, vegetables, and fruits, where freshness is directly related to the quality of the product, can be easily deteriorated during transportation or transportation. In order to maintain insulation, a cold storage technology inside the box is required to keep the inside of the packing box at a constant temperature.

Conventionally, a cold storage box accommodates an article that requires cold storage together with a refrigerant inside the box, and the wall adopts a structure for thermal insulation. An example of the prior art for such a cold box is Patent No. 10-1910860 (October 17, 2018). Looking at the prior art, the lower insulation member 140, the side insulation member 150, the upper insulation member 160, etc. are arranged on the wall inside the wall forming the cold storage box, and the cooling member 190 is provided therein. Is the way to do it.

However, such a cold box of the prior art has a problem that the insulating members, which play an important role in exerting the insulating performance, are separated, and the insulating box structure is very complicated and does not properly exhibit the insulating performance. It was necessary to improve the technology.

An object of the present invention is to provide a technique for maximizing the performance of insulating the space inside the container from the outside by placing the vacuum insulating material between the inner body and the outer body of the insulating container.

The present invention is composed of a body composed of an outer body 110 and an inner body 120, and a lid provided on the upper side of the body, wherein the outer body and the inner body have a hexahedral shape with an upper surface open, and the inner body It is disposed inside the outer body, and the side surfaces of the inner body and the outer body are spaced apart by a first distance D1 to form a side space S1, and the bottom surface of each of the inner body and the outer body is a second distance D2. ) To form a floor space (S2) spaced apart, the upper end of the inner body is placed in contact with the upper end of the outer body, the side space (S1) and the floor space (S2) is provided with an insulating container in which a vacuum insulating material is disposed do.

The vacuum insulating material has a shape of two sheets overlapped in a floor space in a cross shape, and each of the two vacuum insulating materials 200 and 300 includes a bottom portion positioned in the floor space S2 and the side space extending to both sides of the bottom portion ( It consists of a side portion located in S1), the side portion has a larger trapezoidal shape of the outer end.

It is formed by increasing the thickness at the upper edge of the outer body, the outer body fastening portion 115 is provided with a screw hole (118); It is formed by increasing the thickness at the upper edge of the inner body, and is combined with the outer body fastening part, but the inner body fastening part 125 is not formed with a screw hole: fastened from the bottom to the screw hole 118. , The tip portion may further include a screw 119 buried in the inner body fastening portion 125.

The vacuum insulating material 400 may be disposed in the side space (S1) and the bottom space (S2), in another form, while a single vacuum insulating material is folded to form an open-sided cube.

That is, the vacuum insulating material 400, the first member 410 of a rectangular shape forming the bottom of the cube; A second member (420,430) arranged to be folded on two opposite sides of the first member rectangle to form a long side surface of the cube; A third member (421, 422, 431, 432) extending from each side of each of the second members (420, 430) to form a short side of the cube; And a fourth member (440,450) that is disposed to be folded on the basis of two opposite sides of the first member rectangle and overlaps with the third member that forms the short side of the cube.

Here, the fourth member is preferably triangular or trapezoidal.

According to the present invention, the insulation container is divided into an inner body and an outer body, and a vacuum insulating material is inserted between them to provide a structure to block heat transfer inside and outside the container, thereby maximizing the heat insulation inside the container. Is exerted.

1 and 2 are a perspective view and an exploded perspective view of an insulating container according to an embodiment of the present invention,
3 is a vertical cross-sectional view of an insulating container according to an embodiment of the present invention,
4 and 5 are plan views of an inner body and an outer body, respectively, which are part of an insulating container according to an embodiment of the present invention,
6 is a plan view of a vacuum insulating material disposed inside the heat insulating container of the present invention,
7 is a perspective view of two vacuum insulating materials disposed inside the heat insulating container of the present invention.
8 to 12 are other shapes of the vacuum insulating material disposed inside the heat insulating container of the present invention, and a state in which a single vacuum insulating panel is folded and arranged,
13 is a state in which the insulating container according to the present invention is stacked up and down.

The objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments associated with the accompanying drawings. In addition, the terms used are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user operator. Therefore, definitions of these terms should be made based on the contents of the present specification.

1 and 2 are a perspective view and an external perspective view of an insulating container according to an embodiment of the present invention, Figure 3 is a vertical cross-sectional view of the insulating container according to an embodiment of the present invention, Figures 4 and 5 Each is a plan view of an inner body and an outer body that are part of an insulating container according to an embodiment of the present invention.

Insulating container 100 according to the present invention, as shown in the figure, is made of a body (110,120) and a lid 150 provided on the upper side of the body, the body is an external body 110 in the shape of a hexahedron with the upper surface open And an inner body 120. In addition, a silicon guide 170 is disposed on the rim. An inner cover 160 may be provided inside the lid, and a vacuum insulating material (not shown) may be provided inside the lid, or a means for detaching and attaching PCM refrigerant to the inner surface may be provided. In addition, a handle, a coupling member 130 for coupling the body and the lid, and an attachment means 112 are located outside the main body.

Each of the outer body and the inner body has a hexahedral shape with an upper surface open, and the inner body is disposed inside the outer body, but the side and the bottom are combined at regular intervals. That is, the side surfaces of each of the inner body and the outer body are spaced apart by a first distance D1 to form a side space S1, and the bottom surfaces of each of the inner body and outer body are spaced apart by a second distance D2. It is a feature of the present invention to form (S2) and secure the heat insulation inside the container by arranging vacuum insulation materials in the side space (S1) and the bottom space (S2).

For spaces apart from the side and bottom of the body, the upper end of the inner body and the upper end of the outer body are brought into contact with each other. The inner body and the outer body are fastened by means of fastening means such as screws at four upper corners. Looking at the top view shown in Figures 4 and 5, it can be seen that the width of the edge portion is formed relatively thick so that the screw can be fastened.

Specifically, an outer body fastening portion 115 with an increased thickness is formed at the upper edge of the outer body, where a screw hole 118 is drilled. An inner body fastening portion 125 having an increased thickness is formed at the upper edge of the inner body, but a screw hole is not formed therein. This is to fasten the screw from the screw hole 118 of the outer body from the bottom to the top, so that the tip of the screw is buried inside the inner body fastening portion 125. That is, while the upper end of the inner body surrounds the upper end of the outer body, the screws are fastened, but the screws are fastened in the upper direction from the lower surface of the outer body so that the threads are screwed into the corners of the body, and the screws are not visible on the upper surface of the body. I did not.

The arrangement of the fastening means at the corners of the main body, the thickness of the edge of the main body, considering that the outer cover material cannot be mounted using fastening means penetrating the vacuum insulating material due to the nature of the outer material surrounding the inner core and maintaining vacuum. It was made to tighten the screw here. A vacuum insulating material is disposed between the inner body and the outer body, but since it is impossible to combine in a region where the vacuum insulating material is present, a relatively thick thickness is secured and a fastening means is disposed at the upper edge without the vacuum insulating material.

FIG. 6 is a plan view of a first embodiment of a vacuum insulating material disposed inside an insulating container of the present invention, and FIG. 7 is a perspective view of two vacuum insulating materials disposed inside the insulating container of the present invention.

In this embodiment, the vacuum insulator has a shape in which two sheets overlap in a floor space in a cross shape, and each of the two vacuum insulators 200 and 300 extends to both sides of the bottom portion and the bottom portion located in the bottom space S2. Consists of a side portion located in the side space (S1), the side portion has a larger trapezoidal shape of the outer end.

As shown in Figure 13, the heat insulating container of the present invention is made of a structure that can be stacked up and down, so that the side shape of the heat insulating container becomes wider toward the upper side. For this structure, the bottom of each of the two sheets of vacuum insulation materials 200 and 300 is a rectangular shape, and the side surfaces are preferably trapezoidal in shape.

However, although the vacuum insulation material may be arranged as above, a single vacuum insulation material may be folded and arranged as described below in order to reinforce the insulation performance at the edge of the container.

8 to 12 is a view of folding and arranging one vacuum insulation panel in a different shape of the vacuum insulation material disposed inside the heat insulating container of the present invention, and is an idea for blocking thermal bridges at the corners.

The vacuum insulating material 400, in another form, is arranged in the side space (S1) and the bottom space (S2) while forming a hexahedron with the top surface open by folding one sheet of vacuum insulating material. That is, the vacuum insulating material 400, one sheet was folded to form an hexahedral shape with the upper side open.

The vacuum insulating material is composed of a first member 410 having a rectangular shape forming the bottom of the hexahedron, second members 420 and 430 and third members 421, 422, 431 and 432 forming a side surface of the hexahedron.

The second members 420 and 430 are members arranged to be folded on the basis of two opposite sides of the first member rectangle, and at the same time, in the shape of a hexahedron, a long side surface. In addition, the third members 421, 422, 431, and 432 are parts extending from both sides of the second member 420, 430, and in the hexahedral shape, are parts forming a short side.

In addition, in order to block the thermal bridge of the insulated container, an additional fourth member 440,450 is further provided. The fourth member (440,450) is a portion that is folded based on two short sides facing each other in the first member 410 rectangle of the bottom portion, and is made to overlap with the third member that forms a single side in a hexahedral shape. However, the fourth member may have a triangular shape (FIGS. 10 and 11) or a trapezoidal shape (FIG. 12).

13 is a state in which the insulating container according to the present invention is stacked up and down.

The vacuum insulator used in the present invention withstands the force of atmospheric pressure and forms an inner space (thickness) to substantially insulate the core material, wraps the core material and blocks external air to maintain vacuum, and residual gas or infiltrating gas. It is composed of adsorbents that chemically adsorb and remove to delay the destruction of vacuum. The core material of the present invention may be composed of one of glass wool, fumed silica, and organic fibers (polyester, polypropylene, etc.), but the organic fiber is preferred when the use is food packaging. This is because when the vacuum insulating material is forcibly destroyed by external force, the inner core material may be exposed. Since the core material and the outer cover material constituting the vacuum insulating material are general techniques, a description thereof will be omitted.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (6)

It is composed of a body made of an outer body 110 and an inner body 120, a lid provided on the upper side of the body, and a vacuum insulating material 400 provided in a space between the inner body and the outer body,
The vacuum insulator 400 is a shape in which a single vacuum insulator is folded to form an open cube, and is disposed on the side and bottom of the main body.
A first member 410 having a rectangular shape constituting the bottom of the cube;
A second member (420,430) arranged to be folded on two opposite sides of the first member rectangle to form a long side surface of the cube;
A third member (421, 422, 431, 432) extending from each side of each of the second members (420, 430), forming a short side of the cube; And
The first member is formed of a fourth member (440,450) disposed to be folded on the basis of two short sides facing each other.
The fourth member overlaps with the third member constituting the short side of the hexahedron to block heat transfer inside and outside the main body. delete According to claim 1,
The upper end of the inner body is arranged to surround the upper end of the outer body,
It is formed by increasing the thickness at the upper edge of the outer body, the outer body fastening portion 115 is provided with a screw hole (118);
It is formed by increasing the thickness at the upper edge of the inner body, coupled with the outer body fastening portion, the inner body fastening portion 125 is not formed with a screw hole;
Insulated container, characterized in that it further comprises a screw 119 that is fastened from the bottom to the top of the screw hole 118, which is buried in the inner body fastening part 125. delete delete delete

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