KR102255394B1 - Box with inner box and outer box connecting structure - Google Patents

Abstract

According to the present invention, provided is an insulation box comprising a body comprising an inner box (110), an outer box (120) and an insulation structure (130) located between the inner box and the outer box, and a cap (150) provided in an upper part of the body. The insulation structure has a hexahedral shape with an open upper side and is manufactured as an integrated body through a foam-molding process, an outer surface of the insulation structure is matched with an inner surface of the outer box, an inner surface of the insulation structure is matched with an outer surface of the inner box, the cap is manufactured through a foam-molding procedure, the body and the cap are all molded with polypropylene to be easily recycled, and the insulation structure is manufactured as an integrated body to have excellent strength while performing an insulation function.

Description

Box with inner box and outer box connecting structure {BOX WITH INNER BOX AND OUTER BOX CONNECTING STRUCTURE}

The present invention relates to a box, and relates to a box to have an enclosed space to cool or keep warm by blocking heat transfer between the inside and the outside, specifically composed of an inner box and an outer box, and between the inner box and the outer box It relates to a box in which an insulating structure having a surface exactly matching the shape of the inner surface is arranged to increase the internal and external thermal insulation effect.

In general, a box for accommodating a product that requires freezing or refrigeration is a packaging means necessary for storage or transportation to maintain the freshness of food such as agricultural products, aquatic products, livestock products, and dairy products.

Conventionally, in the form of a cold storage box, an item such as food that needs cold insulation is accommodated in the box along with a refrigerant, and a structure for heat insulation is adopted for the wall. As an example of the prior art for such a cold storage box, there is Patent No. 10-1910860 (2018.10.17). In the prior art, a lower insulating member, a side insulating member, and an upper insulating member are disposed on the wall inside the wall constituting the cold storage box, and a cooling member is provided therein.

However, in the cold box of the prior art, the insulation members, which play an important role in exhibiting the insulation performance, are separated from each other, the structure of the insulation box is complicated, and heat transfer at the corners where the insulation members contact each other due to the separation structure of the insulation members There was a structural problem that couldn't block it.

An object of the present invention is to provide a technology for maximizing the performance of insulating the inner space of the insulating box from the outside by placing an insulating box between the inner box and the outer box.

The present invention consists of a main body made of an inner box 110 and an outer box 120 and an insulating structure 130 positioned between the inner box and the out box, and a cap 150 provided on the upper side of the main body, The heat insulating structure has a hexahedral shape with an open top surface and is integrally manufactured through a foam molding process, the outer surface of the heat insulating structure coincides with the inner side of the outer box, and the inner side of the heat insulating structure is the outer side of the inner box. Consistent with the side, the cap is manufactured by a foam molding process, and the main body and the cap are both molded of polypropylene so that recycling is easy, and the insulating structure is manufactured as an integral type, so that it is excellent in terms of strength while exerting a thermal insulation function. Provides an insulation box characterized by.

The side surface of the insulating structure is composed of a first side surface 131 at the lowermost end, a second side surface 132 at the center, and a third side surface 133 at the uppermost end, and the thickness 131a of the first side and the thickness of the third side ( 133a) is formed thicker than the thickness 132a of the second side, so that the upper and lower nesting of the insulation box is possible, while the insulation effect inside and outside the insulation box is exhibited.

A rib is not formed on the outer surface 121 of the bottom of the outbox, and a rib 123a is formed in a grid shape on the inner surface 123 of the bottom of the outbox, and the outer surface 135 of the bottom of the heat insulating structure In the rib groove (135a) is formed in a position corresponding to the rib (123a).

O-rings 129 are fastened along the rim to the upper end 120-1 of the outbox, and the upper end 110-1 of the inner box is coupled to each other while completely covering the upper end 120-1 of the outbox, A fastening part 128 protruding inward is provided at an upper end of the outer box, and a hook 118 protruding downwardly on a bottom surface of the inner box is provided to be fastened to the fastening part 128.

The sidewall of the outbox includes a nesting jaw 160 formed horizontally at a position corresponding to a boundary line of the second side 132 and the third side 133 of the insulation box, and the insulation box top and bottom nesting When stacked, the upper end portion 110-1 of the inner box of the insulating box located at the lower side is positioned on the nesting jaw 160 of the insulating box located at the upper side.

According to the present invention, the structure of the insulation box is integrated with the inner box and the outer box, and a foam-molded insulation structure is integrally provided so that the shape of the contacting portion exactly matches each other, and the structure of the insulation box is located between the inner box and the outer box. By effectively blocking the heat transfer of the insulation box, the insulation inside and outside the insulation box is maximized while providing a structure that enables box nesting.

In the present invention, by arranging an insulating structure having a thermal insulation function inside the center, but not in a separate form, but to have an integral structure, the strength of the insulating box itself is increased, and at the same time, the insulating structure existing inside can be foamed to have elasticity. Therefore, it can exert a buffering effect against an impact.

In addition, according to the present invention, an insulating structure having a thermal insulation function is disposed inside the center, but is not separated from each other but has an integral structure, thereby exhibiting an advantageous effect of improving assembly and workability during box manufacturing.

1 is an overall view of an insulation box according to the present invention,
Figure 2 is a view of a longitudinal sectional view of the insulation box according to the present invention,
3 is an exploded perspective view of an insulation box according to the present invention,
Figure 4 is an overall view of the heat insulation structure that is the configuration of the heat insulation box according to the present invention,
5 is a longitudinal cross-sectional view of an insulating structure that is a configuration of an insulating box according to the present invention,
6 is an overall view of an outbox, which is a configuration of an insulation box according to the present invention,
7 is a cross-sectional view of a nested stacked insulation box according to the present invention,
8 and 9 are views showing the coupling structure of the outer box and the inner box of the insulating box according to the present invention,
10 shows the assembly process of the insulation box according to the present invention.

Objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and preferred embodiments in conjunction with the accompanying drawings. In addition, the terms used are terms defined in consideration of functions in the present invention and 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 is an overall view of an insulation box according to the present invention, FIG. 2 is a longitudinal sectional view of an insulation box according to the present invention, and FIG. 3 is an exploded perspective view of an insulation box according to the present invention, and FIG. It is an overall view of the thermal insulation structure, which is the configuration of the thermal insulation box according to the invention, Figure 5 is a longitudinal sectional view of the thermal insulation structure that is the configuration of the thermal insulation box according to the present invention, and Figure 6 is a configuration of the thermal insulation box according to the present invention, the outbox It is an overall view, FIG. 7 is a cross-sectional view of a nested and stacked insulation box according to the present invention, and FIGS. 8 and 9 are a view showing a coupling structure between an outer box and an inner box of the insulation box according to the present invention. 10 shows the assembly process of the insulation box according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Insulation insulation box 100 according to the present invention, as shown in the drawing, is composed of a main body and a cap 150 provided on the upper side of the main body, the main body is an inner box 110 and the inner box 110 in a hexahedral shape with an open upper surface as a whole. It consists of an outbox 120. A feature of the present invention is that the inner box and the outer box are combined, but the heat insulating structure 130 is disposed in which the shape of the surface in contact with each other is exactly matched to increase the heat insulation performance.

The heat insulating structure 130 has a hexahedral shape with an open upper surface and is integrally manufactured through a foam molding process. The cap 150 is also manufactured through a foam molding process. The insulation box of the present invention is characterized in that it is an eco-friendly material because both the body and the cap are molded of polypropylene, so that it is easy to reuse.

The shape of the insulating structure 130 is such that the outer surface of the insulating box matches the inner surface of the outer box, and the inner surface of the insulating box matches the outer surface of the inner box so that there is no space between them during assembly. And the insulation performance increases.

In addition, the present invention is to arrange the heat insulating structure 130 inside the center, but not separate from each other, but to form an integral structure, thereby increasing the vertical strength of the heat insulation box itself, and at the same time, the heat insulating structure present inside is foam-molded. Since it can have a degree of elasticity, it can also exert a cushioning effect against impact. In addition, by allowing the heat insulating structure to have an integral structure, assembly and workability are improved when the box is manufactured.

In addition, in the heat insulation box of the present invention, the side walls are not formed to have the same thickness in a straight vertical direction as a whole, but are divided into three parts. That is, the inner box 110, the outer box 120, and the sidewalls of the insulating structure 130 are all divided into subdivisions. Looking at this with reference to only the heat insulating structure 130, the configuration of the side surface of the heat insulating structure consists of a first side surface 131 at the lowermost end, a second side surface 132 at the middle, and a third side surface 133 at the uppermost end. By the way, the thickness 131a of the first side and the thickness 133a of the third side are formed to be thicker than the thickness 132a of the second side, so that the top and bottom nesting of the insulation box can be stacked. The insulation effect was made to be exerted. That is, the reason that the thickness 132a of the second side located in the middle part is relatively thin and the thickness of each section is made different by making the upper and lower thicknesses thicker is to 1) increase the nesting efficiency, and 2) improve the insulation effect. It is to increase.

The nesting effect is that when the insulation box is stored in an empty box, it is advantageous for space efficiency to be stacked up and down. This is called nesting for convenience (Fig. 7). As in the present invention, the stacking efficiency can be further increased by configuring and nesting different thicknesses for each section of the sidewall of the insulation box. For nesting, a stepped step is formed on the sidewall of the outbox. That is, a nesting jaw 160 formed horizontally at a position corresponding to the boundary line of the second side surface 132 and the third side surface 133 of the insulating structure is formed in the outbox, and when the upper and lower nesting of the insulating box is stacked, , The inner box upper part 110-1 of the insulating box located at the lower side is located on the nesting jaw 160 of the insulating box located at the upper side (see FIG. 7). In addition, since the coolness (cold) inside the box descends from the top to the bottom, the lower portion is formed thicker to block heat transfer from the bottom of the box to the outside.

As shown in FIGS. 2 to 3, the cap 150 of the present invention includes an upper surface 151 exposed to the outside and a lower surface 153 covering the internal space. The cap of the present invention is made of an EPP (Expanded Poly-Propylene) material manufactured by a foam molding process.

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Ribs are not formed on the outer surface 121 of the bottom of the outbox of the present invention. By choosing a flat structure with no ribs on the bottom, it is easy to transport on a conveyor belt. However, as a method to prevent floor sagging, a rib for strength reinforcement was formed on the inner side of the floor. That is, ribs 123a are formed in a lattice shape on the inner surface 123 of the bottom of the outbox. In addition, a rib groove (135a) is formed at a position corresponding to the rib (123a) on the outer surface (135) of the bottom of the heat insulating structure (130) to increase the assemblability of the coupling. The reason for this is that ribs for strength reinforcement exist in the insulation box, but the structure is convenient because it does not protrude from the outside.

That is, while the ribs exist to reinforce strength, the ribs are not exposed to the outer floor surface of the insulating box, and the ribs are not exposed to the inner floor of the insulating box (ie, the inner floor of the inner box). If the product (item) is placed in an insulation box so that the ribs are not exposed on the inner floor, it is convenient in the process of receiving the product because there are no ribs on the inner floor. In addition, there are no ribs on the outer floor, which is advantageous in the conveyor belt transfer process.

In addition, for sealing the inside and outside of the insulation box, a groove to which the O-ring 129 is fastened is formed along the edge of the upper end 120-1 of the outbox, and the O-ring is disposed in the groove. In a state in which the O-rings are disposed, the upper end portion 110-1 of the inner box is coupled to each other while completely covering the upper end portion 120-1 of the outer box.

The outer box and the inner box are coupled by hooks and fastening grooves at each upper end. That is, a fastening part 128 protruding inward is provided at the upper end of the outer box, and a hook 118 protruding downwardly at a bottom surface of the inner box is provided to be fastened to the fastening part 128, The hook is firmly fastened to the fastening part. The fastening process of the insulation box is made in the order of (a) (b) (c) (d) in FIG. 10 and is shown in detail in the drawing.

One of the characteristics of the present invention is that both the main body and the cap are molded with only a single polypropylene component, so that they are easy to reuse and are eco-friendly materials.

Polypropylene has excellent strength and durability, so it can be reused and reused after washing and heat disinfection due to its heat resistance and non-absorption properties. In addition, there is no generation of toxic gases (dioxin, etc.) during incineration, and it is advantageous for waste heat recovery due to high combustion heat, and the damaged and recovered product has the advantage of being able to be newly molded (recycled) by mixing it with new material after pulverization.

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 concepts defined in the following claims are also included in the scope of the present invention. It belongs to.

Claims (4)

Consisting of a main body made of an inner box 110 and an outer box 120 and an insulating structure 130 positioned between the inner box and the out box, and a cap 150 provided on the upper side of the main body,
The heat insulating structure has a hexahedral shape with an open top surface and is integrally manufactured through a foam molding process, the outer surface of the heat insulating structure coincides with the inner side of the outer box, and the inner side of the heat insulating structure is the outer side of the inner box. Consistent with the side, the main body and the cap are both molded of polypropylene to facilitate recycling, and the heat insulating structure is manufactured as an integral type, so that it is excellent in strength while exhibiting a heat insulation function,
The side surface of the heat insulating structure is composed of a first side surface 131 at the lowermost end, a second side surface 132 at the center, and a third side surface 133 at the uppermost end, and the thickness 131a of the first side and the thickness of the third side ( 133a) is formed thicker than the thickness of the second side (132a), so that the upper and lower nesting of the insulation box is possible, while the insulation effect inside and outside the insulation box is exhibited,
O-rings 129 are fastened along the rim to the upper end 120-1 of the outbox, and the upper end 110-1 of the inner box is coupled to each other while completely covering the upper end 120-1 of the outbox,
A fastening part 128 protruding inward is provided at an upper end of the outer box, and a hook 118 protruding downwardly at a bottom surface of the inner box is provided to be fastened to the fastening part 128. Box. The method of claim 1,
The side wall of the outbox includes a nesting jaw 160 formed horizontally at a position corresponding to a boundary line of the second side surface 132 and the third side surface 133 of the heat insulating structure,
In the case of stacking the top and bottom of the insulation box, the inner box upper portion (110-1) of the insulation box located at the lower side is located in the nesting jaw 160 of the insulation box located on the upper side. delete delete

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