JP2017155835A - Thermal insulation unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a thermal insulation unit capable of suppressing abrupt temperature change of an object subjected to thermal insulation.SOLUTION: A thermal insulation unit 1 includes: a thermal insulation box 10 formed into a box shape comprising a top plate part, a side plate part and a bottom plate part, and capable of storing an object subjected to thermal insulation therein; and a heat insulation cover 20 formed into a box shape comprising an upper surface part and a side surface part, and provided outside of the thermal insulation box 10. Between the thermal insulation box 10 and the insides of the upper surface part and side surface part of the heat insulation cover 20, heat insulation layers are respectively formed.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cold insulation unit.

  Conventionally, metal containers have been used for storage, transportation, etc. of articles that need to be kept cold or warm (hereinafter also referred to as “cold and warmed products”). In such a metal container, an interior body in which a heat insulating sheet is formed in a three-dimensional box shape is accommodated, and a cold and warm insulation material is accommodated in the interior body, and the temperature change of the cold and warm insulation object is accommodated. Has been proposed (see, for example, Patent Document 1).

Japanese Utility Model Publication No. 62-33592

  In general, it is known that a metal container absorbs heat from sunlight or the like, and the internal temperature becomes 60 ° C. or more in summer and in the daytime near the equator. Therefore, even if the above-described interior body is housed inside, there may be a case where the temperature change of the cold insulated material cannot be suppressed. Therefore, in order to suppress the temperature change of the cold insulated material, a container called a reefer container that can control the temperature in the container by the electric power supplied from the power supply device is used. However, this type of container is expensive and it is difficult to reduce transportation costs. Further, when the container is transported, the connection between the container and the power supply device may be temporarily disconnected (for example, movement from the ship to the land). In that case, a sudden temperature change may occur in the cold insulated material until the container is transported to the next storage location equipped with the power supply device.

  An object of the present invention is to provide a cold insulation unit that can suppress a rapid temperature change of a cold insulation product.

The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this.
-1st invention is the cold insulation unit (1) accommodated in the inside of a storage housing | casing, Comprising: The box which has a top-plate part (112), a side-plate part (113-116), and a baseplate part (111) Formed in the shape of a box having a cold and warm box (10) capable of accommodating a cold and warm material inside, and having an upper surface portion (211) and side surfaces (212 to 215). A heat insulation layer provided between the cold insulation box and the inside of the upper surface portion and the inside of the side surface portion of the heat insulation cover. Is a unit.
-2nd invention is the cold insulation heat retention unit (1) of 1st invention, Comprising: The said heat insulation cover (20) is provided with the light reflection layer, The light reflectance in the said light reflection layer of the said heat insulation cover is the following. It is a cold insulation unit characterized by exceeding the light reflectance on the surface of the cold insulation box.
-3rd invention is the cold insulation heat retention unit (1) of 1st or 2nd invention, Comprising: Inside the said upper surface part (211) of the said cold insulation heat insulation box (10) and the said heat insulation cover (20), and the said The heat insulation layer formed between the side portions (212 to 215) is an air layer.
-4th invention is the cold insulation heat insulation unit (1) of 1st or 2nd invention, Comprising: The said top plate part (112) of the said cold insulation heat insulation box (10), and the said upper surface of the said heat insulation cover (20) The heat insulating layer formed between the inside of the portion (211) is a heat insulating cover support plate (40) provided between the top plate portion of the cold insulation box and the inside of the upper surface portion of the heat insulating cover. And the heat insulation layer formed between the side plate portion of the cold insulation box and the inside of the side surface portion of the heat insulation cover is an air insulation unit.

  ADVANTAGE OF THE INVENTION According to this invention, the cold insulation heat retention unit which can suppress the rapid temperature change of a cold insulation material can be provided.

It is a figure explaining the cold insulation heat retention unit 1 of 1st Embodiment. It is a figure explaining the cold insulation warm box. It is a figure explaining the heat insulation panel 120 used for the board parts 111-116. It is a figure explaining the heat insulation cover. It is a figure explaining the 1st usage pattern of the cold insulation heat unit. It is a figure explaining the 2nd usage pattern of the cold insulation heat unit. It is a figure explaining 1 A of cold insulation heat retention units of 2nd Embodiment.

Embodiments of the present invention will be described below with reference to the drawings. In addition, each figure shown below including FIG. 1 is the figure shown typically. Therefore, the size and shape of each part are exaggerated as appropriate for easy understanding. Moreover, in each figure, the hatching showing the cross section of the member is omitted as appropriate.
Numerical values such as dimensions and material names of the respective members described in the present specification are examples of the embodiment, and the present invention is not limited thereto, and may be appropriately selected and used.
In this specification, terms that specify shape and geometric conditions, for example, terms such as parallel and orthogonal, are strictly meanings, have similar optical functions, and can be regarded as parallel and orthogonal Including a state having an error of.

(First embodiment)
FIG. 1 is a diagram illustrating a cold insulation unit 1 according to the first embodiment. FIG. 2 is a diagram for explaining the cold insulation box 10. FIG. 2A is a view for explaining the cold insulation box 10 with the front plate portion 116 closed. FIG. 2B is a diagram illustrating the cold insulation box 10 with the front plate portion 116 opened.

  In the drawings and the following description, for ease of understanding, the vertical direction in the normal use state of the cold insulation unit 1 is the Z direction, and the horizontal direction is the front-rear direction (the front plate portion 116 described later is the front surface). Is the X direction, and the left-right direction perpendicular to the front-rear direction is the Y direction. Further, the vertical upper side in the vertical direction is the + Z side, the vertical lower side is the -Z side, the front side in the front-rear direction is the + X side, the rear side is the -X side, the right side in the left and right direction is the + Y side, The left side is the -Y side.

  The cold insulation unit 1 is a composite having heat insulating properties. In the cold insulation unit 1, for example, a cold insulation product 2 that requires constant temperature transportation such as a frozen product or a heated product is accommodated. The cold insulation unit 1 is placed on a pallet (not shown), and is conveyed by a forklift or the like in a state where one or a plurality of cold insulation materials 2 are accommodated therein. The cold insulation unit 1 is accommodated in the transport container 100 by a forklift or the like.

  FIG. 1 shows a state in which the cold insulation unit 1 is accommodated in the container 100. In the present embodiment, the container 100 is described as a general metal container. However, the container 100 is a reefer container that has a function of keeping the inside cold or warmed by electric power supplied from an external power supply device. Also good.

  The container 100 includes a U-shaped metal fitting 101. A plurality of metal fittings 101 are provided on the vertical upper side (+ Z side) of the side surface portions (reference numerals omitted) arranged on three sides (right side, left side, and rear side). In FIG. 1, only the metal fitting 101 provided at a position that can be engaged with a hooked cord 21 (described later) of the heat insulating cover 20 is illustrated. In the container 100, the counterpart side with which the hooked cord 21 is engaged is not limited to the U-shaped metal fitting 101, and may be, for example, a rail-shaped metal fitting.

  In the container 100, the cold insulation box 10 is placed on the bottom surface portion 102. In the present embodiment, an example in which one cold insulation box 10 is accommodated in the container 100 will be described, but a plurality of cold insulation boxes 10 may be accommodated in the container 100. The container 100 includes door portions 103 at the left and right ends on the front side (+ X side). As shown in FIG. 1, by opening the left and right door portions 103 of the container 100, the article can be accommodated in the container 100 and the article can be taken out from the inside. Moreover, the inside of the container 100 can be sealed by closing the left and right door portions 103 of the container 100.

The cold insulation unit 1 includes a cold insulation box 10 and a heat insulating cover 20.
The cold insulation box 10 is a box-shaped housing that is disposed on the innermost side of the cold insulation unit 1. As shown in FIG. 2A, the cold insulation box 10 includes a bottom plate portion 111, a top plate portion 112, a right plate portion 113, a left plate portion 114, a back plate portion 115, and a front plate portion 116 (hereinafter referred to as “plate portion”). "). The right side plate portion 113, the left side plate portion 114, the back plate portion 115, and the front plate portion 116 constitute a side plate portion in the present embodiment.

The bottom plate portion 111 is a rectangular plate member that forms the bottom surface (the surface on the −Z side) of the cold insulation box 10.
The top plate portion 112 is a rectangular plate member that forms the upper surface (the surface on the + Z side) of the cold insulation box 10.
The right side plate portion 113 and the left side plate portion 114 are rectangular plate members that respectively form the right side surface (+ Y side surface) and the left side surface (−Y side surface) of the cold insulation box 10.
The back plate portion 115 is a rectangular plate member that forms the back surface (the surface on the −X side) of the cold insulation box 10.

  The front plate portion 116 is a rectangular plate member that forms the front surface (+ X side surface) of the cold insulation box 10. As shown in FIG. 2B, the front plate portion 116 is disposed so as to be openable and closable with respect to the cold insulation box 10. The front plate portion 116 of the present embodiment is disposed so as to be openable and closable in the direction of the arrow in the figure by an open / close member (not shown) provided on the front side (+ X side) of the left side plate portion 114. In the cold insulation box 10, the opening and closing of the other plate portions excluding the front plate portion 116 is restricted.

  The above-described bottom plate portion 111, top plate portion 112, right side plate portion 113, left side plate portion 114, back plate portion 115, and front plate portion 116 are each formed by a heat insulating panel 120 (described later) having heat insulating properties. Hereinafter, the structure of the heat insulation panel 120 is demonstrated.

FIG. 3 is a diagram illustrating the heat insulation panel 120 used for the plate portions 111 to 116. FIG. 3 is a cross section parallel to the thickness direction of the heat insulating panel 120.
As shown in FIG. 3, the heat insulating panel 120 includes a protective base 121, a heat insulating material 122, and an adhesive layer 123.

  The protective substrate 121 is a member that protects the heat insulating material 122 and gives the plate portions 111 to 116 sufficient rigidity. The protective substrate 121 is not particularly limited as long as it is a member capable of obtaining a desired rigidity. For example, a plywood, an iron plate, a foaming agent, a resin plate, an embossed resin sheet, a paperboard, or the like may be used. it can.

  Although not shown, the protective base 121 has aluminum deposited on the surface. The surface on which aluminum is deposited functions as a light reflecting layer. By forming the light reflecting layer on the surface of the heat insulating panel 120 (protective substrate 121), the movement of heat due to light can be suppressed. As will be described later, the light reflecting layer is also formed on the surface of the heat insulating cover 20. The light reflectance of the light reflecting layer can be quantified based on, for example, the light reflectance with respect to infrared rays (wavelength: 0.78 μm to 1000 μm). In addition, the light which transmits heat is not limited to infrared rays. Therefore, the light reflectance of the light reflecting layer may be quantified based on the light reflectance with respect to other light (for example, visible light). The relationship between the light reflectivities of the light reflecting layers formed on the surfaces of the cold insulation box 10 and the heat insulating cover 20 will be described later.

  The heat insulating material 122 is a member covered with the protective base material 121. A known material can be used for the heat insulating material 122 as long as desired heat insulating properties can be obtained. As the heat insulating material 122, for example, fiber-based heat insulating materials such as glass wool, rock wool, cellulose fiber, and insulation board, natural heat insulating materials such as wool and carbonized cork, extruded foam polystyrene, beaded polystyrene, rigid urethane foam, A foamed plastic heat insulating material such as highly foamed polyethylene or phenol foam, a vacuum heat insulating material, or the like can be used.

  The heat insulating material 122 of this embodiment includes a core material 122a and an exterior material 122b. As the core material 122a, a material used for a core material such as a known vacuum heat insulating material can be used. For the core material 122a, for example, a porous material such as a powder such as silica, a foamed material such as urethane polymer, or a fiber material such as glass wool can be used. The exterior material 122b is a member that covers the outer periphery of the core material 122a. The exterior material 122b is a flexible sheet in which a core material 122a, a heat welding layer, and a gas barrier layer (both not shown) are sequentially laminated.

  The adhesive layer 123 is a layer that adheres the protective substrate 121 and the heat insulating material 122. The adhesive layer 123 may use a known filler (for example, foamed urethane, rigid urethane foam, etc.) that fills the space between the protective base 121 and the heat insulating material 122 in addition to the adhesive, the pressure-sensitive adhesive, and the double-sided tape. it can.

Next, the heat insulating cover 20 will be described.
FIG. 4 is a diagram illustrating the heat insulating cover 20. Fig.4 (a) is a figure explaining the heat insulation cover 20 of the state which closed the side part. FIG. 4B is a diagram illustrating the heat insulating cover 20 in a state where a part of the side surface portion is opened.

  The heat insulating cover 20 is a box-shaped housing provided outside the cold insulation box 10. As shown in FIG. 4A, the heat insulating cover 20 includes an upper surface portion 211, a right side surface portion 212, a left side surface portion 213, a back surface portion 214, and a front surface portion 215 (hereinafter also referred to as “surface portion”). The heat insulating cover 20 is formed in a box shape without a bottom surface. The right side surface portion 212, the left side surface portion 213, the back surface portion 214, and the front surface portion 215 constitute a side surface portion in the present embodiment. In addition, the shape of the heat insulation cover 20 is not limited to the box shape without a bottom face. The shape of the heat insulating cover 20 may be a box shape having a bottom surface, similar to the cold insulation box 10.

The upper surface portion 211 is a rectangular plate member that forms the upper surface (the surface on the + Z side) of the heat insulating cover 20. The upper surface portion 211 includes four hooked cords 21 on the outer surface 211a.
The hooked cord 21 is a component for suspending the heat insulating cover 20 inside the container 100. The hook-attached cord 21 includes a hook 21a and a cord 21b (see the right back side in FIG. 7A). The hook 21 a is a component that can be engaged with a metal fitting 101 (see FIG. 1) provided inside the container 100. The cord 21b is a string-like component joined to the hook 21a. A hook 21a is joined to one end of the cord 21b. The other end of the cord 21 b is attached to the outer side surface 211 a of the upper surface portion 211 of the heat insulating cover 20. In the cord 21b, the other end portion to which the hook 21a is not joined is attached to the outer side surface 211a of the upper surface portion 211 by, for example, adhesion, sewing, tacking, or the like. Although not shown, the cord 21b includes an adjuster mechanism whose length can be adjusted. Therefore, each of the four hooked cords 21 can be adjusted to a desired length.

The right side surface 212 and the left side surface 213 are rectangular plate members that form the right side surface (+ Y side surface) and the left side surface (−Y side surface) of the heat insulating cover 20, respectively.
The back surface portion 214 is a rectangular plate member that forms the back surface (the surface on the −X side) of the heat insulating cover 20.
The front surface portion 215 is a rectangular plate member that forms a vertically lower side (−Z side) of the front surface (+ X side surface) of the heat insulating cover 20.

  The length of the heat insulating cover 20 in the XYZ directions is set so that the heat insulating cover 20 is large enough to accommodate the cold insulation box 10 therein. The heat insulation cover 20 is at least several mm to 10 cm between the outer surface of the cold insulation box 10 in the vertical upper side (+ Z side) and the horizontal direction (XY direction) with the cold insulation box 10 accommodated therein. It is desirable that the gap be formed in such a size. In addition, in order to increase the heat capacity stored by the air layers A1 and A2 (described later), it is desirable to increase the gap between the heat insulating cover 20 and the cold insulation box 10 as much as possible.

  As shown in FIG. 4A, a hook-and-loop fastener 216 is provided at the right side (+ Y side) end portion of the front surface portion 215 and the front side (+ X side) end portion of the right side surface portion 212. A hook-and-loop fastener 217 is provided at an end portion on the left side (−Y side) of the front surface portion 215 and an end portion on the front side (+ X side) of the left side surface portion 213. A hook-and-loop fastener 218 is provided at the right side (+ Y side) end portion of the back surface portion 214 and the rear side (−X side) end portion of the right side surface portion 212. A hook-and-loop fastener 219 is provided at the left end (−Y side) of the back surface portion 214 and the rear end (−X side) of the left side surface portion 213.

  As shown in FIG. 4B, the heat insulating cover 20 can lift the front surface portion 215 upward (+ Z side) by peeling off the hook-and-loop fasteners 216 and 217. When the front surface part 215 is lifted vertically upward, the front side (−X side) of the heat insulating cover 20 is opened, so that the cold insulation box 10 (see FIG. 1) can be accommodated or taken out of the heat insulating cover 20. .

In order to facilitate the accommodation and removal of the cold insulation box 10, it is desirable to provide the hook-and-loop fasteners 216 and 217 on both sides of the front surface portion 215 in the left-right direction as in this embodiment, but the hook-and-loop fasteners 216 or 217 are provided. It is good also as a structure which provided only any one of these. When only one of the surface fasteners is provided, the heat insulating property of the heat insulating cover 20 can be further improved. The hook-and-loop fasteners 216 to 219 are also used when adjusting the length of the heat insulating cover 20 in the vertical direction (Z direction), as will be described later.
Moreover, the heat insulation cover 20 can be made into a sheet form by removing all the hook-and-loop fasteners 216 to 219. Therefore, when the heat insulating cover 20 is not used, all the hook-and-loop fasteners 216 to 219 are peeled off to form a sheet, which can be stored in a narrow storage space.
Instead of the hook-and-loop fasteners 216 and 217, other joining members may be provided. For example, the front side (+ X side) end of the right side surface part 212 and the front side (+ X side) end part of the left side surface part 213 are extended so as to be folded inward with the material of the heat insulating cover 20, and the right side (+ Y side) of the front side part 215 ) And the left (−Y side) end. In that case, the overlapped end portions can be joined by, for example, a tape. For this joining, it is desirable to use a tape having light reflectivity such as an aluminum tape, but a general double-sided tape may be used.

  The upper surface portion 211, the right side surface portion 212, the left side surface portion 213, the back surface portion 214, and the front surface portion 215 of the heat insulating cover 20 are each formed of a heat insulating sheet having heat insulating properties. The surface portions 211 to 215 constituting the heat insulating cover 20 are, for example, a heat insulating sheet in which an aluminum foil sheet is bonded to both surfaces of a sheet-like polyethylene, polypropylene, polystyrene, and polyethylene terephthalate, a sheet-like polyethylene, polypropylene, polystyrene, and polyethylene terephthalate. It is possible to use a heat insulating sheet or the like having a film on which aluminum is deposited on both sides. Further, the sheet-like polyethylene, polypropylene, polystyrene, and polyethylene terephthalate may be a sheet having closed cells, a sheet having an air layer (for example, “Puchipuchi (registered trademark)” manufactured by Kawakami Sangyo), or the like.

  In the heat insulating cover 20 (heat insulating sheet), the surface layer on which aluminum is formed functions as a light reflecting layer. The light reflectance of the light reflecting layer is desirably 60% or more when the light reflectance for infrared rays is used as a reference. Moreover, it is desirable that the light reflectance in the light reflecting layer of the heat insulating cover 20 is set so as to exceed the light reflectance of the light reflecting layer in the cold insulation box 10 (heat insulating panel 120).

In this embodiment, the light reflection layer by the same material is formed in the outer surface and inner surface of the cold insulation box 10 (heat insulation panel 120). Similarly, although the light reflection layer by the same material is formed in the outer surface and inner surface of the heat insulation cover 20 (heat insulation sheet), the light reflection layer of the heat insulation cover 20 is more than the light reflection layer of the cold insulation box 10. Since the surface roughness is low, the light reflectance is higher than that of the light reflection layer of the cold insulation box 10. In the heat insulating cover 20, a method for increasing the light reflectance may be, for example, reducing the resin component of the surface layer on which aluminum is formed. Further, if there is a layer that absorbs light outside the surface layer on which aluminum is formed (light intrusion and reflection direction), the light reflectivity is lowered. For example, when aluminum is vapor-deposited on a polyester film, the polyester surface is the outside. Therefore, in order to increase the light reflectance, it is desirable not to provide a layer that absorbs light on the surface layer side.
The cold insulation box 10 and the heat insulating cover 20 of the present embodiment have the same light reflectance on the outer surface and the inner surface. Here, the outer side surface and the inner side surface are, in a box shape, a surface disposed outside is an outer surface, and a surface disposed inside is an inner surface.

  On the other hand, in the cold insulation box 10 and the heat insulating cover 20, it may be considered that the material of the light reflecting layer formed on the surface is different between the outer side surface and the inner side surface. In that case, the higher the light reflectance of the light reflecting layer on the higher temperature side, the better. As the light reflectance is increased, light absorption by the heat insulating cover 20 is suppressed, and heat radiation to the side opposite to the side from which light (mainly far infrared rays) is radiated is reduced, thereby further improving the cold insulation. be able to. Therefore, for example, when the container 100 is heated by sunlight and becomes high temperature, the light reflectance of the light reflecting layer formed on the outer surface is made higher than the light reflectance of the light reflecting layer in the cold insulation box 10. By increasing the heat insulation, it is possible to further improve the cold and heat retention.

Next, the usage pattern of the cold insulation unit 1 will be described.
FIG. 5 is a diagram illustrating a first usage pattern of the cold insulation unit 1. FIG. 5 is a cross-sectional view of the ZY plane at a substantially intermediate position in the front-rear direction (X direction) of the cold insulation unit 1.
First, the operator opens the front plate portion 116 (see FIG. 2) of the cold insulation box 10 and accommodates the cold insulation 2 inside. The operator closes the front plate portion 116 of the cold insulation box 10 after accommodating the cold insulation article 2 in the cold insulation box 10. Thereby, the inside of the cold insulation box 10 is in the cold insulation state. In this usage pattern, the operation of housing the cold insulated material 2 in the cold insulated box 10 is performed outside the container 100.

  Next, the worker houses the heat insulating cover 20 inside the container 100. Then, the worker hooks the hooks 21a of the four hook-attached cords 21 attached to the heat insulating cover 20 on the metal fittings 101 provided inside the container 100, respectively, so that the four hook-attached cords 21 and the metal fittings 101 are provided. And engage. At this time, the operator adjusts the length of the cord 21 with the hook so that there is no gap between the vertical lower end (−Z side) end of the heat insulating cover 20 and the bottom surface 102 of the container 100. Adjust by mechanism (not shown).

  Next, the operator peels off the surface fasteners 216 and 217 of the heat insulating cover 20 and lifts the front surface portion 215 upward (+ Z side) (see FIG. 4B). When the front surface portion 215 is lifted vertically upward, the front side (−X side) of the heat insulating cover 20 is opened, so that the operator can accommodate the cold insulation box 10 inside the heat insulating cover 20.

In addition, the order of the operation | work which accommodates the heat insulation cover 20 in the inside of the container 100, and the operation | work which accommodates the cold insulation warm box 10 in the inside of the heat insulation cover 20 may be reverse. That is, the cold insulation box 10 may be accommodated in the container 100 first, and then the heat insulating cover 20 may be accommodated in the container 100. Also in that case, the heat insulation cover 20 can be easily covered with the cold insulation box 10 by removing the hook-and-loop fasteners 216 and 217 of the heat insulation cover 20 and lifting the front surface portion 215 vertically upward (+ Z side).
Next, the operator closes the front side (−X side) of the heat insulating cover 20 by attaching the surface fasteners 216 and 217 of the heat insulating cover 20. Thereby, an air layer A <b> 1 is formed between the inside of the upper surface portion 211 of the heat insulating cover 20 and the cold insulation box 10. Further, an air layer A <b> 2 is formed between the inner side of the right side surface portion 212, the left side surface portion 213, the unillustrated back surface portion 214 and the front surface portion 215 of the heat insulating cover 20 and the cold insulation box 10.
Finally, the worker can close the inside by closing the door 103 (see FIG. 1) of the container 100.

  FIG. 6 is a diagram illustrating a second usage pattern of the cold insulation unit 1. 6A is a cross-sectional view of the ZY plane at a substantially intermediate position in the front-rear direction (X direction) of the cold insulation unit 1 as in FIG. FIG. 6B illustrates the state of the heat insulating cover 20 in the second usage pattern.

  When the cold insulation box 10 is smaller than the heat insulation cover 20, the operator adjusts the length of the hooked cord 21 with an adjuster mechanism (not shown) as shown in FIG. The position where 20 is suspended is moved vertically downward (−Z side).

Further, as shown in FIG. 6B, the worker peels off part of the end portion on the vertical lower side (−Z side) of the hook-and-loop fasteners 216 to 219 (not shown) provided on the heat insulating cover 20. Thereby, the length of the vertical direction of the heat insulation cover 20 can be adjusted. When the length of the heat insulating cover 20 in the vertical direction is shortened, as shown in FIG. 6A, the space between the upper surface portion 211 of the heat insulating cover 20 and the cold insulation box 10, and the ceiling and side walls of the heat insulating cover 20 and the container 100. An appropriate gap can be formed between the two.
Although not shown, even when the length of the container 100 in the vertical direction (Z direction) is larger than that of the heat insulating cover 20, the heat insulating cover 20 and the cold insulation are reduced by shortening the length of the heat insulating cover 20 in the vertical direction. An appropriate gap can be formed between the heat insulating box 10.

  Thus, by adjusting the length of the cord 21 with the hook, an appropriate gap between the heat insulation cover 20 and the heat insulation box 10 according to the size relationship of the heat insulation box 10, the heat insulation cover 20 or the container 100. Can be formed. Thereby, as shown to Fig.6 (a), air layer A1 as a heat insulation layer is formed between the inner side of the upper surface part 211 of the heat insulation cover 20, and the cold insulation warm box 10. FIG. In addition, an air layer A <b> 2 as a heat insulating layer is formed between the right side surface portion 212, the left side surface portion 213, the back surface portion 214 (not shown), and the inside of the front surface portion 215 and the cold insulation box 10.

According to the cold insulation unit 1 of the first embodiment, the following effects are achieved.
In the cold insulation unit 1, when the cold insulation box 10 is accommodated inside the heat insulation cover 20, an air layer A <b> 1 is formed between the inside of the upper surface portion 211 of the insulation cover 20 and the cold insulation box 10 as shown in FIG. 5. Is done. Further, an air layer A <b> 2 is formed between the inner side of the right side surface portion 212, the left side surface portion 213, the unillustrated back surface portion 214 and the front surface portion 215 of the heat insulating cover 20 and the cold insulation box 10.

  The air layers A <b> 1 and A <b> 2 are substantially blocked from venting to the outside, and become a space in which air convection hardly occurs between the heat insulating cover 20 and the cold insulation box 10. For this reason, it is difficult for heat from the outside to be transmitted to the cold insulation box 10 housed inside the heat insulating cover 20 due to the heat insulating effect of the air layers A1 and A2. Therefore, according to the cold insulation unit 1 of the present embodiment, a rapid temperature change of the cold insulation 2 stored in the cold insulation box 10 can be suppressed even in a general metal container.

Therefore, when the container 100 is transported, it is transported in a state in which a rapid temperature change of the cold insulated material 2 is suppressed (for example, it does not exceed 35 degrees during the summer day, and the cold insulated material 2 is not frozen even during the winter night). Can be stored. Further, according to the cold insulation unit 1 of the present embodiment, it is not necessary to use an expensive reefer container, so that the transportation cost can be reduced.
Further, in a container having a function of keeping the inside cold or warmed by the power supplied from the power supply device, such as the reefer container described above, when the connection between the container and the power supply device is temporarily disconnected (for example, Even when the container is moved from the ship to the land), the rapid change in temperature of the cold insulation 2 stored in the cold insulation box 10 is suppressed until the container is transported to the next storage location equipped with the power supply device. be able to.

  In addition, if there is an appropriate gap between the heat insulating cover 20 and the ceiling portion and the side surface portion (not shown) of the container 100, not only the air layers A1 and A2 between the heat insulating cover 20 and the cold insulation box 10, An air layer is also formed between the outer surface of the heat insulating cover 20 and the container 100. Therefore, the rapid temperature change of the cold insulated material 2 accommodated in the cold insulated box 10 can be more effectively suppressed.

  The light reflectance of the light reflecting layer formed on the surface of the heat insulating cover 20 is set so as to exceed the light reflectance of the light reflecting layer formed on the surface of the cold insulation box 10. Therefore, the cold insulation unit 1 can suppress the movement of heat due to light from the heat insulating cover 20 to the cold insulation box 10. For example, in a state where the door 103 of the container 100 is opened, it is possible to effectively suppress the movement of heat due to infrared rays, visible rays, and the like incident on the cold insulation unit 1 from the outside.

  The heat insulating cover 20 can be easily hung inside the container 100 by the hooked cord 21. Moreover, the heat insulation cover 20 can be easily taken out from the inside of the container 100 by releasing the engagement between the hooked cord 21 and the metal fitting 101 (see FIG. 1). Thus, since the cold insulation heat retention unit 1 becomes easy to attach and detach the heat insulating cover 20, workability can be improved.

  The heat insulating cover 20 can form an appropriate gap with the cold insulation box 10 by the adjuster mechanism of the hooked cord 21. Moreover, since it is not necessary to prepare a plurality of heat insulating covers 20 having different sizes, the number of the heat insulating covers 20 and the storage space can be reduced.

(Second Embodiment)
FIG. 7 is a diagram for explaining a cold insulation unit 1A of the second embodiment. FIG. 7 is a cross-sectional view of the ZY plane at a substantially intermediate position in the front-rear direction (X direction) of the cold insulation unit 1A.
In the cold insulation heat retention unit 1A of the second embodiment, the basic configuration of the heat insulation cover 20A and the cold insulation heat retention box 10 is the same as that of the cold insulation heat retention unit 1 of the first embodiment. Therefore, only differences from the first embodiment will be described in the second embodiment. Moreover, in 2nd Embodiment, the code | symbol same as 1st Embodiment is attached | subjected to the member etc. equivalent to 1st Embodiment, and the overlapping description is abbreviate | omitted.

As shown in FIG. 7, the cold insulation unit 1 </ b> A of the second embodiment includes a cold insulation box 10, a heat insulation cover 20 </ b> A, and a heat insulation cover support plate 40. The heat insulating cover support plate 40 has a function of supporting the heat insulating cover 20 </ b> A inside the container 100. Further, the heat insulating cover support plate 40 has a function of forming an air layer A2 between the right side surface portion 212, the left side surface portion 213, the back surface portion 214 and the front surface portion 215 (not shown) of the heat insulating cover 20, and the cold insulation box 10. Have. Further, the heat insulating cover support plate 40 has a function of forming a heat insulating layer B1 between the inside of the upper surface portion 211 of the heat insulating cover 20 and the top plate portion 112 of the cold insulation box 10.
The heat insulating cover support plate 40 is a flat member, and is formed of, for example, a foamed plastic heat insulating material such as extruded polystyrene foam, bead polystyrene, rigid urethane foam, highly foamed polyethylene, or phenol foam.

  The vertical and horizontal dimensions of the heat insulating cover support plate 40 in the XY plane are substantially the same as those of the upper surface portion 211 of the heat insulating cover 20. The thickness of the heat insulating cover support plate 40 is, for example, the air layer A1 formed between the inside of the upper surface portion 211 of the heat insulating cover 20 and the top plate portion 112 of the cold insulation box 10 in the first embodiment (see FIG. 5). ) In the vertical direction (Z direction). Depending on the material used as the heat insulating cover support plate 40, the heat insulating characteristics may be further improved than the air layer A1 (see FIG. 5) formed between the inside of the upper surface portion 211 of the heat insulating cover 20 and the cold insulation box 10. Can be increased. In that case, you may make the thickness of the heat insulation cover support plate 40 smaller (thinner) than the space | interval of air layer A1.

  The basic configuration of the heat insulating cover 20A is the same as that of the heat insulating cover 20 (see FIG. 4) of the first embodiment. The heat insulating cover 20A of the second embodiment is different from the heat insulating cover 20 of the first embodiment in that the upper surface 211 is not provided with the hooked cord 21. As will be described later, the heat insulating cover 20 </ b> A is supported by a heat insulating cover support plate 40.

  As shown in FIG. 7, the heat insulating cover support plate 40 is disposed between the top plate portion 112 of the cold insulation box 10 and the heat insulating cover 20. The heat insulation cover support plate 40 may be inserted between the heat insulation cover 20 and the cold insulation box 10 while the heat insulation cover 20 is put on the cold insulation box 10, or the heat insulation cover support plate 40 may be insulated on the cold insulation box 10. The heat insulating cover 20 may be covered with the cover support plate 40 disposed.

  When the heat insulation cover support plate 40 is disposed between the top plate portion 112 and the heat insulation cover 20 of the cold insulation box 10, the heat insulation cover support plate 40 is provided between the inside of the upper surface portion 211 of the heat insulation cover 20 and the cold insulation box 10. A heat insulation layer B1 is formed. Moreover, since the heat insulation cover support plate 40 has larger vertical and horizontal dimensions in the XY plane than the top plate portion 112 of the cold insulation box 10, the right side surface portion 212, the left side surface portion 213, and the back surface portion 214 (not shown) of the heat insulation cover 20. In addition, an air layer A <b> 2 as a heat insulating layer is formed between the inside of the front surface portion 215 and the cold insulation box 10.

As described above, since the heat insulation layer B1 and the air layer A2 are formed between the heat insulation cover 20A and the cold insulation box 10, the cold insulation unit 1A of the second embodiment is accommodated in the cold insulation box 10. The temperature change of the cold-retained material 2 can be suppressed.
In the cold insulation unit 1A of the second embodiment, since the heat insulating cover 20A is supported by the heat insulating cover support plate 40, it is not necessary to provide the hooked cord 21 (see FIG. 4) on the heat insulating cover 20A. Therefore, the cold insulation unit 1A of the second embodiment can reduce the number of parts that constitute the heat insulating cover 20A. In addition, the cold insulation heat retention unit 1A of the second embodiment can obtain the same effects as the cold insulation heat retention unit 1 of the first embodiment.
In the second embodiment, the heat insulating cover support plate 40 may be bonded to the inside of the upper surface portion 211 of the heat insulating cover 20 with an adhesive or the like.

  Moreover, you may form the recessed part which has the same vertical and horizontal dimension as the top-plate part 112 of the cold insulation box 10 in the surface (-Z side) of the heat insulation cover support plate 40. FIG. By engaging the recess with the top plate portion 112 of the cold insulation box 10, the horizontal (X-Y) direction shift of the heat insulating cover support plate 40 disposed on the top plate portion 112 of the cold insulation box 10 is suppressed. can do.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications and changes can be made as in the modifications described later, and these are also included in the present invention. Within the technical scope. In addition, the effects described in the embodiments are merely a list of the most preferable effects resulting from the present invention, and the effects of the present invention are not limited to those described in the embodiments. In addition, although the above-mentioned embodiment and the deformation | transformation form mentioned later can also be used in combination suitably, detailed description is abbreviate | omitted.

(Deformation)
In the first embodiment, the light reflection layers of the cold insulation box 10 and the heat insulating cover 20 are not limited to both surfaces, and may be formed only on one surface (outer surface).
In the second embodiment, a plurality of holes (about several mm to several cm) penetrating in the thickness direction may be formed in the heat insulating cover support plate 40. Moreover, you may form the opening part (several centimeters-about several tens of centimeters) larger than the hole part mentioned above in the heat insulation cover support plate 40. FIG. Such a hole and opening function as an air layer. The size, shape, arrangement, and the like of the hole and the opening are not particularly limited as long as appropriate heat insulating properties can be obtained as an air layer.
In the first and second embodiments, the cold insulation box 10 may be configured to be foldable and assembleable.

DESCRIPTION OF SYMBOLS 1,1A Insulation unit 10 Insulation box 20, 20A Insulation cover 40 Insulation cover support plate 111 Bottom plate part 112 Top plate part 113 Right side plate part 114 Left side plate part 115 Back plate part 116 Front plate part 211 Upper surface part 212 Right side part 213 Left side 214 Back 215 Front

Claims (4)

A cold and warm unit that is housed in a storage case,
A cold insulation box that is formed in a box shape having a top plate portion, a side plate portion, and a bottom plate portion, and that can contain a cold insulation material inside;
Formed in a box shape having an upper surface portion and a side surface portion, and provided with a heat insulating cover provided outside the cold insulation box,
A heat insulating layer is formed between the inside of the cold insulation box and the inside of the upper surface portion and the inside of the side surface portion of the heat insulating cover,
A cool and warm unit. The cold insulation unit according to claim 1,
The heat insulating cover includes a light reflecting layer,
The light reflectance of the light reflecting layer of the heat insulating cover exceeds the light reflectance of the surface of the cold insulation box;
A cool and warm unit. The cold insulation unit according to claim 1 or 2,
The heat insulation layer formed between the cold insulation box and the inside of the upper surface portion and the inside of the side surface portion of the heat insulating cover is an air layer;
A cool and warm unit. The cold insulation unit according to claim 1 or 2,
The heat insulation layer formed between the top plate portion of the cold insulation box and the inside of the upper surface portion of the heat insulation cover includes the top plate portion of the cold insulation box and the inside of the upper surface portion of the heat insulation cover. Is a heat insulating cover support plate provided between
The heat insulating layer formed between the side plate portion of the cold insulation box and the inside of the side surface portion of the heat insulating cover is an air layer;
A cool and warm unit.

Images