JP7279348B2 - Insulated containers, insulated containers containing contents, and combinations of insulated containers - Google Patents

Description

The present disclosure relates to an insulated container, an insulated filled container, and an insulated container combination.

Conventionally, in a high-performance heat-insulating container, an aluminum deposition layer or a metal layer such as an aluminum foil is provided on the exterior part for the purpose of improving heat insulation, particularly for the main purpose of a heat shielding effect. In addition, as such a heat insulating container, there is also a container having a vacuum heat insulating material (VIP) including an aluminum deposition layer or the like mainly for ensuring barrier properties.

In this way, when a metal layer is used for either the exterior of the heat-insulating container or the vacuum heat insulating material of the heat-insulating container, the metal layer reflects electromagnetic waves. Therefore, it is difficult to read the RFID tag placed inside the panel of the heat insulating container from the outside of the panel by non-contact communication.

Further, conventionally, there has been known a case for containing an article with an RFID tag (for example, Patent Document 1). However, when using such a case, in order to read the contents of the RFID tag, a reading antenna is installed on the inner wall of the case, and the information read from the RFID tag is transmitted using a repeater installed on the top plate of the case. must be sent outbound.

Japanese Patent No. 6220998

The present disclosure provides an insulated container in which an IC tag placed inside the insulated container can be directly read from the outside, an insulated container containing contents, and a combination of the insulated container.

The heat-insulating container according to the present embodiment is a heat-insulating container, and includes a plurality of heat-insulating panels including a top heat-insulating panel, a bottom heat-insulating panel, and a plurality of side heat-insulating panels. One insulating panel is a radio transparent non-metallic panel.

In the heat-insulating container according to this embodiment, at least one heat-insulating panel among the plurality of heat-insulating panels may be a radio-impermeable metal panel.

In the heat-insulating container according to this embodiment, two heat-insulating panels facing each other among the plurality of heat-insulating panels may be non-metallic panels, and the other heat-insulating panels may be metal panels.

In the heat-insulating container according to this embodiment, the top heat-insulating panel and the bottom heat-insulating panel may be non-metal panels, and the plurality of side heat-insulating panels may be metal panels.

In the heat insulating container according to the present embodiment, the metal panel may have a core material and a metal gas barrier layer covering the core material.

In the heat insulating container according to the present embodiment, the nonmetallic panel may have a core material and a nonmetallic gas barrier layer surrounding the core material.

The heat-insulating container according to the present embodiment is a heat-insulating container, and includes a plurality of heat-insulating panels including a top heat-insulating panel, a bottom heat-insulating panel, and a plurality of side heat-insulating panels. One insulating panel includes a radio wave transparent non-metallic portion panel and a radio wave impermeable metal portion panel.

The heat insulating container containing contents according to the present embodiment includes the heat insulating container and the content with an IC tag contained in the heat insulating container.

The heat-insulating container containing contents according to the present embodiment includes the heat-insulating container and the content with an IC tag housed in the heat-insulating container. A cold insulator is placed between them.

The combined body of heat-insulating containers according to the present embodiment includes a first heat-insulating container and a second heat-insulating container, and the first heat-insulating container and the second heat-insulating container each include a top heat-insulating panel. , a bottom insulation panel, and a plurality of side insulation panels, the plurality of insulation panels comprising radio wave transparent non-metallic panels and radio wave non-transparent metal panels; The first heat insulating container and the second heat insulating container have different arrangement relationships between the non-metal panels and the metal panels.

In the heat insulating container assembly according to the present embodiment, the first heat insulating container and the second heat insulating container may be detachably integrated.

In the heat insulating container assembly according to the present embodiment, the first heat insulating container and the second heat insulating container may be integrated so as not to be detachable.

According to this embodiment, the IC tag placed inside the heat insulating container can be directly read from the outside.

FIG. 1 is a perspective view showing an insulated container according to one embodiment. FIG. 2 is an exploded perspective view showing an insulated container according to one embodiment. FIG. 3 is a cross-sectional view showing each heat insulating panel. 4(a) and 4(b) are cross-sectional views showing the vacuum heat insulating material of each heat insulating panel. FIG. 5 is a perspective view showing an insulated container containing contents according to one embodiment. FIGS. 6(a) to 6(d) are perspective views showing the heat insulating container according to Modification 1, respectively. FIG. 7 is a perspective view showing an insulated container according to Modification 2. FIG. FIGS. 8(a) to 8(d) are perspective views showing the heat insulating container according to Modification 3, respectively. FIG. 9 is a perspective view showing an assembly of heat insulating containers according to Modification 4. FIG. FIG. 10 is a perspective view showing an assembly of heat insulating containers according to Modification 5. FIG. FIG. 11 is a perspective view showing an assembly of heat insulating containers according to Modification 6. FIG. FIG. 12 is a perspective view showing an assembly of heat insulating containers according to Modification 7. FIG. FIG. 13 is a perspective view showing a heat insulating container containing contents according to Modification 8. FIG.

An embodiment will be described below with reference to the drawings. Each figure shown below is shown typically. Therefore, the size and shape of each part are appropriately exaggerated for easy understanding. In addition, it is possible to modify and implement as appropriate without departing from the technical idea. In addition, in each figure shown below, the same code|symbol is attached|subjected to the same part and detailed description may be partially abbreviate|omitted. In addition, numerical values such as dimensions and material names of each member described in this specification are examples as an embodiment, and are not limited to these, and can be appropriately selected and used. In this specification, terms specifying shapes and geometrical conditions, such as parallel, orthogonal, and perpendicular terms, not only have strict meanings but also include substantially the same states.

Further, in the following embodiments, the “X direction” is a direction parallel to one side of the bottom surface of the heat insulating container and parallel to the floor surface on which the heat insulating container is arranged, and the “Y direction” is the direction in the X direction. It is the direction that is vertical and parallel to the floor on which the insulated container is placed. "Z direction" is a direction parallel to the vertical direction. In addition, the “top surface” is a surface parallel to the floor surface and is the upper surface of the insulated container, and the “bottom surface” is the surface parallel to the floor surface and is the lower side of the insulated container. refers to the side of "Side surface" refers to a surface located below the top surface and above the bottom surface and perpendicular to the floor surface.

(Construction of heat-insulating container)
The configuration of the heat insulating container according to this embodiment will be described with reference to FIGS. 1 and 2. FIG. FIG. 1 is a diagram showing the structure of a heat insulating container according to this embodiment. FIG. 2 is a diagram showing a state in which each panel of the heat insulating container according to the present embodiment is removed.

As shown in FIG. 1, the heat insulating container 10 according to the present embodiment has a substantially cubic or substantially rectangular parallelepiped shape when assembled, and includes a top heat insulating panel 11, a first side heat insulating panel 12, and a There are six (plural) insulation panels 11-16, including two side insulation panels 13, a third side insulation panel 14, a fourth side insulation panel 15, and a bottom insulation panel 16.

In this specification, the top heat insulation panel 11, the first side heat insulation panel 12, the second side heat insulation panel 13, the third side heat insulation panel 14, the fourth side heat insulation panel 15, and the bottom heat insulation panel 16 may be collectively referred to as heat insulating panels 11 to 16. Also, the first side heat insulating panel 12, the second side heat insulating panel 13, the third side heat insulating panel 14, and the fourth side heat insulating panel 15 may be collectively referred to as side heat insulating panels 12-15.

Each of the heat insulating panels 11 to 16 has a main surface (a pair of widest surfaces facing opposite sides of the six surfaces forming each heat insulating panel) of approximately square or approximately rectangular shape. The top heat-insulating panel 11 and the bottom heat-insulating panel 16 face each other, and their main surfaces have substantially the same size. The first side heat insulating panel 12 and the third side heat insulating panel 14 face each other, and their main surfaces have substantially the same size. Furthermore, the second side heat insulating panel 13 and the fourth side heat insulating panel 15 are opposed to each other, and their main surfaces have substantially the same size. Each of the heat insulating panels 11 to 16 is made of a single rigid plate-like member, and is flexible and does not deform during use.

This heat-insulating container 10 can form a heat-insulating space 20 surrounded by six heat-insulating panels 11-16. Also, the six heat insulating panels 11 to 16 are provided so as to be detachable and assembled with respect to other adjacent heat insulating panels 11 to 16, respectively. Thereby, the heat insulating container 10 can be changed from an assembled state in which the heat insulating space 20 is formed to a disassembled state in which the heat insulating space 20 is not formed, and can be changed from the disassembled state to the assembled state. Therefore, when not in use, the heat-insulating container 10 can be stored and transported in a disassembled state in which it is made smaller by disassembling and stacking.

The heat-insulating container 10 is used, for example, in the distribution field for storing and transporting articles that require cold or heat insulation. In such an insulated container 10, the temperature change inside the insulated container 10 is generally suppressed as much as possible by enclosing the insulated space 20 in which articles can be stored by six insulated panels 11 to 16. configured to be

All of the six heat insulating panels 11 to 16 are heat insulating panels. In this case, the heat insulating panels 11 to 16 are vacuum heat insulating panels, each having a heat insulating portion 40 including a vacuum heat insulating material 41 (see FIG. 3), as will be described later.

In this embodiment, at least one of the six heat insulating panels 11 to 16 is a non-metallic panel that transmits radio waves. Specifically, the top heat-insulating panel 11 and the bottom heat-insulating panel 16 facing each other are nonmetallic panels that transmit radio waves. A non-metallic panel is a panel that does not substantially contain metal, and is a panel that transmits radio waves in its thickness direction (direction across a pair of main surfaces). In this case, since the top heat insulation panel 11 and the bottom heat insulation panel 16 transmit radio waves, the IC tag placed in the heat insulation space 20 can be read from the outside of the top heat insulation panel 11 by contactless communication, for example. On the other hand, the side heat insulating panels 12 to 15 are metal panels that are non-transmissive to radio waves. A metal panel is a panel that substantially contains metal, and is a panel that does not transmit radio waves in its thickness direction (direction across a pair of main surfaces). In this case, since the side heat insulating panels 12 to 15, which are metal panels, reflect radio waves, an IC tag 26 (described later) placed in the heat insulating space 20 is read from the outside of the side heat insulating panels 12 to 15, for example, by contactless communication. is practically difficult.

In each figure, for the sake of convenience, radio wave transparent non-metallic panels are shown in white, and radio wave impermeable metal panels are shown in gray. It should be noted that each non-metal panel and each metal panel may be actually colored in different colors so that the non-metal panel through which radio waves can pass can be identified visually.

In addition, in the present embodiment, the heat insulating container 10 can be assembled and disassembled, but is not limited to this. Some of the heat insulating panels 11-16 may not be assembled or disassembled. For example, the side heat insulation panels 12 to 15 and the bottom heat insulation panel 16 are integrated into a box shape so as not to be disassembled, and the top heat insulation panel 11 is detachable from the box-shaped heat insulation panels 12 to 16 like a lid. Also good.

(Composition of heat insulation panel)
Next, the configuration of each of the heat insulation panels 11-16 will be further described. In the following, "the heat insulation panels 11 to 16 are parallel (perpendicular) to a predetermined plane" means that "the main surfaces of the heat insulation panels 11 to 16 are parallel (perpendicular) to a predetermined plane. ” means.

The top heat-insulating panel 11 is a heat-insulating panel located on the top side (Z-direction plus side) and arranged parallel to the horizontal plane (XY plane). Also, the top heat insulating panel 11 is arranged above the side heat insulating panels 12-15.

The first side heat insulation panel 12 is a heat insulation panel located below the top heat insulation panel 11 and above the bottom heat insulation panel 16 and parallel to the third side heat insulation panel 14, and is positioned on the horizontal plane (XY plane). are arranged perpendicular to (parallel to the ZX plane). Also, the first side insulation panel 12 is arranged perpendicular to the second side insulation panel 13 and the fourth side insulation panel 15 .

The second side heat insulation panel 13 is a heat insulation panel located below the top heat insulation panel 11 and above the bottom heat insulation panel 16 and parallel to the fourth side heat insulation panel 15, and is positioned on the horizontal plane (XY plane). It is arranged perpendicular to (parallel to the YZ plane). Also, the second side insulation panel 13 is arranged perpendicular to the first side insulation panel 12 and the third side insulation panel 14 .

The third side heat insulation panel 14 is a heat insulation panel located below the top heat insulation panel 11 and above the bottom heat insulation panel 16, parallel to the first side heat insulation panel 12, and positioned on the horizontal plane (XY plane). are arranged perpendicular to (parallel to the ZX plane). Also, the third side insulation panel 14 is arranged perpendicular to the second side insulation panel 13 and the fourth side insulation panel 15 .

The fourth side heat insulation panel 15 is a heat insulation panel located below the top heat insulation panel 11 and above the bottom heat insulation panel 16, parallel to the second side heat insulation panel 13, and positioned on the horizontal plane (XY plane). It is arranged perpendicular to (parallel to the YZ plane). Also, the fourth side insulation panel 15 is arranged perpendicular to the first side insulation panel 12 and the third side insulation panel 14 .

The bottom heat-insulating panel 16 is a heat-insulating panel positioned on the bottom side (negative side in the Z direction) and arranged parallel to the horizontal plane (XY plane). Also, the bottom heat insulating panel 16 is arranged below the side heat insulating panels 12-15.

It is preferable that each of the heat insulating panels 11 to 16 has a thickness of, for example, 5 mm or more and 80 mm or less. In the present embodiment, the case where the heat insulating panels 11 to 16 have the same thickness will be described as an example, but the heat insulating panels 11 to 16 may have different thicknesses.

(Internal structure of heat insulation panel)
Next, the structure of each heat insulation panel 11-16 will be described. FIG. 3 is a sectional view showing the heat insulation portion 40 of each of the heat insulation panels 11-16. 4(a) and 4(b) are sectional views showing the vacuum heat insulating material 41 included in the heat insulating portion 40. FIG.

As shown in FIG. 3, the heat insulating portion 40 of each heat insulating panel 11 to 16 includes a vacuum heat insulating material 41, a foam heat insulating material 42, a heat insulating surrounding portion 43, a heat insulating material protection member 44, and a heat shield sheet 45. have.

Among these, the vacuum heat insulating material 41 is attached to the foam heat insulating material 42 . The vacuum heat insulating material 41 is composed of a core material 41a and an exterior material 41b provided around the core material 41a. A foam heat insulating material 42 is arranged on the vacuum heat insulating material 41 on the side of the heat insulating space 20 (lower side in FIG. 3). As a result, it is possible to reduce the risk of damage to the vacuum heat insulating material 41 when a load placed in the heat insulating space 20 collides with it.

The foam heat insulating material 42 can be arranged adjacent to at least the heat insulating space 20 side of the vacuum heat insulating material 41 . The foam insulation 42 may be any known foam insulation that does not contain metal, such as one or both of polyurethane foam and polystyrene foam.

The heat insulating enclosing part 43 is formed so as to surround the vacuum heat insulating material 41 . The heat insulating surrounding part 43 is arranged on the foam heat insulating material 42 and fixed to the foam heat insulating material 42 . By arranging the heat insulating enclosing part 43 so as to surround the vacuum heat insulating material 41, the heat insulation performance is improved as compared with the case where the heat insulating enclosing part 43 is not arranged. Further, it is also possible to construct a panel in which the vacuum heat insulating material 41 has substantially the same area as the foam heat insulating material 42 and the heat insulating enclosing part 43 is not used. In this case, the insulation performance can be further improved, but since there is no insulation enclosing portion 43, there is a possibility that the vacuum insulation material 41 is vulnerable to breakage due to the entry of sharp objects from the sides. A slight gap is formed between the heat insulating enclosing portion 43 and the vacuum heat insulating material 41, so that even if the size of the vacuum heat insulating material 41 slightly changes, the vacuum heat insulating material 41 can be kept outside the heat insulating material. It is designed to be housed within the enclosure 43 . The heat-insulating enclosure 43 may be made of a known foamed heat-insulating material that does not contain metal, such as one or both of polyurethane foam and polystyrene foam.

Also, the heat insulating material protection member 44 is provided on the heat insulating enclosing part 43 and mainly serves to protect the vacuum heat insulating material 41 . As the heat insulator protection member 44, for example, a metal-free organic polymer protection material can be used.

The heat shield sheet 45 is arranged so as to cover the entire outer peripheries of the vacuum heat insulating material 41 , the foam heat insulating material 42 , the heat insulating enclosing portion 43 and the heat insulating material protection member 44 . The heat shield sheet 45 can be arranged to cover the entirety of the vacuum heat insulating material 41 and the foam heat insulating material 42 .

As the heat shield sheet 45, there are those containing metal (metal heat shield sheet) and those not containing metal (non-metal heat shield sheet). Among them, the heat shield sheet 45 containing metal includes, for example, a multilayer sheet containing metal foil, a vapor-deposited sheet in which a vapor-deposited layer is formed on one side of a resin sheet, and the like. As the heat shield sheet 45 containing no metal, for example, a white film type synthetic resin heat shield sheet or the like can be used.

Next, the vacuum heat insulating material 41 will be further explained. As shown in FIG. 4A, the vacuum heat insulating material 41 is composed of a core material 41a and a sheathing material 41b having gas barrier properties, and is a heat insulating material obtained by decompressing the inside of the sheathing material 41b. FIG. 4B is another example of the vacuum heat insulating material 41 . In FIG. 4(a), voids are formed at both ends inside the vacuum heat insulating material 41, but in FIG. 4(b), no voids are formed. Voids may or may not be formed depending on the method of manufacturing the vacuum heat insulating material 41 .

As the core material 41a, a material that does not contain metal, for example, a powder such as silica, a foam such as urethane polymer, or a porous material such as fiber such as glass wool may be used.

The exterior material 41b is a member that covers the periphery of the core material 41a, and may be a flexible sheet in which a thermal adhesive layer and a gas barrier layer are laminated in order from the core material. Gas barrier layers include those containing metal (metallic gas barrier layers) and those containing no metal (non-metallic gas barrier layers). Examples of the gas barrier layer containing a metal (metallic gas barrier layer) include a metal foil or a vapor deposition sheet in which a metal vapor deposition layer is formed on one side of a resin sheet. A metal foil, for example aluminum, can be used. As the metal deposition layer, for example, aluminum, aluminum oxide, or the like can be used. Examples of the gas barrier layer containing no metal (nonmetallic gas barrier layer) include a vapor deposition sheet in which a nonmetal vapor deposition layer is formed on one side of a resin sheet. For example, an inorganic oxide such as a silicon oxide can be used as the non-metal deposition layer.

The exterior material 41b of the vacuum heat insulating material 41 or the heat shielding sheet 45 preferably has a structure that does not transmit visible light. Thereby, it is possible to suppress deterioration of the core material 41a due to the irradiation of visible light.

As described above, at least one of the six heat-insulating panels 11 to 16 of the heat-insulating container 10 is a radio wave-transmitting non-metallic panel. Specifically, the top heat insulation panel 11 and the bottom heat insulation panel 16 are each non-metallic panels that transmit radio waves. A non-metallic panel is a panel that contains substantially no metallic elements. For example, when the nonmetallic panels having the configurations shown in FIGS. are also preferably metal-free.

On the other hand, among the six heat insulating panels 11 to 16 of the heat insulating container 10, the heat insulating panels excluding the non-metallic panels are metal panels that do not transmit radio waves. Specifically, each of the side heat insulating panels 12 to 15 is a metal panel that is non-transmissive to radio waves. A metal panel is a panel at least some elements of which are made of metal elements. For example, when the metal panels having the configurations shown in FIGS. 3 and 4 are used, any one of the vacuum heat insulating material 41, the foam heat insulating material 42, the heat insulating surrounding portion 43, the heat insulating material protection member 44, and the heat shield sheet 45 is used. , preferably comprises metal elements. In particular, it is preferable that part or all of the exterior material 41b of the vacuum heat insulating material 41 and the heat shield sheet 45 contain metal elements.

Note that not all of the six heat insulating panels 11 to 16 are necessarily vacuum heat insulating panels. Some or all of the insulation panels 11-16 may be panels comprising foam insulation, such as polyurethane foam and polystyrene foam. For example, the top heat insulating panel 11 and the bottom heat insulating panel 16 may be panels containing a foam heat insulating material, and the side heat insulating panels 12 to 15 may be vacuum heat insulating panels.

(Action of this embodiment)
Next, the operation of this embodiment having such a configuration will be described.

First, as shown in FIG. 5, the side heat insulating panels 12 to 15 and the bottom heat insulating panel 16 are assembled into a box shape, and the contents 25 with IC tags are accommodated therein. This IC-tagged content 25 has an IC tag 26 on its outer surface.

The IC tag 26 is also called a contactless IC tag, RFID (Radio Frequency Identification) tag, RF tag, etc., and is an ultra-compact communication terminal in which an IC chip and a wireless antenna are sealed with resin, glass, or the like to form a tag. is. The IC tag 26 recognizes and displays the information recorded on the IC chip by recording predetermined information on the IC chip, attaching the tag to the object, and reading the recorded information on the reading device 35 side through wireless communication. It is. The IC tag 26 includes an active type with a built-in power source and a passive type without a built-in power source, and it is preferable to use the passive type. Depending on the communication frequency used, the IC tag 26 may be an electromagnetic induction system using a frequency band of 135 kHz or 13.56 MHz, or a radio wave using a frequency band such as UHF (900 MHz) or 2.45 GHz. It may be a method. The IC tag 26 may be positioned inside the content 25 with an IC tag.

After the contents 25 with IC tags are stored in the box-shaped side heat insulating panels 12 to 15 and the bottom heat insulating panel 16, the top heat insulating panel 11 is mounted on the side heat insulating panels 12 to 15 and sealed. In this way, the heat insulating container 30 containing the contents, which includes the heat insulating container 10 having the heat insulating panels 11 to 16 and the content 25 with the IC tag contained in the heat insulating container 10, is obtained. In this embodiment, such an insulated container 30 containing contents is also provided.

Subsequently, the information stored in the IC tag 26 of the content 25 with the IC tag is read using a reading device 35 such as a reader/writer. The reader 35 is arranged at a position facing the top heat-insulating panel 11, which is a non-metallic panel that transmits radio waves. In this case, since radio waves pass through the top heat insulating panel 11, wireless communication is performed between the IC tag 26 and the reader 35 (see arrow C1 in FIG. 5), and the reader 35 reads the IC chip of the IC tag 26. can recognize data recorded in

Moreover, the side heat insulating panels 12 to 15 are each made of a metal panel that is non-transmissive to radio waves. Therefore, the reflectivity of radio waves inside the side heat insulating panels 12 to 15 is enhanced, and the communication characteristics in the direction passing through the top heat insulating panel 11 can be improved.

In addition, since the side heat insulating panels 12 to 15 are each made of metal panels that are non-transmissive to radio waves, if the reader 35 were to face any one of the side heat insulating panels 12 to 15, there would be no gap between the IC tag 26 and the reader 35. It is practically difficult to carry out wireless communication in the field (see arrows C2 and C3 in FIG. 5).

As described above, according to the present embodiment, at least one heat insulating panel among the plurality of heat insulating panels 11 to 16 is a radio wave transparent non-metallic panel. As a result, the information of the IC tag 26 arranged inside the heat insulating container 10 is directly read from the outside of the heat insulating container 10 while maintaining the heat insulation, heat shielding, and airtightness of the heat insulating space 20 by the heat insulating panels 11 to 16. becomes possible.

Further, according to the present embodiment, at least one heat insulating panel among the plurality of heat insulating panels 11 to 16 is a radio wave non-transmissive metal panel. Thereby, the metal panel functions as a radio wave reflecting surface, and the reflectivity of radio waves from the IC tag 26 can be improved. As a result, the information on the IC tag 26 can be easily read outside the non-metal panel, and the probability (efficiency) of reading the IC tag 26 by the reader 35 can be improved. In addition, since metal panels generally have higher heat insulating properties and heat insulating properties than non-metallic panels, by using metal panels as part of the heat insulating panels, it is possible to suppress the deterioration of the heat insulating properties and heat insulating properties of the heat insulating container 10. can.

Further, according to the present embodiment, the two heat insulating panels facing each other (the top heat insulating panel 11 and the bottom heat insulating panel 16) among the plurality of heat insulating panels 11 to 16 are respectively non-metallic panels, and other heat insulating panels The panels (side insulation panels 12-15) are metal panels respectively. In this case, the reading direction of the IC tag 26 by the reading device 35 coincides with the normal direction of the main surface of the non-metallic panel. On the other hand, it is substantially difficult to read the information on the IC tag 26 from the direction normal to the main surface of the metal panel. In this manner, the reading direction of the IC tag 26 by the reading device 35 can be limited so that the information of the IC tag 26 can be read only from a specific direction. Specifically, in the present embodiment, the top heat insulating panel 11 and the bottom heat insulating panel 16 are each non-metallic panels, and the plurality of side heat insulating panels 12 to 15 are each metal panels. In this case, the reading direction of the IC tag 26 by the reader 35 is aligned with the normal direction (Z direction) of the main surfaces of the top heat insulation panel 11 and the bottom heat insulation panel 16, and the other directions (X direction and Y direction). It becomes practically difficult to read the information on the IC tag 26 from the point of view. In addition, since the plurality of side heat insulating panels 12 to 15 are metal panels, even if another heat insulating container 10 is arranged around the heat insulating container 10, interference by the IC tag of the other heat insulating container 10 can be prevented. can be suppressed.

Further, according to the present embodiment, the metal panel has the core material 41a and the gas barrier layer containing the metal covering the periphery of the core material 41a. can be suppressed.

Further, according to the present embodiment, the nonmetallic panel has the core material 41a and the gas barrier layer that does not contain metal and covers the periphery of the core material 41a. passes through the non-metallic panel.

(Modification)
Next, each modification will be described with reference to FIGS. 6 to 13. FIG. 6 to 13 are diagrams showing modifications. In FIGS. 6 to 13, the same reference numerals are given to the same parts as those shown in FIGS. 1 to 5, and detailed description thereof will be omitted.

(Modification 1)
In the embodiment shown in FIGS. 1 to 5, the top heat insulation panel 11 and the bottom heat insulation panel 16 of the heat insulation container 10 are each non-metal panels, and the plurality of side heat insulation panels 12 to 15 are each metal panels. Indicated. However, it is not limited to this, and as shown in FIGS. good.

For example, as shown in FIG. 6A, among the plurality of heat insulation panels 11 to 16, only the top heat insulation panel 11 is a non-metal panel, and the plurality of side heat insulation panels 12 to 15 and the bottom heat insulation panel 16 are each made of metal. It may be a panel. In this case, the information of the IC tag 26 can be read only from the top heat insulation panel 11 side (Z-direction positive side).

Further, as shown in FIG. 6B, among the plurality of heat insulating panels 11 to 16, the top heat insulating panel 11, the side heat insulating panels 12 and 14, and the bottom heat insulating panel 16 are each non-metal panels, and the side heat insulating panel 13 , 15 may each be a metal panel. In this case, the information on the IC tag 26 can be read from the direction (Z direction) passing through the top heat insulating panel 11 and the bottom heat insulating panel 16 and from the direction (Y direction) passing through the side heat insulating panels 12 and 14 . For example, two IC tags 26 are placed in the heat insulating container 10, one IC tag 26 is read from the direction (Z direction) passing through the top heat insulating panel 11 and the bottom heat insulating panel 16, and the other IC tag 26 is read from the side. It is also possible to read from the direction (Y direction) in which the heat insulating panels 12 and 14 are transmitted.

Further, as shown in FIG. 6C, among the plurality of heat insulating panels 11 to 16, the side heat insulating panels 12 and 14 facing each other are non-metallic panels, and the top heat insulating panel 11, side heat insulating panels 13, 15 and Each of the bottom insulation panels 16 may be a metal panel. In this case, the information on the IC tag 26 can be read only from the direction (Y direction) passing through the side heat insulating panels 12 and 14 . On the other hand, since the four surfaces (insulation panels 11, 13, 15, 16) around the side heat insulation panels 12, 14 are metal panels, the radio wave reflectivity is enhanced, and the direction passing through the side heat insulation panels 12, 14 is increased. (Y-direction) communication characteristics can be improved.

Also, as shown in FIG. 6(d), all of the heat insulating panels 11 to 16 may be non-metallic panels. In this case, the direction of transmission through the side insulation panels 13 and 15 (X direction), the direction of transmission through the side insulation panels 12 and 14 (Y direction), and the direction of transmission through the top insulation panel 11 and the bottom insulation panel 16 (Z direction) can be read from the IC tag 26.

(Modification 2)
FIG. 7 is a diagram showing the heat insulating container 10 according to Modification 2. As shown in FIG. In FIG. 7, a cover 38 is arranged to cover the heat insulating container 10 . The cover 38 is arranged to cover the top heat-insulating panel 11 and the side heat-insulating panels 12 to 15 of the heat-insulating container 10 . The cover 38 may have heat shielding and heat insulating properties, and may be made of, for example, a white film-based synthetic resin heat shielding sheet, or a foaming material such as polyurethane foam or polystyrene foam. Moreover, the cover 38 may be made of a flexible material, or may be made of a plurality of rigid plate-like members. At least the portion of the cover 38 that covers the nonmetallic panel is preferably made of a nonmetallic material. The portion of the cover 38 that covers the metal panel may contain a metal material, such as an aluminum deposition sheet. By covering the top heat insulating panel 11 and the plurality of side heat insulating panels 12 to 15 with the cover 38, the heat shielding and heat insulating properties of the heat insulating space 20 can be further enhanced. In addition, each panel is prevented from being wetted with water, scratched, etc., and the life of the product can be extended. Note that the cover 38 may be configured to cover not only the top heat insulating panel 11 and the plurality of side heat insulating panels 12 to 15 but also the bottom heat insulating panel 16 .

(Modification 3)
8(a)-(d) are diagrams showing the heat insulating container 10 according to Modification 3, respectively. 8(a)-(d), at least one of the plurality of heat insulating panels 11 to 16 includes a radio wave transparent non-metal portion panel 19a and a radio wave impermeable metal portion panel 19b. I'm in. The non-metal partial panel 19a is a partial panel that does not substantially contain metal, and is a panel that transmits radio waves in its thickness direction. The metal panel 19b is a panel that substantially contains metal, and is a panel that does not transmit radio waves in its thickness direction. The non-metal portion panel 19a and the metal portion panel 19b may each be a vacuum heat insulation panel or a heat insulation panel made of a foam material. Alternatively, the non-metallic portion panel 19a that transmits radio waves and the metal portion panel 19b that does not transmit radio waves may be colored in different colors so that the non-metallic portion panel 19a through which radio waves transmit can be identified visually. .

For example, as shown in FIG. 8A, the top heat insulation panel 11, the side heat insulation panels 12 and 14, and the bottom heat insulation panel 16 each include a non-metal portion panel 19a and a metal portion panel 19b, and the side heat insulation panels 13 and 15 Each may be a metal panel. In FIG. 8(a), the top insulation panel 11, the side insulation panels 12, 14 and the bottom insulation panel 16 each include two non-metal portion panels 19a and two metal portion panels 19b. These non-metal portion panels 19a and metal portion panels 19b are arranged in a grid pattern (checkered pattern). In this case, since the non-metal portion panel 19a and the metal portion panel 19b are arranged in a lattice pattern, the transmission direction of radio waves from the IC tag 26 is further limited, and the place where communication with the IC tag 26 is possible is limited. can do. Further, by reducing the area of the non-metallic portion panel 19a, deterioration of the heat insulating performance of the heat insulating container 10 can be suppressed.

Also, as shown in FIG. 8(b), the side heat insulating panels 12 and 14 facing each other include a non-metallic portion panel 19a and a metal portion panel 19b, respectively, and the top heat insulating panel 11, the side heat insulating panels 13 and 15, and the bottom heat insulating panel. Each panel 16 may be a metal panel. In FIG. 8(b), the side insulating panels 12, 14 each include two non-metallic part panels 19a and two metallic part panels 19b. These non-metal portion panels 19a and metal portion panels 19b are arranged in a grid pattern (checkered pattern). In this case, the information on the IC tag 26 can be read only from the normal direction (Y direction) of the side heat insulating panels 12 and 14 . Also, the transmission direction of radio waves from the IC tag 26 can be further limited. Furthermore, deterioration of the heat insulating performance of the heat insulating container 10 can be suppressed.

Also, as shown in FIG. 8(c), all of the plurality of heat insulating panels 11-16 may each include a non-metal portion panel 19a and a metal portion panel 19b. In FIG. 8(c), the insulation panels 11-16 each include a non-metallic portion panel 19a and a metallic portion panel 19b. Among these, the non-metal portion panel 19a has a substantially rectangular shape in a plan view, and is positioned in the center of each heat insulating panel 11-16. A metal portion panel 19b having a substantially square square shape in plan view surrounds the outer periphery of the non-metal portion panel 19a. In this case, the information on the IC tag 26 can be read from all normal directions of the main surfaces of the heat insulating panels 11 to 16 (X direction, Y direction and Z direction). In addition, the transmission direction of radio waves from the IC tag 26 can be limited to the in-plane central portion of each heat insulating panel 11-16. Furthermore, deterioration of the heat insulating performance of the heat insulating container 10 can be suppressed.

Also, as shown in FIG. 8(d), the top heat insulation panel 11, the side heat insulation panels 12 and 14, and the bottom heat insulation panel 16 each include a non-metal portion panel 19a and a metal portion panel 19b, and the side heat insulation panels 13 and 15 Each may be a metal panel. In FIG. 8(d), the top heat insulating panel 11, the side heat insulating panels 12, 14 and the bottom heat insulating panel 16 each include one non-metal portion panel 19a and one metal portion panel 19b. The non-metal portion panel 19a and the metal portion panel 19b are substantially rectangular in plan view and have the same size, and are arranged side by side. In this case, since the non-metal portion panel 19a and the metal portion panel 19b are arranged side by side, it is possible to further limit the transmission direction of radio waves from the IC tag 26 and limit the place where communication with the IC tag 26 is possible. can be done. Moreover, deterioration of the heat insulating performance of the heat insulating container 10 can be suppressed.

(Modification 4)
FIG. 9 is a diagram showing an assembly 50 of a plurality (three) of heat insulating containers according to Modification 4. As shown in FIG. In FIG. 9, an insulated container assembly 50 includes a first insulated container 10A, a second insulated container 10B, and a third insulated container 10C. The first heat-insulating container 10A, the second heat-insulating container 10B, and the third heat-insulating container 10C (collectively referred to as heat-insulating containers 10A to 10C) each include a top heat-insulating panel 11, a bottom heat-insulating panel 16, and a plurality of side insulation panels 12-15 and a plurality of insulation panels 11-16. For example, the first insulated container 10A contains frozen contents, the second insulated container 10B contains refrigerated contents, and the third insulated container 10C contains room temperature contents. May be.

In FIG. 9, the heat insulating panels 11 to 16 of the first heat insulating container 10A and the second heat insulating container 10B each include a radio wave transparent non-metal panel and a radio wave impermeable metal panel. In this case, the arrangement positions of the nonmetallic panels and the metal panels of the first heat insulating container 10A and the arrangement positions of the nonmetallic panels and the metal panels of the second heat insulating container 10B are different from each other. That is, in the first heat-insulating container 10A, the top heat-insulating panel 11 and the bottom heat-insulating panel 16 are each non-metallic panels, and the side heat-insulating panels 12 to 15 are each metal panels. In the second heat-insulating container 10B, the side heat-insulating panels 12 and 14 facing each other are non-metal panels, and the top heat-insulating panel 11, side heat-insulating panels 13 and 15, and bottom heat-insulating panel 16 are metal panels. The heat insulating panels 11 to 16 of the third heat insulating container 10C are all made of metal panels.

In this way, the arrangement relationships of the nonmetallic panels and the metallic panels are different among the heat insulating containers 10A to 10C. As a result, the first reader 35A arranged on the top heat insulation panel 11 side can read the information of the IC tag 26 housed in the first heat insulation container 10A. On the other hand, the first reader 35A cannot read the information of the IC tags 26 housed in the second heat insulating container 10B and the third heat insulating container 10C. Further, the second reader 35B arranged on the side of the side insulation panel 12 can read the information of the IC tag 26 accommodated in the second insulation container 10B. On the other hand, the second reader 35B cannot read the information of the IC tags 26 housed in the first heat insulating container 10A and the third heat insulating container 10C.

In this way, the first reader 35A and the second reader 35B can selectively read the IC tags 26 of the specific heat-insulating containers 10A and 10B by utilizing the difference in the radio wave transmission direction of the individual heat-insulating containers 10A-10C. can be read. This suppresses interference from the IC tags 26 of the insulated containers 10A to 10C that are not to be read, and prevents the first reader 35A and the second reader 35B from erroneously reading the IC tags 26 that are not to be read. can be done. Also, for example, it is possible to detect that the content that should be stored in the first heat insulating container 10A is mistakenly stored in the second heat insulating container 10B. As a result, it is possible to find the contents stored in the wrong heat insulating container, and to prevent the problem that the contents are transported while being stored in the wrong heat insulating container.

Further, in FIG. 9, the nonmetallic panels and the metal panels of the heat-insulating containers 10A to 10C may be colored in different colors so that the nonmetallic panels through which radio waves can pass can be visually identified.

Furthermore, the arrangement of the radio-wave-permeable nonmetallic panels of the heat-insulating container may be changed so as to change the communication direction for each reader that reads radio waves of different frequency bands. Examples of the frequency band include 2.4 GHz band, 900 MHz band, 135 kHz band, and the like. By putting the contents with IC tags corresponding to these different frequency bands into an insulated container in which radio wave transparent non-metallic panels corresponding to the predetermined frequency bands are arranged, each different frequency band has a fixed direction. The IC tag can be read from the container, and erroneous detection of other heat-insulated containers can be prevented.

(Modification 5)
FIG. 10 is a diagram showing an assembly 50 of a plurality (three) of heat insulating containers according to Modification 5. As shown in FIG. In FIG. 10, an insulated container assembly 50 includes a first insulated container 10A, a second insulated container 10B, and a third insulated container 10C. Among these heat insulating containers 10A to 10C, the arrangement relationships of the nonmetallic panels and the metallic panels are different from each other. In this case, unlike the example shown in FIG. 9, the heat insulating containers 10A to 10C are integrated with each other. In addition, a connecting member 27 such as a double-sided tape, an adhesive, or a hook-and-loop fastener is provided between adjacent heat-insulating panels of the heat-insulating containers 10A-10C. fixed in a non-detachable manner. Specifically, a connecting member 27 connects the second side heat insulating panel 13 of the first heat insulating container 10A and the fourth side heat insulating panel 15 of the second heat insulating container 10B. A connecting member 27 connects the second side heat insulating panel 13 of the second heat insulating container 10B and the fourth side heat insulating panel 15 of the third heat insulating container 10C.

In this case, it is possible to fix the orientation of the radio wave transparent non-metallic panels of the heat insulating containers 10A to 10C and the arrangement of the heat insulating containers 10A to 10C. This can prevent mistakes such as placing the heat insulating containers 10A to 10C in the wrong positions or misorienting the non-metallic panels of the heat insulating containers 10A to 10C. In addition, for example, when the contents of different temperature zones are stored in the heat-insulating containers 10A to 10C, the contents of a plurality of temperature zones to be delivered to the same place will not be lost. Incorrect reading direction can be prevented. Furthermore, when the heat insulating containers 10A to 10C are detachably fixed by the connecting member 27, the heat insulating containers 10A to 10C are used individually (for example, as a cold box), and the heat insulating containers 10A to 10C are used by connecting them. You can switch between cases at will. As a result, the degree of freedom of use of the heat insulating containers 10A to 10C is increased, and the required number of the heat insulating containers 10A to 10C can be reduced.

(Modification 6)
FIG. 11 is a diagram showing an assembly 50 of a plurality (three) of heat insulating containers according to Modification 6. As shown in FIG. In FIG. 11, an insulated container assembly 50 includes a first insulated container 10A, a second insulated container 10B, and a third insulated container 10C. Among these heat insulating containers 10A to 10C, the arrangement relationships of the nonmetallic panels and the metallic panels are different from each other. Also, the heat insulating containers 10A to 10C are integrated with each other so as not to be detachable. In FIG. 11, unlike the example shown in FIG. 10, the combined body 50 has a configuration in which the interior of the integrated container is divided into a plurality of regions (insulated containers 10A to 10C) by partition plates 17A and 17B. The partition plate 17A is made of a radio-impermeable metal panel, and serves also as the second side heat insulation panel 13 of the first heat insulation container 10A and the fourth side heat insulation panel 15 of the second heat insulation container 10B. The partition plate 17B is made of a radio-impermeable metal panel, and serves also as the second side heat insulating panel 13 of the second heat insulating container 10B and the fourth side heat insulating panel 15 of the third heat insulating container 10C. The partition plates 17A and 17B may be fixed, or may be detachable so that the internal spaces can be connected and used.

In this case, it is possible to fix the orientation of the radio wave transparent non-metallic panels of the heat insulating containers 10A to 10C and the arrangement of the heat insulating containers 10A to 10C. This can prevent mistakes such as placing the heat insulating containers 10A to 10C in the wrong positions or misorienting the non-metallic panels of the heat insulating containers 10A to 10C.

(Modification 7)
FIG. 12 is a diagram showing an assembly 50 of a plurality (three) of heat insulating containers according to Modification 7. As shown in FIG. In FIG. 12, an insulated container assembly 50 includes a first insulated container 10A, a second insulated container 10B, and a third insulated container 10C. Among these heat insulating containers 10A to 10C, the arrangement relationships of the nonmetallic panels and the metallic panels are different from each other. Also, the heat insulating containers 10A to 10C are detachably integrated with each other. In FIG. 12, the insulated containers 10A-10C can be used independently of each other. Also, the heat insulating containers 10A to 10C are housed in an outer box 36 that surrounds the heat insulating containers 10A to 10C as a whole. The outer box 36 is made of radio wave transparent material as a whole and has a box body 36a and a lid 36b covering the box body 36a.

In this case, it is possible to fix the orientation of the radio wave transparent non-metallic panels of the heat insulating containers 10A to 10C and the arrangement of the heat insulating containers 10A to 10C. In addition, the heat-insulating containers 10A to 10C can be transported as a unit while being housed in the outer box . 12, the heat insulating containers 10A to 10C may be detachably fixed by connecting members 27 as in the example shown in FIG. Further, instead of the outer box 36, a flexible bag-like exterior material may be used to cover the heat insulating containers 10A to 10C. Furthermore, each of the top heat insulation panels 11 of the heat insulation containers 10A to 10C may be attached to the lid 36b of the outer box 36.

(Modification 8)
13A and 13B are diagrams showing a heat insulating container 30 containing contents according to Modification 8. FIG. In FIG. 13, a cold insulator 28 is placed between a nonmetallic panel (in this case, the top heat insulating panel 11) of the heat insulating container 10 and the content 25 with an IC tag. The cold insulator 28 contains at least one of a cold insulator and a heat insulator, and can be in the form of a water-containing gel, for example. In general, the cold insulator 28 containing moisture transmits radio waves when frozen, and does not transmit radio waves when melted. For this reason, an attempt is made to read the information of the IC tag 26 using the reader 35 from the top heat insulation panel 11 side. 28 can be determined to be melted. As a result, it is possible to determine whether the cold insulator 28 is frozen or melted without opening the heat insulating container 10.例文帳に追加

It is also possible to appropriately combine a plurality of constituent elements disclosed in the above embodiments and modifications as necessary. Alternatively, some components may be deleted from all the components shown in the above embodiments and modifications.

10 heat insulation container 11 top heat insulation panel 12 first side heat insulation panel 13 second side heat insulation panel 14 third side heat insulation panel 15 fourth side heat insulation panel 16 bottom heat insulation panel 19a nonmetal part panel 19b metal part panel 20 heat insulation space 25 IC Content with tag 26 IC tag 30 Thermal insulation container containing content 35 Reader 40 Thermal insulation part 41 Vacuum insulation material 41a Core material 41b Exterior material 42 Foam insulation material 43 Thermal insulation surrounding part 44 Thermal insulation protection member 45 Thermal insulation sheet 50 Combined body

Claims (10)

an insulated container,
a plurality of insulation panels including a top insulation panel, a bottom insulation panel, and a plurality of side insulation panels,
The plurality of heat insulating panels includes a radio wave transparent non-metallic panel and a radio wave non-transmissive metal panel,
The heat-insulating container, wherein the non-metallic panel includes a vapor-deposited sheet in which a non-metallic vapor-deposited layer is formed on one side of a resin sheet, and the non-metallic panel as a whole has radio wave transparency. 2. The insulated container according to claim 1 , wherein two of said plurality of insulated panels facing each other are said non-metallic panels, and the other insulated panels are each said metallic panels. 3. The insulated container according to claim 1 , wherein the top heat- insulating panel and the bottom heat-insulating panel are the non-metallic panels, and the plurality of side heat-insulating panels are the metal panels. 4. The insulated container according to any one of claims 1 to 3 , wherein said metal panel has a core material and a metal gas barrier layer surrounding said core material. 5. The insulated container according to any one of claims 1 to 4 , wherein said non-metallic panel has a core material and a non-metallic gas barrier layer surrounding said core material. The insulated container according to any one of claims 1 to 5 ;
and a content with an IC tag housed in the heat insulating container. The insulated container according to any one of claims 1 to 5 ;
a content with an IC tag housed in the heat insulating container,
An insulated container containing a content, wherein a cold insulator is placed between the non-metallic panel of the insulated container and the content with the IC tag. a first insulated container;
a second insulated container;
Each of the first insulated container and the second insulated container is
having a plurality of heat insulating panels including a top heat insulating panel, a bottom heat insulating panel, and a plurality of side heat insulating panels;
The plurality of heat insulating panels includes a radio wave transparent non-metallic panel and a radio wave non-transmissive metal panel,
An assembly of heat-insulating containers, wherein the first heat-insulating container and the second heat-insulating container have different arrangement relationships between non-metallic panels and metal panels. 9. The combined body of insulated containers according to claim 8 , wherein said first insulated container and said second insulated container are detachably integrated. 9. The combined body of insulated containers according to claim 8 , wherein said first insulated container and said second insulated container are non-detachably integrated.

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