JP2003343970A - Storage unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a storage unit capable of easily attaching a drain pan to a predetermined position. <P>SOLUTION: The number 50 in the drawing indicates a base foot on a bottom face of a thermal insulation vessel 1. The base feet 50 are arranged forward and backward in two sections and symmetrically on the right and left sides, namely, in four sections in total. This base foot 50 is composed of an upper part 52 and a lower part 51 provided with a screw 53. Moreover, the base foot 50 is fixed by screwing the lower part 51 into a bottom wall of the thermal insulation vessel 1 while the upper part 52 is sandwiched between the thermal insulation vessel 1 and it. Furthermore, a step difference part 54 having a difference in steps H of such extent that it is slightly larger than height of the drain pan 41 is formed in the upper part 52. The base feet are arranged in such a way that the step difference parts 54 of the base feet 50 on the right and left sides face each other. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a storage cabinet in which the interior of a cabinet is kept cold or kept warm by a thermo module composed of a Peltier device to store beverages in cold storage or foods in low temperature storage.

[0002]

2. Description of the Related Art As a storage for keeping the inside of a storage of foods and drinks cold or warm by a thermo module, for example, the storage described in JP-A-10-325664 is known. This conventional device includes a heat insulating container for storing stored items at a predetermined temperature, a thermo module disposed on the rear wall of the heat insulating container, and a surface on the inside of the thermo module (heat exchange surface on the use side). It has an attached heat sink for heat absorption, and a heat sink for exhaust heat attached to a surface (heat source side heat exchange surface portion) on the outer side of the thermomodule. Then, the heat in the refrigerator is transferred to the outer surface of the refrigerator by the thermo module via the heat sink for heat absorption, and the moved heat is released to the outside of the refrigerator via the heat sink for heat dissipation. A cover portion having an intake port and an exhaust port is attached to the outside to form a cooling air passage. Although not described in the above publication, generally, a drain pan for receiving the drain generated in the refrigerator was directly arranged on the floor surface below the heat insulating container.

[0003]

However, in such a storage cabinet, since the drain pan is directly placed on the floor, the position of the drain pan is not fixed, and it is difficult to fix the drain pan at a predetermined position. It was

The present invention has been made in view of the above problems existing in such a conventional technique, and it is an object of the present invention to provide a storage box in which a drain pan can be easily attached to a predetermined position. To aim.

[0005]

In order to achieve the above object, the present invention provides a heat insulating container for storing stored items at a predetermined temperature, cooling means for cooling the inside of the heat insulating container, and inside the heat insulating container. In a storage cabinet provided with a drain pan for receiving the drain generated in the lower part of the heat insulating container, four foot legs are provided on the lower surface of the heat insulating container so that two pieces are arranged on each of the left and right when viewed from the front, Further, a step portion is provided on each of the four legs, and the drain pan can be slidably mounted from the front between the step portion and the lower surface of the heat insulating container.

[0006]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described in detail below with reference to FIGS. In each embodiment, the same or common parts are designated by the same reference numerals, and the description thereof will be simplified.

Embodiment 1. Therefore, first, the first embodiment
Will be described with reference to FIGS. Reference numeral 1 is a heat insulating container provided with an inner box 2, an outer box 3, and a heat insulating material 4 injected so as to be interposed between the inner box 2 and the outer box 3. This inner box 2
Is made of an aluminum-based metal plate that has good thermal conductivity and is resistant to corrosion. The outer case 3 is made of plastic, and is divided into a front outer case 3a and a rear outer case 3b in the first embodiment, and as shown in FIGS. The front end of the box 3b serves as a narrowed portion, and is fitted inside the front outer box 3a to be integrally connected. An opening is provided on the front surface of the heat insulating container 1, and an opening / closing door 5 is provided at the opening.

Reference numeral 10 denotes a thermo module comprising a Peltier element 10a, a utilization side heat exchange surface portion 10b and a heat source side heat exchange surface portion 10c. In the rear wall of the heat insulating container 1, a storage hole having a size substantially the same as that of the thermo module 10 is formed by penetrating the outer box 3 and the heat insulating material 4 and leaving the metal plate forming the inner box 2 in the storage hole. A module 10 is provided. A state in which a heat transfer block 11 made of an aluminum alloy having good heat conductivity is interposed between the thermo module 10 and the inner box 2, and the heat transfer block 11 is heat-transferred to the inner box 2 by screwing. Is joined to. In addition, the heat exchange surface portion 10b on the use side of the thermo module 10 and the inner box 2
And are joined so that heat can be transferred through the heat transfer block 11. The heat transfer block 11 is integrally fixed to the heat insulating container 1 by injecting the heat insulating material 4. The thermo module 10 is detachably fixed to the heat transfer block 11 from the rear surface side with screws or the like. Further, a concave surface slightly larger than the heat transfer block 11 is provided at a position corresponding to the heat transfer block 11 on the inner surface of the inner box 2, and a heat insulating sheet 2a made of a heat insulating member such as polypropylene is attached to the concave surface. . The depth of this concave surface is
The thickness of the heat insulating sheet 2a is substantially equal to that of the heat insulating sheet 2a.

A heat sink 12 is joined to the heat source side heat exchange surface portion 10c of the thermo module 10 in a heat conductive manner. The heat sink 12 has a large number of aluminum fins 12a arranged in a lateral direction so as to flow the outside air from the right side to the left side (from the left side to the right side when viewed from the rear side) when viewed from the front side so that heat is exchanged. Is configured. Further, 13 is an air passage forming plate that covers the heat sink 12, 14 is a back surface that covers not only the air passage forming plate 13 but also the entire back surface of the heat insulating container 1, and forms an outside chamber on the outer side of the rear wall of the heat insulating container 1. It is a cover. Therefore, this back cover 1
4 is formed in a substantially box shape with an open front surface. The rear corners of the left and right side surfaces 14a, 14b of the rear cover 14 are inclined surface portions that incline toward the center in the left-right direction toward the rear.
The rear corners of c and 14d are also inclined surfaces that incline toward the center in the vertical direction. And this back cover 1
4, an intake port 15 is formed on the inclined surface portion of the right side surface portion 14a, and an exhaust port 16 is formed on the inclined surface portion of the left side surface portion 14b when viewed from the front. Further, the auxiliary intake port 15a of the intake port 15 is in the right half of the lower surface part 14d of the rear cover 14 when viewed from the front, and the auxiliary exhaust port 16a of the exhaust port 16 is in the left half when viewed from the front. Has been formed.

The air passage forming plate 13 has upper and lower surface portions 13c,
13d is formed in a horizontal plane, and the right side surface portion 13 is seen from the front.
a is an inclined surface portion that is substantially parallel to the inclined surface portion of the right side surface portion 14a of the back cover 14. Two axial flow fans 20 are attached to the rear cover 14 side of the right side surface 13a so as to face the right side surface of the rear cover 14 with a vertical interval. The right side surface portion 13a
There are two fan guide holes for the axial blower 20 on the inclined surface of the
Two axial blowers 20 are attached so that the outside air flows through the air passage forming plate 13 from the right to the left through the guide holes. The left side surface portion 13b of the air passage forming plate 13 is bent backward, and is extended until its tip comes into contact with the rear end portion of the left side surface portion 14b of the back cover 14. Further, on the back side of the back surface portion 13e of the air passage forming plate 13, a control board 31 in which the control circuit components of the storage are arranged is attached. Further, right and left upright pieces 14e and 14f and upright upright pieces 14g and 14h are erected from the rear cover 14 so as to block the left and right and up and down of the control board 31 in the back surface portion 13e of the air passage forming plate 13. As a result, a storage portion for the control board 31 is formed.

On the upper side of the air duct forming plate 13 and on the back surface of the heat insulating container 1, there is attached a power supply board 32 on which the power supply circuit components of the storage are arranged. Further, a protective cover 33 formed by a surface portion parallel to the inclined surface portion of the upper surface portion 14c of the back cover 14 and a surface portion parallel to the back surface of the back cover 14 is attached, and the protection cover 33, the back surface of the heat insulating container 1, and the wind. A storage chamber for the power supply board 32 is formed by the upper surface portion 13c of the passage forming plate 13. A communication hole 17 composed of a plurality of holes is provided in the upper surface portion 13c of the air passage forming plate 13, and a part of the outside air flowing through the air passage forming plate 13 is introduced into the storage chamber of the power supply board 32. is doing. The bottom wall of the heat insulating container 1 is provided with a drainage port 42 for guiding the drain water formed on the inner surface of the inner box 2 to a dish-shaped drain pan 41 arranged below the heat insulating container 1. There is.

As shown in FIG. 7, 50 is a foot on the bottom surface of the heat insulating container 1. This foot 50 is 2 front and back
The parts are arranged symmetrically, that is, at a total of four positions. The foot 50 has an upper part 52 and a screw 5 respectively.
3 and a lower part 51 provided with 3. Further, the foot 50 is fixed by screwing the lower part 51 to the bottom wall of the heat insulating container 1 with the upper part 52 sandwiched between the heat insulating container 1 and the upper part 52. Further, the upper part 52 has a step portion 5 having a step H that is slightly larger than the height dimension of the drain pan 41.
4 are formed. Then, the stepped portions 54 of the left and right foot legs 50 are arranged so as to face each other.

The drain pan 41 has a substantially T-shaped horizontal plane, and the width of the front part is larger than that of the rear part.
The drain capacity can be increased. The dimension L between the step portions 54 of the left and right foot 50 is formed to be slightly larger than the rear width dimension of the drain pan 41. With this configuration, the drain pan 41 is slidably inserted and attached at the rear portion thereof between the step portion 54 of the foot 50 and the bottom surface of the heat insulating container 1 so as to be freely inserted and removed. Further, the drain pan 41 is formed so as to be arranged at a predetermined position by sliding the drain pan 41 to a position where the rear edge of the front portion thereof comes into contact with the front foot 50 and inserting the drain pan 41. At this time, the rear end portion of the drain pan 41 extends rearward from the rear edge of the heat insulating container 1. Also,
Ventilation holes 18 are formed in the horizontal portion of the lower surface of the back cover 14 located above the extending portion of the drain pan 41, and a part of the outside air flowing through the inside of the back cover 14 flows inside the drain pan 41. It is designed to be distributed.

The opening / closing door 5 on the front of the heat insulating container 1 is
An outer plate 5a having a hollow space therein, and a heat insulating material 5c injected into the hollow inside of the outer plate 5a, which has a heat insulating performance. The opening / closing door 5. The opening / closing door 5 is pivotally supported by an upper hinge 60 on the upper right part and a lower hinge 70 on the lower right part so as to be openable and closable so as to open to the right when viewed from the front (FIGS. 1 and 9 to 14).
reference). Further, a locking mechanism such as a magnet is provided at the front end of the left end of the outer box 3 facing the left end portion of the open / close door 5, so that the open / close door 5 can be held in a closed state. Further, as shown in FIG. 1 and FIG. 2, 80 is the opening / closing door 5 in consideration of the design.
A long and vertically long operation panel is installed in the center of the
An operation part 82 for setting and displaying the temperature inside the storage is formed in a portion corresponding to the operation board 81 on which the control circuit components of the storage inside the storage compartment are arranged.

The details of the mounting portion of the upper hinge 60 are shown in FIGS. 9 to 11, but the upper body side hinge 61 and the like are constructed so as not to protrude to the side or the upper and lower sides of the opening / closing door 5 and the heat insulating container 1. ing. The upper body side hinge 61 is made of a plastic material and is fixed to the heat insulating container 1 by a screw (not shown). Further, a shaft support hole 62 is provided in the shaft support portion of the main body side hinge 61. Reference numeral 63 denotes a plastic pivot pin, which is shown in a state of being removed from the opening / closing door 5 in FIG. 9, but is actually fixed to the opening / closing door 5 side and is rotatably supported in the pivot support hole 62. Has been done. Further, reference numeral 64 is a notch provided at a corner portion of the opening / closing door 5, so that when the opening / closing door 5 is opened to a predetermined angle as shown in FIG. 11, the main body side hinge 61 hits the opening / closing door 5. Are avoiding. Further, the notch 64 is provided so as not to impair the external appearance even when viewed from the front side or the right side of the opening / closing door 5 even in the middle of the side portion of the opening / closing door 5.

The details of the mounting portion of the lower hinge 70 are shown in FIGS. 12 to 14, but the lower main body side hinge 71 is made of a metal member, and in order to increase the strength, in this embodiment, the iron plate is squeezed downward. It has a U-shaped cross section. In addition, a shaft support pin 72 having a through hole 73 for supporting the lower surface of the opening / closing door 5 is provided at the tip of the lower body side hinge 71. Further, the mounting portion of the lower hinge 70 to the heat insulating container 1 is formed as a recess 74 opened downward so as not to be seen from the side, and the lower hinge 70 is screwed and fixed to the heat insulating container 1 from below. ing. Further, as shown in FIG. 14, a cutout 75 is formed in a corner portion of the opening / closing door 5 leaving the front wall so that the opening / closing door 5 can be opened to a predetermined angle. The electric wire 85 is passed through the inside of the U-shaped section of the main body side hinge 71 and the through hole 73 of the shaft support pin 72 so that the electric wire 85 is less twisted to the operation panel 80 when the opening / closing door 5 is opened. It is passed from the heat insulating container 1 side to the opening / closing door 5 side.

Next, the operation of the storage configured as described above will be described. The operator selects a set temperature in the storage (for example, an arbitrary temperature of 0 to 50 ° C.) with the operation unit 82, and operates the storage. At this time, the direction in which the direct current is applied to the thermomodule 10 is selected according to the relationship between the outside air temperature, the temperature of the stored items, and the set temperature inside the refrigerator, and the use side heat exchange surface portion 10b of the thermomodule 10 absorbs or absorbs heat. As the heat is radiated, the axial blower 20 is operated, the outside air is sucked from the intake port 15 and the auxiliary intake port 15a, flows through the air passage forming plate 13, and is discharged from the exhaust port 16 and the auxiliary exhaust port 16a. To be done. As a result, in the heat insulating container 1, the inner box 2 of the heat insulating container 1 is cooled or heated via the heat transfer block 11, and the inside of the heat insulating container 1 is controlled to a predetermined temperature. In the heat source side heat exchange surface portion 10c of the thermo module 10, heat is radiated or absorbed between the outside air flowing through the air passage forming plate 13 via the heat sink 12 and the heat is absorbed or radiated in the heat insulating container 1. The amount of heat is radiated or absorbed by the outside air.

When the set temperature in the refrigerator is low, the inside of the heat insulating container 1 is cooled from the surface of the inner box 2 so that the drain water condensed on the surface of the inner box 2 falls on the bottom surface of the inner box 2. Then, the water is drained from the drain port 42 to the drain pan 41. Then, the drain water stored in the drain pan 41 is promoted to be naturally evaporated by the outside air flowing out from the ventilation holes 18 formed in the lower surface portion of the back cover 14. Further, during the operation of the storage, a part of the outside air flowing through the air passage forming plate 13 is introduced into the storage chamber of the power supply substrate 32 from the communication hole 17 formed in the upper surface portion 13c of the air passage forming plate 13. The power supply board 32 is cooled to prevent the power supply board 32 from overheating.

Since the first embodiment is configured as described above, even if the back surface of the storage, or the back and left and right sides of the storage, approach or contact the wall surface of the building, the back The rear corners of the left and right side surfaces 14a and 14b of the cover 14 are formed as inclined surface portions that are inclined inward, and the intake port 15 and the exhaust port 16 are formed in the inclined surface portions. The space does not block the intake port and the exhaust port 16. Further, since the inclined surface portions are provided at the rear corners of the upper and lower surface portions 14c and 14d of the rear cover 14, the air passages communicating with the intake port 15 and the exhaust port 16 are secured along the inclined surface portions. As a result, the outside air can be smoothly distributed in the air passage forming plate 13. It should be noted that it may be possible to provide an intake port or an exhaust port on the upper surface of the rear cover 14 in order to smoothly flow the air outside the refrigerator, but in this case, there is a drawback that dust easily enters. In addition, since there is a need to reduce the required floor area in the storage cabinet, there is a tendency that it is easily accepted by the market even if the horizontal dimension is reduced and the height dimension is increased. Therefore, providing the intake port and the exhaust port on the left and right side surfaces 14a and 14b has the advantage that the size of the intake port and the exhaust port can be increased. Further, two axial flow blowers 20 are used as blowers for circulating the outside air in the outdoor chamber, and the two axial flow blowers 2 are used.
Since 0 is provided so as to face the right side surface portion 14a of the back cover 14, the depth dimension of the storage can be made compact.

The right and left side portions 14 of the rear cover 14
By sloping the rear corners of a and 14b and sloping the rear corners of the upper and lower surface parts 14c and 14d of the rear cover 14, the design effect that makes the depth dimension of the storage cabinet feel small is exhibited. To be done. In addition, the upper and lower surface portions 14
Air passages to the intake port 15 and the exhaust port 16 are secured along the inclined surface portions of c and 14d, so that the outside-compartment air can more smoothly flow in the outside-compartment. Further, since the auxiliary intake port 15a and the auxiliary exhaust port 16a are provided on the inclined surface portion that can be placed on the lower surface portion 14d of the rear cover 14, the outside air in the outside compartment can flow more smoothly.

Further, the heat exchange surface portion 10b on the use side of the thermo module 10 is heat-transferably attached to the inner box 2 made of aluminum-based metal via the heat transfer block 11 so as to cool or heat the inside of the heat insulating container 1. Therefore, the structure is simplified and the effective storage space in the heat insulating container 1 is expanded. Moreover, since the concave surface is formed in the inner surface portion of the inner box 2 corresponding to the heat transfer block 11 and the heat insulating sheet 2a is attached to this portion, the heat insulating effect of the heat insulating sheet 2a causes
Condensation of this portion is prevented, and the stored items near this portion are not locally supercooled or heated. Moreover, since the heat insulating sheet 2a is attached to the concave portion,
During the attaching work, the confirmation work of the attaching position of the heat insulating sheet 2a becomes easy.

In addition, since a part of the outside air flowing through the outside chamber is circulated in the storage chamber of the power substrate 32 in which the power circuit components are arranged, the power substrate 32 is always cooled. , There is no danger of overheating. In addition, this power supply board 32
Is disposed above the upper surface portion 13c of the air passage forming plate 13, so that foreign matter such as dust is less accumulated than when the air passage forming plate 13 is disposed below the air passage forming plate 13, and the power supply board 3
2 improves reliability.

Further, the back cover 14 is raised from the rear cover 14
e, 14f, 14g, 14h are erected, and the air passage forming plate 13
Control board 31 attached to the rear part 13e of the
Since the storage chamber is formed, the control board 31 is protected from foreign matters such as dust, and the reliability of the control board is improved. In addition, the rising pieces 14e, 14f, 14
g and 14h have a function of improving the strength of the back cover 14, and further have a function of smoothly guiding the outside air sucked from the intake ports 15 and 15a into the air passage forming plate 13. Further, by removing the back cover 14, maintenance of the control board 31 can be easily performed.

Further, since the drain pan 41 is slidably mounted, it can be easily removed for cleaning or the like. In addition, since a part of the outside air flowing through the outside chamber is poured into the drain pan 41 through the ventilation hole 18 provided in the lower surface portion 14d of the back cover 14, the drain water is positively evaporated by the outside air. To be done. Therefore, drain pan 4
From 1, there is no drain water. Further, since the upper hinge 60 and the lower hinge 70 do not protrude to the left, right, up and down, the appearance is not impaired in design when viewed from the front.

Embodiment 2. The second embodiment is shown in FIG.
5, the left and right side surface portions 14a of the rear cover 14,
14b does not have an inclined surface portion at the rear corner portion, but extends straight rearward in the same direction as the left and right side surface portions of the heat insulating container 1, and the intake port 15 is formed on the left and right side surface portions 14a and 14b thus formed.
And the exhaust port 16 is provided. Even with this structure, the intake port 15 and the exhaust port 16 are not covered by the rear cover 14.
As long as it is formed on the left and right side surfaces of the storage compartment, even if the wall surface is installed close to the back surface of the storage cabinet, the outside air flow in the air duct forming plate 13 can be performed smoothly.

Embodiment 3. The third embodiment is shown in FIG.
6, the left and right side surface portions 14a of the rear cover 14,
Similarly to the second embodiment, 14b is straightly extended rearward, and the right side surface portion 13a of the air passage forming plate 13 is also
First, the back cover 14 is inclined and extended, and then, the back cover 14 is folded back straight forward at the position of the inner surface of the back cover 14, and the axial blower 20 is attached to the right side surface portion 13a thus formed. In this way, since the axial blower 20 is not attached so as to be inclined, the depth dimension of the back cover 14 increases, but the wall surface approaches the back surface of the storage as in the first and second embodiments. Even when installed in this state, the outside air flow in the air duct forming plate 13 is smoothly performed.

Fourth Embodiment In the fourth embodiment, as in each of the above-described embodiments, the heat absorption or heat dissipation in the use-side heat exchange surface portion 10b of the thermo module 10 is thermally conducted to the inner box 2 via the solid heat transfer block 11. Instead of cooling or heating the inside of the heat insulating container 1 through the box 2,
As shown in FIG. 7, the inside of the heat insulating container 1 is cooled or heated through a fluid heat medium such as water circulating in the heat medium pipe 90. The heat medium pipe 90 is connected to a heat exchanger 91 that exchanges heat with the use-side heat exchange surface portion 10 b of the thermo module 10. Then, the heat medium such as water circulating in the heat medium pipe 90 is cooled or heated via the heat exchanger 91. Further, the heat medium pipe 90 is provided so as to be attached to the outside of the inner box 2.
A wide range of the inner box 2 is cooled or heated through the heat medium circulating through the inside of the heat insulating container 1 to cool or heat the inside of the heat insulating container 1.
In addition, 92 is a heat medium circulation pump. Therefore, in this case, although the number of components increases, the inner box 2 can be cooled uniformly and the temperature distribution in the heat insulating container 1 can be improved.

Next, modifications of the above embodiment will be described. (1) The storage may be dedicated to refrigeration or hot storage. (2) The number of the thermo modules 10 may be determined in relation to the cooling load of the stored items, and may be one, or may be three or more. (3) Thermomodule 1 in the first to third embodiments
The 0-use side heat exchange surface portion 10b may directly exchange heat with the inner box 2.

(4) The thermo module 10 is used only for cooling, that is, it is used so that only heat is absorbed in the heat exchange surface portion 10b on the use side. On the other hand, a dedicated heating heater is provided, and this heating heater is used when heating is required. The inside of the heat insulating container 1 may be heated. (5) Heat source side heat exchange surface portion 10 of the thermo module 10
Instead of directly exchanging heat between c and the heat sink 12, heat may be indirectly exchanged through a fluid heat medium such as water. In this case, the number of parts is increased, but other effects are the same as those in each embodiment. (6) In Embodiments 1 to 3, the use-side heat exchange surface portion 10b of the thermo module 10 may be brought into direct contact with the inner box 2 without the heat transfer block 11 to conduct heat. In this case, it becomes difficult to replace the thermo module 10, but the number of parts is reduced, and other effects are the same as in the first to third embodiments.

(7) The outer box 3 is, as shown in FIG.
The front part and the rear part may be integrated without being divided. (8) The pedestal 50 may be an integral type instead of the split type as shown in FIG.

(9) The outside air flow in the air duct forming plate 13 may be formed so as to flow from the left side to the right side when viewed from the front, contrary to the above embodiments. In addition, the axial blower 2
Instead of 0, another blower, for example, a centrifugal blower may be used. (10) The opening / closing door 5 may be left-opened with the shaft support on the left side when viewed from the front.

(11) The mounting structure of the drain pan 41 using the stepped portion 54 of the foot 50 may be applied to a refrigerator using a refrigeration cycle having an ordinary compressor as a component.

[0033]

Since the present invention is constructed as described above, it has the following effects. The present invention provides a heat-insulating container for storing stored items at a predetermined temperature, a cooling means for cooling the inside of the heat-insulating container, and a drain pan for receiving a drain generated in the heat-insulating container provided below the heat-insulating container. In the storage, four foot legs are provided on the lower surface of the heat insulating container so that two feet are arranged on each of the right and left when viewed from the front, and step portions are provided on each of the four foot legs. Since the drain pan can be slidably mounted from the front between the portion and the lower surface of the heat insulating container, the drain pan can be easily taken in and out even with a simple structure.

[Brief description of drawings]

FIG. 1 is an external perspective view of a storage case according to Embodiment 1 of the present invention from the front.

FIG. 2 is a sectional view taken along line II-II in FIG.

3 is a sectional view taken along line III-III in FIG.

FIG. 4 is a rear view of the storage according to the first embodiment of the present invention.

FIG. 5 is a perspective view of the storage case according to the first embodiment of the present invention viewed from the rear with the back cover and the protective cover removed.

FIG. 6 is an exploded perspective view of the storage according to the first embodiment of the present invention.

7 is a sectional view taken along line VII-VII in FIG.

FIG. 8 is an explanatory diagram of a foot of the storage according to the first embodiment of the present invention.

9 is a perspective view of a part of FIG. 1 in a disassembled state.

10 is a sectional view taken along line XX in FIG.

FIG. 11 is a cross-sectional view corresponding to FIG. 10 with the open / close door opened.

FIG. 12 is a side view showing a part of the portion B in FIG. 1 as a sectional view.

13 is a perspective view of a lower main body side hinge used in FIG. 12. FIG.

FIG. 14 is a view of the part B in FIG. 1 viewed from below with the opening / closing door opened.

FIG. 15 is a sectional view of the back cover portion of the storage according to the second embodiment of the present invention, which corresponds to FIG.

FIG. 16 is a cross-sectional view of the back cover portion of the storage according to the third embodiment of the present invention, which corresponds to FIG.

FIG. 17 is a sectional view corresponding to FIG. 2 of the storage according to the fourth embodiment of the present invention.

FIG. 18 is a view showing a modified example of the outer box of the storage according to the embodiments of the present invention.

FIG. 19 is a view showing a modified example of the foot of the storage according to the first embodiment of the present invention.

[Explanation of symbols]

1 heat insulation container, 2 inner box, 2a heat insulation sheet, 3 outer box, 10 thermo module, 10a Peltier element,
10b Use side heat exchange surface portion, 10c Heat source side heat exchange surface portion, 11 Heat transfer block, 12 Heat sink, 14
Rear cover, 15 intake ports, 16 exhaust ports, 17 communication holes, 18 ventilation holes, 20 axial blower, 31 control board, 32 power supply board, 33 protective cover, 41 drain pan, 50 pedestals, 54 stepped portion.

   ─────────────────────────────────────────────────── ─── Continued front page    F term (reference) 3L045 AA04 DA04 EA03                 3L048 AA07 BA06 CA02 CB08 DA03                       DB01 DC09

Claims (2)

[Claims] 1. A heat insulating container for storing stored items at a predetermined temperature, a cooling means for cooling the inside of the heat insulating container, and a drain pan for receiving drain generated in the heat insulating container are provided below the heat insulating container. In the storage, four feet are provided on the lower surface of the heat insulating container so that two feet are arranged on each of the left and right when viewed from the front, and step portions are provided on each of the four feet. A storage cabinet, wherein the drain pan can be slidably mounted from the front between the step portion and the lower surface of the heat insulating container. 2. The storage cabinet according to claim 1, wherein the drain pan has a substantially T-shaped horizontal plane shape, and a width dimension of a front portion thereof is larger than a width dimension of a rear portion thereof.