JP2020197361A - Storage - Google Patents

Abstract

To provide a storage capable of determining whether or not air circulation between a storage chamber and heat exchange chamber is normally performed.SOLUTION: A storage comprises: a cart 10 comprising a heat insulating box 11A having a cold storage chamber 25H, and a temperature sensor 63H capable of detecting the temperature of the cold storage chamber 25H; and a station 30 that houses the cart 10 in a drawable manner. The station 30 comprises: a heat exchange chamber 31 in which a heater 34 capable of heating air is housed; a circulation fan 35A capable of circulating air between the cold storage chamber 25H and the heat exchange chamber 31; and a control unit 80 that executes a determination process of determining whether or not air circulation between the cold storage chamber 25H and the heat exchange chamber 31 is normally performed based on the detected temperature of the temperature sensor 63H. The control unit 80 and the temperature sensor 63H are electrically connected to each other via a pair of connectors 65, 72 fitted to each other.SELECTED DRAWING: Figure 4

Description

The present invention relates to a storage.

Conventionally, as a storage, for example, the one described in Patent Document 1 is known. Patent Document 1 describes a cold storage device including a station and a cart that can be taken in and out of the station as a storage. The cart is equipped with a heat insulating box that constitutes a storage room (warming room and refrigerating room), and the station is equipped with a heat exchange room containing a cooler, a heater and a circulation fan. By driving the circulation fan, air circulates between the heat exchange chamber and the storage chamber, and it is possible to heat or cool the storage in the storage chamber.

Japanese Unexamined Patent Publication No. 2011-43310

In the above configuration, the storage in the storage chamber may be arranged on the air circulation path between the heat exchange chamber and the storage chamber. As a result, there is a concern that the storage may not be sufficiently heated or cooled due to the obstruction of air circulation.

The present invention has been completed based on the above circumstances, and provides a storage that can determine whether or not air circulation between the storage chamber and the heat exchange chamber is normally performed. The purpose is to provide.

In order to solve the above problems, the storage of the present invention includes a box body having a storage chamber capable of accommodating the storage, and a cart-side temperature sensor capable of detecting the temperature of the storage chamber. A cart is provided and a station in which the cart is stored in and out of the cart is provided, and the station accommodates at least one of a heating means capable of heating air and a cooling means capable of cooling air. A circulation fan capable of circulating air between the storage chamber and the heat exchange chamber through the heat exchange chamber, the duct connecting the heat exchange chamber and the storage chamber, and the duct. A control unit that executes a determination process for determining whether or not air circulation between the storage chamber and the heat exchange chamber is normally performed based on the temperature detected by the cart-side temperature sensor. The control unit and the cart-side temperature sensor are electrically connected to each other via a pair of connectors fitted to each other.

The control unit and the cart-side temperature sensor are electrically connected via a pair of connectors. Thereby, the control unit can determine whether or not the air circulation between the storage chamber and the heat exchange chamber is normally performed based on the temperature of the storage chamber detected by the cart-side temperature sensor. .. Then, the user can release the connection between the control unit and the cart-side temperature sensor by releasing the mating of the pair of connectors, and can take out the cart from the station.

Further, the pair of connectors may be provided on at least one of the outer surface of the box body and the outer surface of the station. Since the pair of connectors is arranged outside the box (or station), the user can easily release the mating of the pair of connectors.

Further, the heating means is housed in the heat exchange chamber, and the station includes a station-side temperature sensor capable of detecting the temperature of air from the storage chamber to the heat exchange chamber, and the control unit. Is that the air circulation between the storage chamber and the heat exchange chamber is normal when the detection temperature of the station side temperature sensor is higher than the detection temperature of the cart side temperature sensor in the determination process. It can be determined that the temperature has not been increased.

Since the heating means is housed in the heat exchange chamber, warm air can be circulated between the storage chamber and the heat exchange chamber by operating the heating means and the circulation fan. Here, when the circulation of warm air between the storage chamber and the heat exchange chamber is normally performed, the temperature of the warm air from the heat exchange chamber to the storage chamber drops after warming the stored material. Return to the heat exchange room in this state. Therefore, the detection temperature of the station side temperature sensor is lower than the detection temperature of the cart side temperature sensor. Therefore, the control unit can determine that the circulation of warm air (air) is not normally performed when the detection temperature of the station side temperature sensor is higher than the detection temperature of the cart side temperature sensor by a predetermined temperature. ..

Further, the station includes a release device for disconnecting the duct and the storage chamber by displacing the end of the duct on the storage chamber side to a side far from the storage chamber, and a touch panel. The control unit operates a display process for displaying an operation button on the display surface of the touch panel when the pair of connectors is disengaged, and operates the release device when the operation button is operated. It is possible to execute the release process of disconnecting the connection between the duct and the storage chamber.

An operation button is displayed when the mating of the pair of connectors is released, and by operating the operation button, the release process for releasing the connection between the duct and the storage chamber is executed. In other words, the release process cannot be executed when the pair of connectors are fitted. Then, when the duct and the storage chamber are connected, it is difficult to remove the cart from the station. Therefore, it is possible to suppress the situation where the cart is taken out from the station in the state where the pair of connectors are fitted, and it is possible to suppress the situation where the pair of connectors are damaged.

According to the present invention, there is provided a storage that can determine whether or not the air circulation between the storage chamber and the heat exchange chamber is normally performed.

An exploded perspective view of a cold storage device according to an embodiment of the present invention. Perspective view of cold storage device Sectional view showing cold storage device (cross-sectional view seen from the front side) Front view showing a cold storage device Front view showing the vicinity of connectors 76 and 65 (with the connection cable removed) Perspective view showing the upper part of the station with the panel member 30A removed. Perspective view showing a part of the expansion / contraction device 50 Perspective view which shows duct holding member 51 Sectional drawing which shows the state which ducts 52 to 55 are not connected with a heat insulating box 11A. Cross-sectional view showing a state in which ducts 52 to 55 are connected to the heat insulating box 11A. The figure which shows the electric composition of a cold storage device Flow chart showing the processing of the control unit related to the heating operation The figure which shows the display surface of a touch panel

An embodiment of the present invention will be described with reference to FIGS. 1 to 13. In this embodiment, the cold storage device 1 is illustrated as a storage. As shown in FIG. 1, the cold storage device 1 of the present embodiment includes a cart 10 and a station 30 in which the cart 10 can be taken in and out. The cart 10 includes a cart main body 11 having a heat insulating box 11A (box body) constituting the heat insulating chamber 11B (storage chamber), and a frame cart 20 for storing the tray 40. The heat insulating box 11A has both front and rear openings, and the heat insulating box 11A is equipped with a double door 12 that opens and closes the front and rear openings. In FIG. 1, the opening / closing door on the right side of the opening on the front side is omitted. Further, a caster 13 is provided on the bottom surface of the heat insulating box 11A.

The frame cart 20 has a structure in which a metal frame 23 is raised from the left and right side edges of a bottom plate 21 provided with casters 22. The frame cart 20 can be taken in and out of the cart body 11 from the front side. A heat insulating partition wall 24 is provided in the substantially central portion of the frame cart 20 in the left-right direction over the entire area in the front-rear direction. The partition wall 24 has a shape in which a plurality of unit partition walls 24A are stacked. The tray 40 is stored in a plurality of stages while penetrating between the upper and lower unit partition walls 24A from both the front and rear sides.

As shown in FIG. 2, when the frame cart 20 is housed in the cart body 11, the heat insulating chamber 11B is divided into left and right by the partition wall 24, so that the hot food (storage) on the tray 40 is stored on the left side. A refrigerating and heating chamber 25H (storage chamber) capable of accommodating is formed, and a refrigerating chamber 25C (storage chamber) capable of accommodating cold food on the tray 40 is formed on the right side. As shown in FIG. 3, the left inner panel 14A is provided inside the cart main body 11 at a distance from the left heat insulating wall 16L (the wall portion constituting the heat insulating box 11A), and the left heat insulating wall 16L The first air circulation passage 41 is formed by the left inner panel 14A. Further, a right inner panel 14D is provided inside the cart body 11 at intervals from the right heat insulating wall 16R, and a second air circulation passage 42 is formed by the right heat insulating wall 16R and the right inner panel 14D. Has been done. The left inner panel 14A and the right inner panel 14D are formed with a plurality of blowout holes 14B (see FIG. 1) for allowing air to flow into the cart body 11.

As shown in FIG. 1, a plurality of openings 17A to 17D are formed in the ceiling 15 of the heat insulating box 11A. As shown in FIG. 9, the opening 17A is formed above the first air circulation passage 41, and the opening 17B is formed above the cold storage chamber 25H. Further, the opening 17C is formed above the refrigerating chamber 25C, and the opening 17D is formed above the second air circulation passage 42.

As shown in FIG. 1, the station 30 has a substantially box shape having an opening 30E on the front surface. The cart 10 can be taken in and out of the station 30 through the opening 30E. A machine room 36 is formed in the upper part of the station 30. The machine room 36 houses a compressor 38 and a condenser (not shown) constituting the cooling device 37. As shown in FIG. 3, below the machine room 36 in the station 30, the first heat exchange chamber 31 and the second heat exchange chamber 32 are formed side by side side by side. The first heat exchange chamber 31 is arranged above the cold storage chamber 25H. The first heat exchange chamber 31 houses a first cooler 33A (evaporator, cooling means), a heater 34 (heating means), and a first circulation fan 35A. The first cooler 33A constitutes a part of the cooling device 37. The heater 34 is capable of heating the air in the heat exchange chamber 31, and the cooler 33A is capable of cooling the air in the heat exchange chamber 31.

The second heat exchange chamber 32 is arranged above the refrigerating chamber 25C. A second cooler 33B (evaporator, cooling means) and a second circulation fan 35B are housed in the second heat exchange chamber 32. The second cooler 33B constitutes a part of the cooling device 37, and can cool the air in the heat exchange chamber 32. The first cooler 33A and the second cooler 33B are connected in parallel with the compressor 38 and the condenser via a refrigerant pipe and an on-off valve (not shown). The control unit 80 (see FIG. 11, which will be described later) can control the supply of the refrigerant to the coolers 33A and 33B by switching the on-off valve. As a result, the control unit 80 has a state in which both the first cooler 33A and the second cooler 33B are operating, a state in which only the first cooler 33A is operating, and a second cooling. It is possible to switch the state in which only the vessel 33B is operating.

Further, a temperature sensor 61H is arranged in the heat exchange chamber 31, and a temperature sensor 61C is arranged in the heat exchange room 32. The temperature sensor 61H (station side temperature sensor) is arranged adjacent to the suction side of the circulation fan 35A, and the air in the cold storage chamber 25H sucked by the circulation fan 35A (from the cold storage chamber 25H to the heat exchange chamber 31). It is possible to detect the temperature of air). The temperature sensor 61C (station side temperature sensor) is arranged adjacent to the suction side of the circulation fan 35B, and the air in the refrigerating chamber 25C sucked by the circulation fan 35B (air from the refrigerating chamber 25C toward the heat exchange chamber 32). It is possible to detect the temperature of. Further, the heat exchange chamber 31 is provided with a temperature sensor 62H adjacent to the discharge side of the circulation fan 35A. The temperature sensor 62H can detect the temperature of the air sent to the cold storage chamber 25H by the circulation fan 35A. By stopping the heater 34 based on the temperature detected by the temperature sensor 62H, the control unit 80 can suppress the situation where high-temperature air heads for the cold storage chamber 25H and protect the tableware and the like in the cold storage chamber 25H. it can. As the temperature sensors 61H, 61C, 62H, 63H, 63C, for example, a thermistor can be used, but the temperature sensors are not limited to these.

As shown in FIG. 3, four ducts 52, 53, 54, 55 and a telescopic device 50 that expands and contracts the ducts 52, 53, 54, 55 are arranged below the heat exchange chambers 31, 32. ing. The heat exchange chambers 31 and 32 and the heat insulating chamber 11B (refrigerating chamber 25H and refrigerating chamber 25C) are configured to communicate with each other via ducts 52 to 55. As shown in FIGS. 7 and 9, the expansion / contraction device 50 includes a duct holding member 51 for holding the ducts 52, 53, 54, 55, a spring member 56 (coil spring) for pulling the duct holding member 51 upward, and a gear. The moving shaft 57A, the cam plate 57C attached to the rotating shaft 57A, the roller 57D rotatably attached to the tip of the cam plate 57C (the end opposite to the rotating shaft 57A), and rotation. A gear 57E provided at the front end of the shaft 57A, a gear 57F that meshes with the gear 57E, and a motor 57G that rotates the gear 57F are provided.

As shown in FIG. 8, the duct holding member 51 has a box shape that opens upward, and its four corners are suspended by four spring members 56 (see FIG. 3). The upper end of the spring member 56 is attached to, for example, the bottom wall constituting the heat exchange chambers 31 and 32. Further, although only two spring members 56 are shown in FIG. 2, a total of four spring members 56 are provided.

As shown in FIG. 8, in the duct holding member 51, the openings 51A, 51B, 51C, 51D are located at positions corresponding to the openings 17A, 17B, 17C, 17D formed in the ceiling 15 of the heat insulating box 11A, respectively. It is formed. As shown in FIG. 9, the ducts 52 to 55 extend downward (on the heat insulating chamber 11B side) from the heat exchange chamber 31 (or the heat exchange chamber 32). The ducts 52 to 55 are bellows-shaped members made of a rubber material and can be expanded and contracted in the vertical direction. The duct 52 has a flange 52A and a flange 52B. The upper flange 52A is fixed to the bottom wall of the first heat exchange chamber 31 so as to surround the through hole formed in the bottom wall.

The lower flange 52B is doubly formed, and the duct 52 is formed by inserting the peripheral edge of the opening 51A of the duct holding member 51 between the doubly formed flanges 52B. It is fixed at 51. The lower end portion 52C of the duct 52 extends in a trumpet shape and is arranged below the duct holding member 51. The configurations of the ducts 53 to 55 are basically the same as those of the duct 52. Ducts 53-55 are fixed to the bottom wall of the corresponding heat exchange chamber at their upper ends and are connected to the corresponding openings 51B-51D at the lower flange. Further, as shown in FIG. 8, the ducts 52 and 55 have the same shape as each other, and the ducts 53 and 54 have the same shape as each other. The ducts 52, 55 (openings 51A, 51D) are set to have a larger length in the front-rear direction and a smaller length in the left-right direction than the ducts 53, 54 (openings 51B, 51C).

As shown in FIG. 7, the rotating shaft 57A is composed of pipes extending in the front-rear direction of the station 30, and two cam plates 57C are provided apart from each other in the axial direction of the rotating shaft 57A. Further, as shown in FIG. 8, cutouts 51E opened upward are formed on the front and rear wall portions of the duct holding member 51. In the state where the duct holding member 51 is in the raised position (the state shown in FIG. 9), the rotating shaft 57A is fitted to the notch 51E. Further, as shown in FIGS. 2 and 6, the station 30 includes a panel member 30A forming a part of the front surface and a panel member 30B arranged behind the panel member 30A. As shown in FIG. 6, the front end of the rotating shaft 57A is rotatably fixed to the panel member 30B, and the motor 57G is fixed to the panel member 30B.

As shown in FIG. 8, on the bottom surface of the duct holding member 51, contacted plates 58 with which the rollers 57D abut are provided at the center position in the width direction and at both front and rear ends, and in front view of each contacted plate 58. A stopper plate 59 is formed on the left edge so as to stand up. From the state shown in FIG. 9, when the motor 57G rotates the rotation shaft 57A clockwise, the cam plate 57C rotates, and the roller 57D pushes down the contacted plate 58 provided on the duct holding member 51. Then, as shown in FIG. 10, the duct holding member 51 is pushed down.

When the duct holding member 51 is pushed down, the ducts 52 to 55 extend toward the heat insulating chamber 11B of the cart 10, and the lower ends of the ducts 52 to 55 hit the ceiling 15 so as to surround the openings 17A to 17D of the ceiling 15 of the heat insulating box 11A. Touch. As a result, the first heat exchange chamber 31 and the first air circulation passage 41 are connected (communication) by the duct 52, and the first heat exchange chamber 31 and the cold storage chamber 25H are connected (communication) by the duct 53. Will be done. Further, the second heat exchange chamber 32 and the refrigerating chamber 25C are connected (communicated) by the duct 54, and the second heat exchange chamber 32 and the second air circulation passage 42 are connected (communicated) by the duct 55. ..

Further, when the motor 57G rotates the rotation shaft 57A counterclockwise from the state shown in FIG. 10, the pressure of the contacted plate 58 by the roller 57D is released, and the spring member 56 elastically returns to hold the duct. The member 51 rises. As a result, the ducts 52 to 55 contract, so that the lower ends of the ducts 52 to 55 are separated from the ceiling 15. That is, the expansion / contraction device 50 displaces the end (lower end) of the ducts 52 to 55 on the heat insulating chamber 11B side to the side (upper side) far from the heat insulating chamber 11B (refrigerating chamber 25H and refrigerating chamber 25C). This is an example of a release device for releasing the connection between the ~ 55 and the heat insulating chamber 11B. As described above, in the present embodiment, the ducts 52 to 55 can be expanded and contracted by operating the expansion / contraction device 50 (more specifically, the motor 57G), and the ducts 52 to 55 can be connected and disconnected from the heat insulating chamber 11B. You can switch. As a result, it is possible to prevent the ducts 52 to 55 from interfering with the cart 10 when the station 30 is taken in and out of the cart 10.

When the first circulation fan 35A rotates while the ducts 52 and 53 are connected to the cart 10 (more specifically, the heat insulating chamber 11B), the air in the cold storage chamber 25H is transferred from the duct 53 to the first heat exchange chamber 31. Is sucked into. The air sucked into the first heat exchange chamber 31 is cooled by the first cooler 33A (or heated by the heater 34) and sent from the duct 52 to the first air circulation passage 41. The air sent into the first air circulation passage 41 flows into the cold storage chamber 25H from the plurality of outlet holes 14B (see FIG. 1) formed in the left inner panel 14A. That is, the circulation fan 35A is capable of circulating air between the cold storage chamber 25H and the heat exchange chamber 31 via the ducts 52 and 53.

Further, when the second circulation fan 35B rotates while the ducts 54 and 55 are connected to the cart 10 (more specifically, the heat insulating chamber 11B), the air in the refrigerating chamber 25C is transferred from the duct 54 to the second heat exchange chamber. It is sucked into 32. The air sucked into the second heat exchange chamber 32 is cooled by the second cooler 33B and sent from the duct 55 to the second air circulation passage 42. The air sent into the second air circulation passage 42 flows into the refrigerating chamber 25C through a plurality of outlet holes (not shown) formed in the right inner panel 14D. That is, the circulation fan 35B can circulate air between the refrigerating chamber 25C and the heat exchange chamber 32 via the ducts 54 and 55.

Further, as shown in FIG. 3, the cart 10 has a temperature sensor 63H (cart side temperature sensor) capable of detecting the temperature of the cold storage chamber 25H and a temperature capable of detecting the temperature of the cold storage chamber 25C. It includes a sensor 63C (cart side temperature sensor). The temperature sensor 63H is arranged in the lower part of the first air circulation passage 41. Wiring 64H is connected to the temperature sensor 63H. The wiring 64H passes through the air circulation passage 41 and extends upward from the temperature sensor 63H, then passes through the ceiling 15 of the heat insulating box 11A and extends to the right side of the heat insulating box 11A, and at the extended end thereof, the heat insulating box 11A It is connected to a connector 65 (see FIG. 5) provided on the outer surface of the above. As shown in FIG. 3, the temperature sensor 63C is arranged in the lower part of the second air circulation passage 42. Wiring 64C is connected to the temperature sensor 63C. The wiring 64C passes through the air circulation passage 42 and extends upward from the temperature sensor 63C, and then is connected to the connector 65 at the extending end portion thereof.

As shown in FIG. 1, the cold storage device 1 includes a connection cable 70 that electrically connects the cart 10 and the station 30. As shown in FIG. 5, the connection cable 70 includes a wiring 71, a connector 72 provided at the end of the wiring 71 on the cart 10 side, and a connector 73 provided at the end of the wiring 71 on the station 30 side. To be equipped. As shown in FIGS. 4 and 5, the connector 72 is fitted with the connector 65. Further, the lower right portion of the panel member 30A is a notch portion 30D, and the connector 76 is arranged at a portion corresponding to the notch portion 30D. That is, the connector 76 is provided on the outer surface of the station 30. The connector 73 and the connector 76 are fitted to each other. Further, the wiring 71 is held by a clip 30G provided on the panel member 30F constituting the opening 30E of the station 30.

Further, as shown in FIG. 6, an electrical box 75 is arranged on the back side of the panel member 30A (front side of the panel member 30B). The connector 76 is connected to the electrical box 75 via the wiring 77 arranged on the front surface of the panel member 30B. Further, the electrical box 75 is electrically connected to the electrical box 78 arranged in the machine room 36.

(Electrical configuration of cold storage device)
Next, the electrical configuration of the cold storage device 1 will be described. As shown in FIG. 11, the cold storage device 1 includes a control unit 80. The control unit 80 includes a touch panel 74, temperature sensors 61H, 61C, 62H, 63H, 63C, a motor 57G, circulation fans 35A, 35B, a heater 34, a cooling device 37 (more specifically, a compressor 38 or an on-off valve). The timing unit 62 and the storage unit 63 are electrically connected.

The control unit 80 is mainly composed of, for example, a CPU, and the storage unit 63 is composed of, for example, a ROM or RAM. By executing the program stored in the storage unit 63, the control unit 80 executes each device (touch panel 74, motor 57G, circulation fan 35A, 35B, heater 34, cooling device 37 (and thus cooling) connected to the control unit 80. It is possible to control the operation of the devices 33A, 33B)). The control unit 80, the timekeeping unit 62, and the storage unit 63 are composed of, for example, each device (circuit board or the like) housed in the electrical box 75 and the electrical box 78. As described above, the temperature sensors 63H and 63C are electrically connected to the electrical box 75 via a pair of connectors 65 and 72 and a pair of connectors 73 and 76 fitted to each other. That is, the control unit 80 and the temperature sensors 63H and 63C are electrically connected via a pair of connectors 65 and 72 and a pair of connectors 73 and 76.

Further, as shown in FIG. 6, a touch panel 74 (more specifically, a liquid crystal panel with a touch panel) is arranged on the back side of the panel member 30A (the front side of the panel member 30B). As shown in FIG. 2, the touch panel 74 has a display surface 74A exposed on the front surface of the station 30, and has a function as a display unit for displaying an image on the display surface 74A and an operation unit that can be operated by the user. It has a function as. By operating the switch displayed on the touch panel 74, the user performs operations related to the operation of the cold storage device 1, various settings (for example, input of cooking completion time, target temperature, etc.), confirmation of operation history, and the like. be able to. The timekeeping unit 62 is supposed to time the current time, and the control unit 80 can control each device based on the current time of the timekeeping unit 62.

In the present embodiment, the user stores the tray 40 in which the hot food and the cold food are arranged in the state where the cart 10 is taken out from the station 30 over the refrigerating chamber 25C and the refrigerating chamber 25H. Next, the user stores the cart 10 in the station 30 and connects the connection cable 70 to each of the connector 65 and the connector 76. As a result, the temperature sensors 63H and 63C are electrically connected to the control unit 80. Next, the user selects a driving course by operating the touch panel 74. After that, the control unit 80 extends the ducts 52 to 55 in the contracted state by operating the motor 57G and connects them to the heat insulating chamber 11B. Next, the control unit 80 sets each device (heater 34, cooling device 37, circulation fan 35A) so that the temperature detected by the temperature sensors 61H and 61C becomes a preset set temperature based on the selected operation course. And the circulation fan 35B, etc.) are controlled. Examples of the operation course include precooling operation, chilled operation, heating operation, and the like. The control unit 80 controls the operation or non-operation of the coolers 33A and 33B by switching the opening / closing of the on-off valve included in the cooling device 37 and switching the compressor 38 on / off.

The chilled operation is an operation of chilling the refrigerating chamber 25C and the refrigerating / heating chamber 25H, and the control unit 80 operates the coolers 33A and 33B, the circulation fan 35A, and the circulation fan 35B. The heating operation is an operation of keeping the refrigerating chamber 25C cold and heating the refrigerating chamber 25H. The control unit 80 stops the operation of the cooler 33A, and the heater 34, the cooler 33B, the circulation fan 35A, and the circulation fan. Operate 35B. Further, the precooling operation is an operation for cooling the inside of the heat insulating chamber 11B in an empty state after the heating operation and before the next meal is put in, and the control unit 80 includes the coolers 33A and 33B, the circulation fan 35A, and the circulation. Operate the fan 35B.

By the way, the air circulation path (for example, the outlet hole 14B) between the heat exchange chambers 31 and 32 and the heat insulating chamber 11B is partially formed by the installation object (for example, a bag containing food tags or seasonings) installed on the tray 40. There is a concern that the air circulation between the heat exchange chambers 31 and 32 and the heat insulating chamber 11B may not be sufficiently performed due to the blockage. Therefore, the control unit 80 determines whether or not the air circulation between the heat exchange chambers 31 and 32 and the heat insulating chamber 11B is normally performed based on the temperature detected by the temperature sensor 63H (or the temperature sensor 63C). Execute the judgment process. Such a determination process is performed in each operation course when, for example, the temperature detected by the temperature sensors 61H and 61C reaches a preset set temperature. Here, as a determination process, it is executed in association with the heating operation, and the control unit 80 normally circulates air between the cold storage chamber 25H and the heat exchange chamber 31 based on the detected temperature of the temperature sensor 63H. An example of what determines whether or not it is damaged.

As shown in FIG. 12, when the heating operation is started, the control unit 80 starts the operation of the heater 34 and the circulation fan 35A (step S1), and then the detection temperature T1 of the temperature sensor 61H is preset. When the set temperature reaches T2 (YES in step S2), the operation of the heater 34 is stopped (step S3, heating operation is completed). Then, the control unit 80 determines whether or not the detection temperature T1 of the temperature sensor 61H is higher than the detection temperature T3 of the temperature sensor 63H by the predetermined temperature T4 (determination process, step S4), and the detection temperature T1 is the temperature sensor 63H. When the predetermined temperature T4 is higher than the detected temperature T3 (YES in step S4 when T1> T3 + T4), it means that the air circulation between the cold storage chamber 25H and the heat exchange chamber 31 is not performed normally. The determination is made, the touch panel 74 is operated, and the notification process (step S5) is performed. The predetermined temperature T4 is set at, for example, 20 ° C., but the temperature is not limited to this and can be changed as appropriate. In the notification process, the control unit 80 displays, for example, a warning message on the display surface 74A of the touch panel 74 notifying that "air circulation between the cold storage chamber 25H and the heat exchange chamber 31 is not performed correctly".

When a warning message is displayed on the touch panel 74, for example, the user operates the touch panel 74 after eliminating the cause of obstructing the air circulation between the cold storage chamber 25H and the heat exchange chamber 31. Perform the heating operation again. Further, along with the warning message, a matter assumed as a cause of obstructing the air circulation between the cold storage chamber 25H and the heat exchange chamber 31 may be displayed on the display surface 74A. As a result, the user who confirms the warning message can promptly eliminate the cause. The control unit 80 controls to maintain the set temperature T2 for a set time by repeatedly turning on and off the heater 34 while operating the circulation fan 35A after stopping the heater 34 in step S3. I do. In other words, after the time set from step S3 has elapsed, both the circulation fan 35 and the heater 34 are stopped.

Further, when the detection temperature T1 is (detection temperature T3 + predetermined temperature T4) or less (NO in step S4, when the air circulation between the cold storage chamber 25H and the heat exchange chamber 31 is normally performed). Displays a message (for example, "remove the connection cable") prompting the user to "remove the connection cable 70 from the connector 65 or the connector 76" on the display surface 74A of the touch panel 74 (for example, "remove the connection cable"). Step S6, message display processing). The user who sees this display releases the mating of the pair of connectors 73,76 (or the pair of connectors 65,72). As a result, the connection between the station 30 and the cart 10 by the connection cable 70 is released. Both the mating of the pair of connectors 73 and 76 and the mating of the pair of connectors 65 and 72 may be released.

Next, when the pair of connectors 73,76 (or the pair of connectors 65,72) are disengaged (YES in step S7), the control unit 80 of the touch panel 74, as shown in FIG. The operation button 74B is displayed on the display surface 74A (step S8 in FIG. 12, display process). Note that FIG. 13 illustrates an operation button 74B in which the word “cart removal” is displayed. Then, as shown in FIG. 13, the control unit 80 executes the release process when the operation button 74B is operated (touch operation) (YES in step S9). In the release process, the control unit 80 raises the duct holding member 51 by operating the motor 57G (a part of the release device), and causes the ducts 52 to 55 in the extended state to be in the contracted state. The connection between 52 to 55 and the heat insulating chamber 11B is released (step S10). As a result, the connection between the station 30 and the cart 10 by the ducts 52 to 55 is released, so that the user can take out the cart 10 from the station 30.

In this embodiment, NTC thermistors are used as the temperature sensors 63H and 63C. The NTC thermistor has a property that the electric resistance increases as the temperature decreases. Therefore, for example, in the control unit 80, when the detection temperature of the temperature sensor 63H (or the temperature sensor 63C) is lower than the minimum operating temperature, the pair of connectors 73,76 (or the pair of connectors 65,72) can be fitted. It can be determined that the temperature sensor 63H or the wiring related to the temperature sensor 63C is disconnected. The minimum operating temperature of the temperature sensor referred to here is a lower limit value of the operating temperature range preset in the temperature sensor. In other words, "the temperature detected by the temperature sensor is lower than the minimum operating temperature" means that the electrical resistance of the temperature sensor, which is an NTC thermistor, is larger than the range that can normally be taken (in other words, the wiring related to the temperature sensor is broken. It corresponds to (being in a state of being). The method for determining whether or not the pair of connectors 73, 76 (or the pair of connectors 65, 72) has been disengaged by the control unit 80 is not limited to the above, and can be appropriately changed. For example, when the pair of connectors 73,76 (or the pair of connectors 65,72) are separated by a predetermined distance, the control unit 80 uses a proximity sensor or the like to separate the pair of connectors 73,76 (or the pair of connectors 65,72). ) May be determined to have been released.

Next, the effect of this embodiment will be described. In the present embodiment, the control unit 80 and the temperature sensor 63H are electrically connected via a pair of connectors 73 and 76 and a pair of connectors 65 and 72. As a result, the control unit 80 determines whether or not the air circulation between the cold storage chamber 25H and the heat exchange chamber 31 is normally performed based on the temperature of the cold storage chamber 25H detected by the temperature sensor 63H. It can be determined. Then, the user of the cold storage device 1 can release the connection between the control unit 80 and the temperature sensor 63H by releasing the mating of the pair of connectors 73,76 (or the pair of connectors 65,72). , The cart 10 can be taken out from the station 30.

Further, the pair of connectors 73 and 76 are provided on the outer surface of the station 30, and the pair of connectors 65 and 72 are provided on the outer surface of the heat insulating box 11A. Since the pair of connectors 73 and 76 are arranged outside the heat insulating box 11A and the station 30, the user can easily release the mating of the pair of connectors 73 and 76.

Further, the heat exchange chamber 31 accommodates the heater 34, the station 30 is provided with a temperature sensor 61H capable of detecting the temperature of the air from the cold storage chamber 25H toward the heat exchange chamber 31, and the control unit 80 In the determination process, when the detection temperature of the temperature sensor 61H is higher than the detection temperature of the temperature sensor 63H, the air circulation between the cold storage chamber 25H and the heat exchange chamber 31 is not normally performed. Is determined.

Since the heater 34 is housed in the heat exchange chamber 31, hot air can be circulated between the cold storage chamber 25H and the heat exchange chamber 31 by operating the heater 34 and the circulation fan 35A. Here, when the hot air is normally circulated between the cold / hot storage room 25H and the heat exchange room 31, the hot air from the heat exchange room 31 to the cold / hot storage room 25H is stored (warm). After warming the food), it returns to the heat exchange chamber 31 in a state where the temperature has dropped. Therefore, the detection temperature of the temperature sensor 61H is lower than the detection temperature of the temperature sensor 63H. On the other hand, when the hot air is not normally circulated between the cold / hot storage chamber 25H and the heat exchange chamber 31, the hot air does not reach the lower part of the cold / hot storage chamber 25H and easily returns to the heat exchange chamber 31. Therefore, the detection temperature of the temperature sensor 63H is unlikely to rise, and the detection temperature of the temperature sensor 61H is likely to rise. Therefore, when the detection temperature T1 of the temperature sensor 61H is higher than the detection temperature T3 of the temperature sensor 63H by the predetermined temperature T4 (when T1> T3 + T4), the control unit 80 normally circulates the warm air (air). It can be determined that it has not been performed.

Further, the station 30 includes a telescopic device 50 that disconnects the ducts 52 to 55 and the heat insulating chamber 11B by displacing the end of the ducts 52 to 55 on the heat insulating chamber 11B side to the side far from the heat insulating chamber 11B, and a touch panel. 74, and the control unit 80 displays the operation button 74B on the display surface 74A of the touch panel 74 when the mating of the pair of connectors 73,76 (or the pair of connectors 65,72) is released. Then, when the operation button 74B is operated, the expansion / contraction device 50 is operated to execute the release process of releasing the connection between the ducts 52 to 55 and the heat insulating chamber 11B.

In the present embodiment, the operation button 74B is displayed when the mating of the pair of connectors 73,76 (or the pair of connectors 65,72) (the connection between the cart 10 and the station 30 by the connection cable 70) is released. By operating the operation button 74B, a release process for releasing the connection between the ducts 52 to 55 and the heat insulating chamber 11B is executed. In other words, the release process cannot be executed in a state where the pair of connectors 73,76 (or the pair of connectors 65,72) are fitted. Then, when the ducts 52 to 55 and the heat insulating chamber 11B are connected, it is difficult to take out the cart 10 from the station 30. Therefore, it is possible to prevent the cart 10 from being taken out from the station 30 with the pair of connectors 73,76 (or the pair of connectors 65,72) fitted, and the pair of connectors 73,76 (or the pair of connectors 65,72) can be prevented from being taken out. It is possible to suppress a situation in which the pair of connectors 65, 72) are damaged.

Further, the control unit 80 executes a determination process for determining whether or not air circulation between the refrigerating chamber 25C and the heat exchange chamber 32 is normally performed based on the temperature detected by the temperature sensor 63C. May be good. In this case, the control unit 80 starts the operation of the cooling device 37, and then stops the operation of the cooling device 37 when the detection temperature T11 of the temperature sensor 61C reaches the preset set temperature T12. After that, the control unit 80 determines whether or not the detection temperature T13 of the temperature sensor 63C is higher than the detection temperature T11 of the temperature sensor 61C (determination processing), and if the detection temperature T13 is higher than the detection temperature T11, It is determined that the air circulation between the refrigerating chamber 25C and the heat exchange chamber 32 is not normally performed, and the touch panel 74 is operated to perform the notification process. In the notification process, the control unit 80 displays, for example, a warning message on the touch panel 74 notifying that "air circulation between the refrigerating chamber 25C and the heat exchange chamber 32 is not performed correctly".

When the circulation of cold air between the refrigerating chamber 25C and the heat exchange chamber 32 is normally performed, the temperature of the cold air directed from the heat exchange chamber 32 to the refrigerating chamber 25C rises after cooling the stored matter. Since it returns to the heat exchange chamber 32 in the state, the detection temperature of the temperature sensor 61C becomes higher than the detection temperature of the temperature sensor 63C. On the other hand, if the cold air is not normally circulated between the refrigerating chamber 25C and the heat exchange chamber 32, the cold air does not reach the lower part of the refrigerating chamber 25C and easily returns to the heat exchange chamber 32. The detection temperature of 63C is hard to drop, and the detection temperature of the temperature sensor 61C is easy to drop. Therefore, when the detection temperature of the temperature sensor 63C is higher than the detection temperature of the temperature sensor 61C, the control unit 80 can determine that the circulation of cold air (air) is not normally performed. When the operation for cooling the cold storage chamber 25H is completed, the control unit 80 connects the cold storage chamber 25H and the heat exchange chamber 31 when the detection temperature of the temperature sensor 63H is higher than the detection temperature of the temperature sensor 61H. It may be determined that the air circulation between the air is not normally performed, and the touch panel 74 may be operated to perform the notification process.

When the air circulation path between the heat exchange chambers 31 and 32 and the heat insulation chamber 11B is partially blocked, the lower part (lower part of the cart 10) far from the heat exchange chambers 31 and 32 in the heat exchange chamber 11B is It becomes more difficult for air to circulate. Therefore, the temperature sensors 63H and 63C are provided in the lower part of the air circulation passages 41 and 42 so that the temperature in the lower part of the heat insulating chamber 11B can be detected.

<Other embodiments>
The present invention is not limited to the embodiments described in the above description and drawings, and for example, the following embodiments are also included in the technical scope of the present invention.
(1) The temperature sensors 63H and 63C and the control unit 80 may be electrically connected via only one of the pair of connectors 73 and 76 and the pair of connectors 65 and 72.
(2) In the above embodiment, the thermistor is exemplified as the temperature sensor, but the present invention is not limited to this.
(3) In the notification process, the user may be notified that "air circulation is not performed correctly" by operating a buzzer or a lamp.

1 ... Cold storage device (storage), 10 ... Cart, 11A ... Insulation box (box body), 11B ... Insulation room (storage room), 30 ... Station, 31, 32 ... Heat exchange room, 33A, 33B ... Cooler ( Cooling means), 34 ... heater (heating means), 35A, 35B ... circulation fan, 50 ... expansion / contraction device (release device), 52-55 ... duct, 61H ... temperature sensor (station side temperature sensor), 63H ... temperature sensor ( Cart side temperature sensor), 65, 72 ... A pair of connectors, 73, 76 ... A pair of connectors, 74 ... Touch panel, 74A ... Touch panel display surface, 74B ... Operation buttons, 80 ... Control unit

Claims (4)

A cart including a box having a storage chamber capable of accommodating storage, a cart-side temperature sensor capable of detecting the temperature of the storage chamber, and the like.
It is equipped with a station where the cart can be taken in and out.
The station
A heat exchange chamber in which at least one of a heating means capable of heating air and a cooling means capable of cooling air is housed.
A duct connecting the heat exchange chamber and the storage chamber,
A circulation fan capable of circulating air between the storage chamber and the heat exchange chamber through the duct,
A control unit that executes a determination process for determining whether or not air circulation between the storage chamber and the heat exchange chamber is normally performed based on the temperature detected by the cart-side temperature sensor is provided. ,
A storage unit in which the control unit and the cart-side temperature sensor are electrically connected to each other via a pair of connectors fitted to each other. The storage according to claim 1, wherein the pair of connectors is provided on at least one of the outer surface of the box and the outer surface of the station. The heating means is housed in the heat exchange chamber.
The station includes a station-side temperature sensor capable of detecting the temperature of air from the storage chamber to the heat exchange chamber.
In the determination process, the control unit determines that the temperature of the air between the storage chamber and the heat exchange chamber is higher than the detection temperature of the cart-side temperature sensor when the detection temperature of the station-side temperature sensor is higher than the detection temperature of the cart-side temperature sensor. The storage according to claim 1 or 2, wherein it is determined that the circulation is not normally performed. The station
A release device that displaces the end of the duct on the storage chamber side to a side far from the storage chamber to release the connection between the duct and the storage chamber.
Equipped with a touch panel
The control unit
A display process for displaying an operation button on the display surface of the touch panel when the pair of connectors is disengaged.
According to any one of claims 1 to 3, the release process of releasing the connection between the duct and the storage chamber by operating the release device when the operation button is operated is executed. The listed storage.

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