JP3896260B2 - Refrigerator with display case - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a refrigerator with a showcase in which a showcase is installed on the upper surface of a refrigerator body.
[0002]
[Prior art]
For example, Japanese Patent Application Laid-Open No. 11-294925 discloses a case where a showcase for keeping food such as sushi and vegetables on a top surface of a refrigerator used in a kitchen such as a restaurant. In the refrigerator with a showcase described in this publication, a refrigeration chamber is defined inside the heat insulating box constituting the refrigerator, and the chilled air cooled by the cooler constituting the refrigeration mechanism together with the compressor and the condenser is refrigerated. The refrigerator is configured to be cooled by being fed into the room by an internal fan. In addition, an opening is provided at the bottom of the heat-insulating structure showcase disposed on the top surface of the heat insulating box at a position corresponding to the opening formed in the ceiling of the heat insulating box, so By introducing into the storage room defined in the showcase through the opening, the storage room is cooled.
[0003]
[Problems to be solved by the invention]
In the refrigerator with a showcase described above, a drainage hose for discharging drainage such as condensed water generated in the showcase to the outside of the machine is connected to the showcase. The drainage hose is piped inside the heat insulating box, or piped in a recess provided in the outer surface of the heat insulating box. However, in this case, there is a problem in that the volume of the heat insulating box is reduced or the heat insulating performance is lowered due to a decrease in the thickness of the heat insulating material in the recess. In addition, the maintenance such as exchanging and cleaning the drainage hose is complicated, and there is a problem that the heat insulation box requires complicated processing and the cost is increased.
[0004]
OBJECT OF THE INVENTION
The present invention has been proposed to solve this problem in view of the above-described drawbacks. The drain pipe is piped without deteriorating the heat insulating performance, and maintenance such as replacement and cleaning of the drain pipe is performed. An object is to provide a refrigerator with an easy showcase.
[0005]
[Means for Solving the Problems]
In order to overcome the above-mentioned problems and to achieve the intended purpose suitably, the present invention provides a refrigerator compartment in which a refrigeration mechanism is housed in a machine room internally defined in a refrigerator body, and is internally defined in a heat insulation box of the refrigerator body. Is cooled by the cooler of the refrigeration mechanism, a showcase is disposed on the upper surface of the refrigerator body, and a storage chamber defined in the inner box constituting the showcase is disposed in the inner box. In the refrigerator with a showcase configured to be cooled by a cooling pipe connected to the refrigeration mechanism,
A drainage pipe for discharging drainage such as dew condensation water generated in the storage room is connected to the showcase so that one end of the drainage pipe opens in contact with the inner box in the storage room,
An exhaust heat space that is sucked from a suction port provided in a front panel that defines the machine room and through which air that has risen in temperature by exchanging heat with a condenser and a compressor constituting the refrigeration mechanism in the machine room flows. Defined in the machine room,
The drain pipe, without disposed within the heat-insulating main body, provided in the waste heat in space,
In the exhaust heat space, the drain pipe is arranged so as to intersect the flow of the air whose temperature has increased over substantially the entire length of the drain pipe .
[0006]
DETAILED DESCRIPTION OF THE INVENTION
Next, the refrigerator with a showcase according to the present invention will be described below with reference to the accompanying drawings by giving a preferred embodiment. 1 to 3 show a refrigerator 10 with a showcase according to an embodiment. The refrigerator 10 is basically composed of a refrigerator main body 11 arranged on the lower side and a showcase 12 arranged on the upper side. Constructed.
[0007]
In the refrigerator main body 11, as shown in FIG. 1, an outer box 13, an inner box 14 provided with a required space inside the outer box 13, urethane filled between both boxes 13, 14, etc. A heat insulating box 16 is formed from the heat insulating material 15, and a refrigerator compartment 17 for storing refrigerated goods such as foods and beverages is defined in the box 16. A rectangular opening 16a used as an outlet opening forward is formed in the front portion of the heat insulating box 16, and the opening 16a is opened and closed by a heat insulating door 18 (FIG. 2). reference). Moreover, the top plate 19 is arrange | positioned on the upper surface of the heat insulation box 16, and this top plate 19 is comprised so that it can be used as a cooking table.
[0008]
A plurality of panels 20, 21 and a base 22 are provided below the projecting portion of the top plate 19 on one outer side (left side in FIG. 1) in the longitudinal direction of the heat insulation box 16 from which the top plate 19 projects. A machine room 23 is defined, and a refrigeration mechanism 24 (described later) is accommodated in the machine room 23. The top plate 19 that defines the upper part of the machine room 23 is provided with a cooler storage part 25 that hangs from the lower surface to a height that is about the middle position of the machine room 23. A cooler chamber 26 communicating with the refrigerating chamber 17 is defined inside the cooler storage section 25, and a cooler 27 of the refrigeration mechanism 24 and an internal fan 28 are stored in the cooler chamber 26. The cold air cooled by circulating and supplying the refrigerant to the cooler 27 is forced to convection to the refrigerating chamber 17 by the operation of the internal fan 28 to cool the refrigerating chamber 17. .
[0009]
On the left side wall of the heat insulation box 16 facing the machine chamber 23, a cold air outlet 29 is opened at a position corresponding to the cooler chamber 26, and the cool air cooled in the cooler chamber 26 is supplied to the internal fan 28. It is blown out to the refrigerator compartment 17 through the cold air outlet 29 by operation. Further, on the left side wall of the heat insulating box 16, a cold air suction duct 30 is disposed below the cold air outlet 29, and the air in the refrigerator compartment 17 is sucked into the cooler chamber 26 through the duct 30. Is done. The cold air outlet 29 is provided with a cold air guide plate 31 for guiding the cold air to the upper side of the refrigerator compartment 17. In addition, a first temperature sensor 32 for detecting the temperature of the refrigerator compartment 17 is disposed in the vicinity of the cooler 27, and an electromagnetic valve 54 for a refrigerator compartment described later is opened and closed based on the detected temperature of the sensor 32. It is set to be controlled.
[0010]
Components such as a condenser 34, a condenser fan 35 (see FIG. 4), a compressor 36, and the like constituting the refrigeration mechanism 24 are provided on a base plate 33 that is housed in the machine room 23 and can be taken in and out from the front side. In this order from the front side. The front panel 20 defining the machine room 23 has a large number of external air inlets 20a, and the side panel 21 has a large number of internal air outlets (not shown). In the machine room 23, a heat exhaust space 66 is defined between the side panel 21, the cooler housing portion 25, and the refrigeration mechanism 24, and the outside sucked from the suction port 20 a by the operation of the condenser fan 35. The condenser 34 and the compressor 36 are air-cooled by air, and the air after the heat exchange flows through the exhaust heat space 66 and is discharged from the outlet.
[0011]
As shown in FIG. 3, the showcase 12 disposed on the rear side of the upper surface of the heat insulating box 16 has an outer box 37 and an inner box 38 provided with a required space inside the outer box 37. And an insulating material 39 such as urethane filled between the boxes 37 and 38, and an opening 12a functioning as an outlet is provided only in the upper part thereof. That is, the outer box 37 and the inner box 38 are all formed in a box shape that opens upward from the bottom surface, the front surface, the rear surface, and both side surfaces, and the upper opening of the inner box 38 accommodated inside the outer box 37. Is an opening 12a, and a storage chamber 40 for storing food and the like is defined in the inner box 38. The bottom of the inner box 38 is set so as to be inclined downward from the rear end toward the front end, and a container 41 such as a tray containing ingredients such as sushi material is inclined forward via the slats 42. Configured to be placed.
[0012]
Rail members 43, 44 are disposed over the entire length in the longitudinal direction (left-right direction in FIG. 1) between the front and rear upper end portions of the outer box 37 and the inner box 38, and between the rail members 43, 44, Each of a plurality of slide doors (doors) 45 having a substantially U-shaped cross section made of a transparent material such as glass or resin is detachable and slidable in the longitudinal direction. As shown in FIG. 3, the rear rail member 44 is positioned so as to be higher than the front rail member 43 by a predetermined dimension, and the flat surface of the slide door 45 placed between the rail members 43 and 44 is inclined forward. Set to do. Thereby, the foodstuffs etc. which are stored in the storage room 40 can be easily visually recognized from the front side of the refrigerator 10 with a showcase through the slide door 45. In FIG. 2, reference numeral 46 indicates side covers disposed at both ends in the longitudinal direction of the outer box 37.
[0013]
As shown in FIG. 3, a cooling pipe 47 connected to the refrigeration mechanism 24 is arranged in a meandering manner on the outer surface on the heat insulating material side of the bottom surface portion and the rear surface portion of the inner box 38. The entire inner box 38 is cooled by circulation of the refrigerant supplied from. That is, the storage chamber 40 is cooled by natural convection of cool air cooled by the inner box 38. The inner box 38 is formed of a material having good thermal conductivity, and is configured so that the storage chamber 40 can be efficiently cooled.
[0014]
A second temperature sensor 48 for detecting the temperature of the storage chamber 40 is disposed on the outer surface of the inner box 38, and a storage chamber electromagnetic valve 56, which will be described later, is controlled to open and close based on the detected temperature of the sensor 48. It is set to be. In this case, as described above, the inner box 38 itself is formed of a material having good thermal conductivity. However, since the second temperature sensor 48 does not directly detect the temperature in the storage chamber 40, the storage chamber Since there is a difference between the room temperature of 40 and the temperature detected by the second temperature sensor 48, it is recommended that this temperature difference be corrected by electronic control. Note that the second temperature sensor 48 may be disposed inside the storage chamber 40 so as to control the opening / closing of the storage chamber electromagnetic valve 56 by directly detecting the room temperature.
[0015]
FIG. 5 shows a schematic configuration of the refrigeration mechanism 24 in the refrigerator 10 with a showcase according to the embodiment. In the refrigeration mechanism 24, a discharge pipe 49 led out from the refrigerant discharge side of the compressor 36 is connected to the condenser 34. The high-pressure and high-temperature vaporized refrigerant compressed by the compressor 36 is supplied to the condenser 34 to be condensed. The refrigerant pipe 50 led out from the refrigerant outlet side of the condenser 34 is connected to the first connection port 53 a of the first cheese 53 via the dryer 51 and the strainer 52. A first capillary tube 55 is connected to the second connection port 53 b of the first cheese 53 via a refrigerating chamber electromagnetic valve 54, and the first capillary tube 55 is connected to the refrigerant inlet side of the cooler 27. . A second capillary tube 57 is connected to the third connection port 53 c of the first cheese 53 via a storage chamber solenoid valve (switching means) 56, and the second capillary tube 57 is connected to the coolant inlet side of the cooling pipe 47. Connected to. That is, a part of the liquefied refrigerant condensed in the condenser 34 is branched and supplied to the cooler 27 via the first capillary tube 55, and the liquefied refrigerant decompressed via the first capillary tube 55 expands in the cooler 27. Heat exchange is performed by vaporization, and the refrigerator compartment 17 is cooled by the cold air cooled by the cooler 27. A part of the liquefied refrigerant condensed in the condenser 34 is also branched and supplied to the cooling pipe 47 via the second capillary tube 57, and the liquefied refrigerant decompressed via the second capillary tube 57 expands in the cooling pipe 47. Heat exchange is performed by vaporization, and the storage chamber 40 is cooled via an inner box 38 cooled by the cooling pipe 47.
[0016]
A suction pipe 58 is connected to the refrigerant suction side of the compressor 36, and the first return pipe 59 led out from the refrigerant outlet side of the cooler 27 and the refrigerant outlet side of the cooling pipe 47 led to the suction pipe 58. The second return pipe 60 is connected via the second cheese 61, and the vaporized refrigerant whose temperature has been increased by exchanging heat between the cooler 27 and the cooling pipe 47 corresponds to the corresponding first return pipe 59, second return pipe 60, and suction. It is configured to return to the compressor 36 via a tube 58. Then, the refrigerant returned to the compressor 36 is subjected to recirculation after being compressed to high pressure and high temperature.
[0017]
As shown in FIG. 5, the refrigeration mechanism 24 is provided with a first heat exchanging part 62 in which a part of the first capillary tube 55 is connected by solder or the like so as to be parallel to the first return pipe 59. In the section 62, the liquefied refrigerant flowing through the first capillary tube 55 and the vaporized refrigerant flowing through the first return pipe 59 led out from the cooler 27 are heat-exchanged to supercool the liquefied refrigerant. . Further, a second heat exchanging portion 63 in which a part of the second capillary tube 57 is connected by solder or the like so as to be parallel to the second return pipe 60 is provided, and the second capillary tube 57 is circulated in the exchanging portion 63. Heat exchange is performed between the liquefied refrigerant and the vaporized refrigerant flowing through the second return pipe 60 led out from the cooling pipe 47 to supercool the liquefied refrigerant.
[0018]
As shown in FIGS. 1 and 2, on the front surface of the showcase 12 is a stop means for shutting down the storage chamber 40 by the cooling pipe 47 by shutting off the electromagnetic valve 56 for the storage chamber and the power source. A power switch 64 is provided. That is, the power switch 64 is turned on to connect the storage chamber solenoid valve 56 and the power source, and in this state, the solenoid valve 56 is controlled to open and close based on the temperature detected by the second temperature sensor 48. It is set as follows. Further, by switching the power switch 64 to the OFF state, the storage chamber solenoid valve 56 and the power source are shut off, and in this state, the solenoid valve 56 is maintained in a closed state in which the supply of the refrigerant to the cooling pipe 47 is stopped. To be set. Even when the power switch 64 is turned off, the cooling of the refrigerator compartment 17 by the cooler 27 is continued. 1 and 2, reference numeral 65 denotes an operation lamp that displays the ON state of the power switch 64.
[0019]
The refrigeration pipes such as the second capillary tube 57 connecting the cooling pipe 47 and the storage chamber electromagnetic valve 56 and the second return pipe 60 connecting the cooling pipe 47 and the second cheese 61 are as shown in FIGS. The heat exhaust space 66 of the machine room 23 is disposed. Further, a drainage hose (drainage pipe) 67 for discharging drainage such as dew condensation water generated in the storage chamber 40 is connected so that one end thereof opens in the storage chamber 40. As shown in FIGS. 1 and 4, the drain hose 67 is configured to be led out of the machine after being piped in the exhaust heat space 66 in the same manner as the refrigeration pipes 57 and 60.
[0020]
[Effect of the embodiment]
Next, the operation of the refrigerator with a showcase according to the embodiment will be described below. The power switch 64 is in an ON state, and the storage chamber 40 of the showcase 12 can be cooled.
[0021]
In the refrigeration mechanism 24 of the refrigerator 10 with a showcase, the vaporized refrigerant compressed by the compressor 36 is cooled and condensed by the condenser 34 through the discharge pipe 49, and the liquefied refrigerant is connected to the refrigerant pipe 50. The first capillary 53 is branched and supplied to the first capillary tube 55 and the second capillary tube 57 via the first cheese 53. The liquefied refrigerant flowing through the first capillary tube 55 is supercooled by exchanging heat with the vaporized refrigerant flowing through the first return pipe 59 of the cooler 27 in the first heat exchange section 62. Then, by expanding and evaporating all at once in the cooler 27, heat is exchanged with the air in the cooler chamber 26 in contact with the cooler 27 to cool.
[0022]
The cold air cooled by the cooler 27 is blown out from the cold air outlet 29 toward the refrigerating chamber 17 by the operation of the internal fan 28, and the refrigerating chamber 17 is cooled by circulating this cold air through the refrigerating chamber 17. (See FIG. 1). The cold air exchanged in the refrigerating chamber 17 is sucked into the cooler chamber 26 through the cool air suction duct 30, is again heat-exchanged with the cooler 27, cooled, and then blown out to the refrigerating chamber 17 again. Is done. That is, in the refrigerator main body 11 in the refrigerator 10 with a showcase, the refrigerator compartment 17 is efficiently cooled by a forced air convection method.
[0023]
In addition, the liquefied refrigerant flowing through the second capillary tube 57 is supercooled by exchanging heat with the second return pipe 60 of the cooling pipe 47 in the second heat exchanging portion 63, and then the cooling pipe 47. By expanding and evaporating all at once, heat is exchanged with the inner box 38 for cooling. Since the inner box 38 is formed of a material having good thermal conductivity, the bottom, front, rear and both side parts of the inner box 38 are efficiently cooled, and the inner box 38 is inside the storage chamber 40. The air in contact with is cooled, and the storage chamber 40 is cooled by natural convection of this cold air. That is, in the showcase 12, since the storage chamber 40 is cooled by the natural convection method of cold air, there is no possibility that the food stored in the storage chamber 40 is dried by the flow of cold air.
[0024]
The refrigerant returned to the compressor 36 through the first return pipe 59, the second return pipe 60, and the suction pipe 58 is compressed to high pressure and high temperature, and then recirculated. In such a refrigeration operation, the supply and stop of the refrigerant to the cooler 27 is performed by controlling the opening and closing of the refrigerating chamber electromagnetic valve 54 based on the temperature detected by the first temperature sensor 32 in the refrigerating chamber 17. Are repeated, and the refrigerator compartment 17 is maintained at a preset temperature. Similarly, in the showcase 12, the supply of the refrigerant to the cooling pipe 47 is controlled by controlling the opening and closing of the storage chamber electromagnetic valve 56 based on the temperature detected by the second temperature sensor 48 in the storage chamber 40. The storage chamber 40 is maintained at a preset temperature.
[0025]
As described above, the opening 12a through which the food and the like are taken in and out of the storage chamber 40 is opened only at the upper part of the showcase 12, so the sliding door 45 is slid to open the opening 12a. Even so, the heavy cold air cooled in the storage chamber 40 hardly flows out of the room through the upper opening 12a. Further, since the cold air does not flow out of the room, the wet light warm air outside the room hardly flows into the room through the opening 12a. As a result, the temperature of the storage room 40 hardly changes, and the freshness is suppressed by suppressing the deterioration of the foodstuff. Can be maintained. Moreover, the showcase 12 has the bottom surface, front surface portion, rear surface portion, and both side surface portions of the inner box 38 all covered with the heat insulating material 39, and the inner case 38 with which the cooling pipe 47 is in contact is thermally conductive. Since it is formed of a good material, the heat insulation performance is good, and the entire inner box 38 is cooled uniformly and efficiently, thereby suppressing the occurrence of temperature unevenness in the storage chamber 40.
[0026]
Wastewater such as condensed water generated in the storage chamber 40 is discharged to the outside through the drainage hose 67. In this case, since the drainage hose 67 is arranged in the exhaust heat space 66 of the machine room 23 without being piped inside or outside the heat insulation box 16, the volume of the heat insulation box 16 is reduced. Therefore, the heat insulating material 15 is not thinned and the heat insulating performance is not deteriorated, and it is not necessary to perform complicated processing on the heat insulating box 16, so that an increase in cost can be suppressed. Moreover, since the air whose temperature has increased due to heat exchange with the condenser 32 and the compressor 36 flows in the exhaust heat space 66, the drainage hose 67 can be warmed to suppress the occurrence of condensation or icing. Furthermore, since the drainage hose 67 is not connected to the inside of the heat insulation box 16, maintenance such as replacement and cleaning of the drainage hose 67 can be easily performed.
[0027]
In the embodiment, the exhaust heat space 66 is provided with refrigeration pipes such as a second capillary tube 57 and a second return pipe 60 that connect the cooling pipe 47 of the showcase 12 and the refrigeration mechanism 24 in the machine room. ing. Accordingly, as in the case of the drainage hose 67 described above, (1) prevention of a decrease in the volume of the heat insulation box 16, (2) prevention of a decrease in the heat insulation performance of the heat insulation box 16, and (3) an increase in the cost of the heat insulation box 16 (4) Prevention of dew condensation and icing, and (5) Easy maintenance such as repair of refrigeration pipes. In addition, since the drain hose 67 and the refrigeration pipes 57 and 60 are not disposed in the heat insulating box 16, the showcase 12 can be easily separated from the refrigerator body 11, and the refrigeration mechanism 24 can be pulled out from the machine room 23. There is no hindrance.
[0028]
Next, after the end of business hours, the food in the storage room 40 in the showcase 12 is transferred to the refrigerator compartment 17, and when the showcase 12 is not used, the power switch 64 is turned off. As a result, the storage chamber solenoid valve 56 is shut off from the power source, and the solenoid valve 56 is maintained in a closed state in which the supply of the refrigerant to the cooling pipe 47 is stopped. That is, all the refrigerant supplied from the condenser 34 to the first cheese 53 is supplied to the cooler 27 through the first capillary tube 55, and efficient cooling of the refrigerator compartment 17 is achieved. In addition, since the refrigerator main body 11 and the showcase 12 are completely insulated from each other, the compressor load can be reduced, the life of the compressor 36 can be extended, and the power consumption can be reduced. Running costs can be kept low.
[0029]
Further, when the storage chamber 40 of the showcase 12 is cleaned, the storage chamber 40 is defrosted by turning off the power switch 64 while the refrigerator compartment 17 is continuously cooled. It is possible to clean from, and cleanability is good.
[0030]
【The invention's effect】
As described above, in the refrigerator with a showcase according to the present invention, the drain pipe connected to the showcase is arranged in the exhaust heat space of the machine room, so that the heat insulation performance of the refrigerator main body is not deteriorated. Maintenance such as replacement and cleaning of the drain pipe can be easily performed. Further, by arranging the drain pipe in the exhaust heat space, it is possible to suppress the occurrence of condensation and icing due to the exhaust heat in the space.
[0031]
Furthermore, since the drain pipe is not piped inside or outside the heat insulating box, it is possible to prevent the heat insulating capacity from being reduced due to a decrease in the volume of the heat insulating box or a decrease in the heat insulating material. And since it is not necessary to give a complicated process to a heat insulation box, the raise of cost can be suppressed.
[Brief description of the drawings]
FIG. 1 is a longitudinal front view of a refrigerator with a showcase according to a preferred embodiment of the present invention.
FIG. 2 is a schematic perspective view of a refrigerator with a showcase according to an embodiment.
FIG. 3 is a longitudinal sectional side view of a main part of a refrigerator with a showcase according to an embodiment.
FIG. 4 is a side view showing a refrigeration mechanism of the refrigerator with a showcase according to the embodiment.
FIG. 5 is a schematic configuration diagram illustrating a refrigeration mechanism of the refrigerator with a showcase according to the embodiment.
[Explanation of symbols]
11 Refrigerator body, 12 Showcase, 16 Heat insulation box, 17 Cold room
20 Front panel, 20a Suction port, 23 Machine room, 24 Refrigeration mechanism 27 Cooler, 34 Condenser, 36 Compressor, 38 Inner box, 40 Storage room 47 Cooling pipe, 66 Waste heat space, 67 Drain hose (drain pipe)

Claims (2)

The refrigeration mechanism (24) is housed in a machine room (23) defined internally in the refrigerator body (11), and the refrigerator compartment (17) defined in the heat insulation box (16) of the refrigerator body (11) is provided in the refrigerator room (11). While being cooled by the cooler (27) of the refrigeration mechanism (24), the showcase (12) is disposed on the upper surface of the refrigerator body (11), and the interior of the inner box (38) constituting the showcase (12) In the refrigerator with a showcase configured to cool the storage chamber (40) defined by the cooling pipe (47) disposed in the inner box (38) and connected to the refrigeration mechanism (24),
A drain pipe (67) for discharging drainage such as condensed water generated in the storage chamber (40) is opened so that one end thereof contacts the inner box (38) in the storage chamber (40). Communicatively connected to the showcase (12),
A suction port (20a) provided in a front panel (20) defining the machine room (23) is sucked in, and a condenser (34) and a compression unit constituting the refrigeration mechanism (24) in the machine room (23) . A heat exhaust space (66) through which air heated by heat exchange with the machine (36) flows is defined in the machine room (23) ,
The drain pipe (67), without disposed within the heat-insulating main body (16), provided in the waste heat space (66) inside,
The drainage pipe in said waste heat space (66) (67) that are arranged to intersect with the temperature increase flow of air over substantially the entire length of the drainage pipe (67) Features a refrigerator with a showcase.   The refrigerator with a showcase according to claim 1, wherein the machine room (23) is provided adjacent to an outer side of the heat insulating box (16) in which a refrigerator compartment (17) is defined.

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