JP4688698B2 - Cooling storage - Google Patents

Description

  The present invention relates to a cooling storehouse in which cool air exchanged with a cooler is circulated by a blower in a storage chamber configured in a main body.

  Conventionally, this type of cold storage has low temperature showcases installed in stores such as supermarkets and convenience stores, etc., and has a storage room with an opening on the front surface, and the front opening of the storage room can be opened and closed by an open / close door The product displayed in the storage chamber is cooled to a predetermined temperature by closing the air and circulating the cool air exchanged with the cooler in the storage chamber.

  Also, in prefabricated low-temperature storage (freezer / refrigerator) mainly used for the preservation of food, etc., a heat insulation box is assembled by connecting a plurality of heat insulation panels to each other, and the storage constructed in this heat insulation box By circulating the cool air heat-exchanged with the cooler in the room, articles such as food stored in the storage room are cooled to a predetermined temperature (for example, see Patent Document 1).

  Here, a large number of allergens such as airborne microorganism viruses such as influenza virus and cedar pollen exist in the air. Therefore, in this kind of showcase, prefabricated cold storage and other cooling storages, there is a concern about microbial contamination and allergen contamination of goods and foods stored in the storage chamber.

On the other hand, for the purpose of removing airborne microorganisms and the like, a sterilization apparatus has also been proposed in which electrolyzed water mist is diffused in the air and the electrolyzed water mist is brought into direct contact with airborne microorganisms to inactivate viruses and the like. (For example, refer to Patent Document 2).
Japanese Utility Model Publication No. 5-14145 Japanese Patent Laid-Open No. 2002-181358

  However, when the sterilization apparatus as described above is applied to a cold storage such as a showcase or a prefabricated cold storage, the ozone in the mist directly acts on food in the storage room, so the value as a product is significantly deteriorated. There is a problem. In particular, since the storage chamber is cooled by a cooling means such as a cooler, the mist is supplied to the storage chamber, whereby the humidity rises abnormally, visibility deteriorates, and frost formation on the cooler also increases. Therefore, there is a risk that the cooling performance is also significantly deteriorated. In addition, in the case of goods and articles that dislike moisture, quality deterioration also occurs due to abnormally high humidity.

  The present invention is made in order to solve the conventional technical problem, and provides a cooling storage that can suppress frost formation on the cooler while effectively sterilizing the storage chamber. .

The cooling storage according to the present invention is configured by circulating cold air heat-exchanged with a cooler by a blower in a storage chamber configured in a main body, gas-liquid contact means for holding electrolytic water, and the gas-liquid A sterilizing air path for ventilating the contact means and bringing it into contact with the electrolyzed water; and a cold air inflow amount adjusting means for adjusting the amount of cool air in the storage chamber flowing into the sterilizing air path. A part of the cool air in the storage chamber flowing into the cooler flows into the air path for sterilization of the sterilization means, passes through the gas-liquid contact means, and then passes through the cooler. The sterilization means is configured to merge with cold air, and the sterilization means prohibits the inflow of cold air into the sterilization air path by the cold air inflow amount adjustment means during the defrosting operation of the cooler. To do.

The cooling storage of the invention of claim 2 is the above invention, wherein the sterilization means is located on the air upstream side of the gas-liquid contact means, and an outside air introduction section for introducing outside air into the sterilization air path; An outside air introduction amount adjusting means for adjusting the amount of outside air introduced from the outside air introduction unit is provided.

According to a third aspect of the present invention , the sterilization means is a filter for removing cool air flowing into the sterilization air path and / or impurities in the outside air introduced from the outside air introduction section. It is provided with.

According to a fourth aspect of the present invention , the sterilization means is the electrolyzed water supplied to the gas-liquid contact means or water for generating the electrolyzed water and / or the gas-liquid contact means. The water receiving tray which stores electrolyzed water and the antifreezing heating means for heating this water receiving tray and preventing freezing are provided.

The cooling storage of the invention of claim 5 is characterized in that, in each of the above inventions, the sterilizing means is detachably attached to the main body.

  According to the present invention, the gas-liquid contact means for holding the electrolyzed water in the cooling storage chamber in which the cool air exchanged with the cooler is circulated by the blower in the storage chamber configured in the main body, and the gas-liquid contact means And a sterilizing means having a sterilizing air path for bringing the air into contact with the electrolyzed water, and the sterilizing air path of the sterilizing means is provided in the storage chamber flowing into the cooler. Since a part of the cold air flows in and passes through the gas-liquid contact means and then merges with the cold air that has passed through the cooler, the air supplied to the storage chamber or the storage chamber by contact with the electrolyzed water is sterilized. It becomes possible to perform sterilization in the storage chamber efficiently.

  In particular, the air that has passed through the sterilizing means can be configured not to pass through the cooler, and the inconvenience that the cooler is frosted by contact with the electrolyzed water and humidified is suppressed. It becomes possible to do.

In addition, the sterilization means includes a cold air inflow adjustment means for adjusting the amount of cold air in the storage chamber flowing into the sterilization air path, so that the sterilization means flows into the sterilization air path arbitrarily or automatically. The amount of cool air to be adjusted can be adjusted, and an appropriate amount of cool air flowing into the air path for sterilization can be realized according to the main body provided with the sterilization means. Therefore, the versatility of the sterilization means can be enhanced, and sterilization corresponding to the cooling capacity of each main body becomes possible.

Furthermore, since the sterilization means prohibits the inflow of cold air into the air path for sterilization by the cold air inflow adjustment means during the defrosting operation of the cooler, a part of the sensible heat of the air circulating in the warehouse is It is possible to avoid the fact that it is used to evaporate the electrolyzed water of the sterilization means, and this makes it possible to effectively use the sensible heat of the air circulating in the warehouse to defrost the cooler It becomes. It becomes possible to execute the defrosting operation of the cooler effectively.

According to the invention of claim 2, in the above invention, the sterilization means is located on the air upstream side of the gas-liquid contact means, the outside air introduction part for introducing the outside air into the sterilization air path, and the outside air Since the outside air introduction amount adjusting means for adjusting the amount of outside air introduced from the introduction portion is provided, after the outside air introduced from the outside air introduction portion is positively sterilized by the sterilization means, It becomes possible to introduce outside air.

  As a result, the volume of the air in the main body is reduced by the cooler to reduce the volume and the internal pressure is reduced, thereby eliminating the inconvenience that the main body door is difficult to open and the drainage drain provided in the main body. It is possible to eliminate the inconvenience that outside air randomly enters the main body through a gap between the mouth and the door. Therefore, the air in the main body can be further purified.

According to the invention of claim 3, in each of the above inventions, the sterilization means includes a filter for removing cool air flowing into the sterilization air path and / or impurities in the outside air introduced from the outside air introduction section. Since it is provided, it becomes possible to remove dust, dust, and the like with the filter, and the air in the main body can be further purified.

According to the invention of claim 4, in each of the above-mentioned inventions, the sterilization means is electrolyzed water supplied to the gas-liquid contact means, water for generating the electrolyzed water, and / or electrolysis from the gas-liquid contact means. Since the water receiving tray for storing water and the antifreezing heating means for preventing the freezing by heating the water receiving tray are provided, the inconvenience that the electrolyzed water in the water receiving tray is frozen by the cold air that cools the inside of the main body. Can be prevented.

According to the invention of claim 5, in each of the above inventions, the sterilization means is detachably attached to the main body, so that the sterilization means can be mounted on many models, and versatility can be enhanced. Maintenance and repair work of the sterilization means can be easily performed.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a perspective view of a showcase 1 as an embodiment of the cooling storage of the present invention, and FIG. 2 is a longitudinal side view of the showcase 1. The showcase 1 according to the embodiment is a low-temperature showcase that is installed in a store such as a supermarket or a convenience store and displays products while cooling them, and is attached to both sides of the heat insulation wall 3 having a substantially U-shaped cross section. The main body 2 is composed of the side plates 4 and 4 formed. A storage chamber 5 is formed in a space surrounded by the heat insulating wall 3 and the side plates 4 and 4. Further, in the storage chamber 5, shelves 7..

  A cooler (cooling means) 8 of a cooling device is provided at the upper rear of the storage chamber 5, and a blower 9 for circulating cold air is installed in front of the cooler 8. The cooler 8 and the blower 9 are In the cooling chamber 15 partitioned from the storage chamber 5 by the partition plate 10. The cooling device and the blower 9 are controlled by a main body side control device (not shown) provided in the main body 2.

  The partition plate 10 is formed with a predetermined distance between the rear wall 10A and the back wall 3C of the heat insulating wall 3, and an opening (not shown) is formed in the rear wall 10A. Further, an opening 11 is formed at a position of the partition plate 10 corresponding to the blower 9. Thus, the cold air in the storage chamber 5 sucked into the cooling chamber 15 by the blower 9 from the opening formed in the rear wall 10A is exchanged with the cooler 8 and then discharged into the storage chamber 5 from the opening 11. The inside of the storage chamber 5 is cooled to a predetermined temperature by forced circulation.

  Note that communication holes communicating with the inside of the main body 2 are formed in at least two places on the upper surface of the rear portion of the main body 2, and one of the communication holes forms a partition plate 10 that partitions the storage chamber 5 and the cooling chamber 15. The cold air inlet 18 is formed at a corresponding position between the rear wall 10 </ b> A and the back wall 3 </ b> C of the heat insulating wall 3, and the other communication hole is located downstream of the cooler 8 in the cooling chamber 15. In the embodiment, the air discharge port 19 is formed at the front upper portion of the cooler 8. Before the sterilization apparatus 20 to be described in detail later is attached, the cold air suction port 18 and the air discharge port 19 are closed by a hole closing member.

  Further, door frames 13 are respectively attached to the upper and lower edges of the front opening 12 of the storage chamber 5, and sliding door type glass doors 14 and 14 that allow the inside to be seen through are attached to the door frame 13. 12 is opened and closed freely.

  A machine room 16 is formed below the bottom wall 3A of the heat insulating wall 3. In the machine room 16, a condenser and a compressor (not shown) constituting the refrigerant circuit of the cooler 8 and the cooling device are formed. Etc. are provided. Also, a condenser blower (not shown) is attached to the rear of the condenser, and a grill 17 is formed on the front surface of the machine room 16 so that air is sucked from the grill 17 and waste heat is transferred to the outside from the rear. It is supposed to be discharged.

  On the upper surface of the main body 2 of the showcase 1, that is, on the upper wall 3B of the heat insulating wall 3, a sterilization apparatus 20 as a sterilization means of the present invention is installed. Here, an example of the configuration of the sterilization apparatus 20 will be described with reference to FIG. FIG. 3 shows a longitudinal side view of the sterilization apparatus 20.

  The sterilization apparatus 20 includes a heat insulating material, and includes a box-shaped case 21 that forms a sterilization air path. The bottom of the case 21 is formed on the top surface of the main body 2. A communication hole is formed at a position corresponding to the communication hole at each location. That is, a sterilization device side cold air suction port 22 is formed at a position corresponding to the cold air suction port 18 on the main body 2 side, and a position corresponding to the air discharge port 19 on the main body 2 side is located on the sterilization device side. An air discharge port 23 is formed. In addition, on one side surface of the case 21, in this embodiment, on the rear surface located on the back side of the main body 2, an outside air suction port (outside air introduction portion) 24 is located on the air upstream side of a gas-liquid contact member 30 described later. Is formed. Prefilters 25 and 26 are attached to the suction ports into the sterilization apparatus 20, that is, the sterilization apparatus side cold air suction port 22 and the outside air suction port 24, respectively.

  In the present embodiment, the sterilization apparatus side cold air suction port 22 has a cold air inflow adjustment valve (a cold air inflow adjustment) for adjusting the amount of cold air sent from the main body 2 inside the suction port 22. Means) 27 is provided. The cold air inflow amount adjusting valve 27 is subjected to open / close control and opening degree control by a sterilization device side control device (not shown) provided in the case 21. On the other hand, in the present embodiment, the outside air inlet 24 is provided with an outside air introduction amount adjusting valve (outside air introduction amount adjusting means) 28 for adjusting the amount of outside air introduced from the outside. It has been. The outside air introduction amount adjustment valve 27 is subjected to opening / closing control and opening degree control by the sterilization device side control device. The adjusting valves 27 and 28 are not limited to automatic control by the control device as described above, and may be manually opened and closed. Further, the sterilization apparatus side control apparatus is connected to the main body side control apparatus via an unillustrated energization line, and can input data such as a defrosting operation of the cooler 8, for example.

  And in the case 21 between these suction inlets 22 and 24 and the sterilization apparatus side air discharge opening 23, the gas-liquid contact member 30 with high water retention as a gas-liquid contact means is erected. The gas-liquid contact member 30 is a filter member having a honeycomb structure, and has a structure in which a wide gas contact area is ensured, electrolytic water can be dropped, and clogging is difficult. That is, as shown in FIG. 4, the gas-liquid contact member 30 is formed in a honeycomb shape as a whole by joining a material 30A bent into a wave shape and a flat material 30B. These materials 30A and 30B include materials that are less reactive with electrolyzed water, which will be described later, that is, materials that are less deteriorated by electrolyzed water, such as polyolefin resin-based, PET resin-based, vinyl chloride resin-based, fluororesin-based, or Materials such as ceramic resin are used.

  A water tray 31 having a water level sensor 38 for detecting a predetermined water level is disposed below the gas-liquid contact member 30, and a water supply pipe 33 is connected to the water tray 31. A water pipe (not shown) is connected to the water supply pipe 33 as a supply source of tap water containing chloride ions, and the water supply supplied to the water receiving tray 31 by the water amount adjustment valve 34 based on the output of the water level sensor 38. The amount is adjusted. In addition, the water receiving tray 31 is provided with a temperature sensor 39 for detecting the temperature of tap water containing electrolyzed water received in the water receiving tray 31 and a heater 40 as heating means. The temperature sensor 39 and the heater 40 are anti-freezing means provided to prevent the tap water including the electrolyzed water received in the water receiving tray 31 from freezing. In this embodiment, when detecting + 5 ° C. In addition, when the heater 40 is energized and + 10 ° C. is detected, the heater 40 is deenergized. As a result, it is possible to avoid the inconvenience that the electrolyzed water or the like in the water receiving tray 31 freezes, and even if tap water is not supplied to the water receiving tray 31 for some reason, there is a risk of fire due to emptying. It is possible to avoid the inconvenience that occurs.

  A circulation pump 35 is disposed in the water tray 31. An electrolytic tank 36 is connected to the circulation pump 35, and an electrolytic water supply pipe (electrolyzed water dropping means) 37 is connected to the electrolytic tank 36. The electrolyzed water supply pipe 37 is configured to include a large number of water spray holes (not shown) on the outer periphery.

  The electrolyzer 36 is provided with three pairs of electrodes (not shown) in the embodiment. When the electrodes are energized, the tap water flowing into the electrolyzer 36 is electrolyzed (electrochemical treatment) and activated. Oxygen species are generated. Here, the reactive oxygen species are oxygen molecules having an oxidation activity higher than that of normal oxygen and related substances, and are so-called narrowly defined as superoxide anion, singlet oxygen, hydroxyl radical, or hydrogen peroxide. These active oxygens include so-called broadly active oxygens such as ozone and hypohalous acid. The electrolytic cell 36 is disposed in the vicinity of the gas-liquid contact member 30 and is configured so that the active oxygen species generated by electrolyzing tap water can be quickly supplied to the gas-liquid contact member 30.

The electrode is, for example, an electrode plate having a base made of Ti (titanium) and a coating layer made of Ir (iridium) or Pt (platinum). The current value applied to these electrodes is 20 mA (milliamperes) / current density. A predetermined free residual chlorine concentration (for example, 1 mg (milligram) / l (liter)) is generated as cm ² (square centimeter).

When the tap water is energized by the above electrode,
4H ⁺ + 4e ⁻ + (4OH ⁻ ) → 2H ₂ + (4OH ⁻ )
In the electrode constituting the anode,
2H ₂ O → 4H ⁺ + O ₂ + 4e ⁻
At the same time, the chloride ions contained in the water (pre-added to tap water)
2Cl ⁻ → Cl ₂ + 2e ⁻
In addition, this Cl ₂ reacts with water,
Cl ₂ + H ₂ O → HClO + HCl
It becomes.

  In this configuration, when the electrode is energized, HClO (hypochlorous acid) having a high sterilizing power is generated, and cold air or outside air is passed through the gas-liquid contact member 30 supplied with this hypochlorous acid. The gas-liquid contact member 30 can prevent propagation of germs, and can inactivate cold air passing through the gas-liquid contact member 30 and viruses floating in the outside air. Further, when the odor passes through the gas-liquid contact member 30, it reacts with hypochlorous acid in the electrolytic water, and is ionized and dissolved to be removed from the air and deodorized.

  Note that the sterilization apparatus 20 in the present embodiment positively contacts the cold air introduced into the case 21, that is, the cold air or the outside air in the sterilization air path with the gas-liquid contact member 30. The wall is provided with a partition wall 41 formed to hang down above the electrolyzed water supply pipe 37, and cool air or outside air introduced into the case 21 stays in the vicinity of the gas-liquid contact member 30 for a predetermined period. For the purpose of making it, it is formed on the bottom wall of the case 21 and at the opening edge on the gas-liquid contact member 30 side of the sterilization apparatus side air discharge port 23 by extending a predetermined dimension upward. A partition wall 42 is formed.

  Next, the operation of the sterilization apparatus 20 will be described. When the operation of the sterilizer 20 is started, the circulation pump 35 is driven, and the tap water accumulated in the water receiving tray 31 is supplied to the electrolytic cell 36. In this electrolytic cell 36, the tap water is electrolyzed by the energization of the electrodes to generate electrolyzed water containing active oxygen species (electrochemical treatment). The electrolyzed water is sprinkled on the upper edge of the gas-liquid contact member 30 through a water spray hole (not shown) of the electrolyzed water supply pipe 48, and the electrolyzed water soaked in the upper edge of the gas-liquid contact member 30 is discharged. Wet gradually toward the bottom.

  The surplus electrolyzed water is received in the water tray 31. In the configuration of the embodiment, when the amount of water is reduced by evaporation or the like, the water amount adjustment valve 34 provided in the water supply pipe 33 is controlled to open and close based on the output of the water level sensor 38, and the water tray 31 receives water. Tap water is supplied as appropriate. In the present embodiment, a water pipe (not shown) is connected to the water supply pipe 33, and the water amount adjustment valve 34 is controlled to open and close based on the output of the water level sensor 38, whereby the water tray 31 has a predetermined water level. However, the present invention is not limited to this. For example, a water supply tank (not shown) in which tap water is separately stored is provided, and tap water is appropriately supplied from the water supply tank so that the water receiving tray 31 is provided. It is also possible to adopt a configuration that maintains a predetermined water level.

  The gas-liquid contact member 30 wetted with the electrolyzed water is introduced into the case 21 from the outside through the cool air flowing into the case 21 via the sterilization device side cold air suction port 22 and from the outside via the outside air suction port 24. The outside air is supplied by ventilation. The cold air and the outside air that have flowed into the case 21 come into contact with the active oxygen species that have soaked into the gas-liquid contact member 30 provided in the sterilization air path, and are sterilized, and then the partition wall 41 in the case 21. , 42 and discharged from the sterilization apparatus side air discharge port 23.

  In the present embodiment, the sterilization apparatus 20 is provided on the upper surface of the main body 2 of the cooling storage 1, and the sterilization apparatus side cold air suction port 22 corresponds to the cold air suction port 18 formed on the main body 2 side so that they communicate with each other. At the same time, the sterilization apparatus side air discharge port 23 corresponds to the air discharge port 19 formed on the main body 2 side, and these are communicated with each other.

  Therefore, a part of the cool air circulating in the display chamber 5 by the operation of the blower 9 is passed through the cool air suction port 18 and the sterilization device side cold air suction port 22 for the sterilization air path in the case 21 of the sterilization device 20. Flow into. Note that the amount of cold air flowing into the sterilization apparatus 20 is automatically or arbitrarily adjusted by the cold air inflow amount adjusting valve 27 as described above. The remaining cold air directly flows into the cooling chamber 15 from an opening (not shown) formed in the rear wall 10A of the partition plate 10 and exchanges heat with the cooler 8 disposed in the cooling chamber 15, and then the blower 9 After being accelerated further by the above, the liquid is discharged into the storage chamber 5 from the opening 11.

  When the outside air introduction amount adjustment valve 28 provided in the sterilization apparatus 20 is opened, outside air is introduced into the case 21. Therefore, the cold air that has flowed into the case 21 is supplied to the gas-liquid contact member 30 through the outside air, whereby the cold air and the outside air are sterilized. As described above, the sterilized air discharged from the sterilization apparatus side air discharge port 23 flows into the cooling chamber 15 in the main body 2 from the air discharge port 19.

  Here, the air discharge port 19 is formed on the downstream side of the cooler 8 in the cooling chamber 15, in the present embodiment, on the upper front side of the cooler 8. And the outside air) come into contact with the active oxygen species soaked in the gas-liquid contact member 30, and then merge with the cold air after heat exchange in the cooler 8 to form the storage chamber 5 through the opening 11 formed in the partition plate 10. It is discharged inside.

  For example, when influenza virus invades into the cold air in the storage chamber 5 or the outside air introduced into the sterilizing apparatus 20, the reactive oxygen species is used to remove the surface protein (spike) of the virus essential for the infection. It has a function of destroying and disappearing (removing). When this function is destroyed, the influenza virus and the receptor (receptor) necessary for the infection of the virus are not bound, thereby preventing the infection. As a result of a verification test in collaboration with the Institute for Hygiene and Environment, it was found that 99% or more of the virus can be removed when the air in which the influenza virus has entered is passed through the gas-liquid contact member 30 having this configuration.

  In this way, a sterilization device 20 is provided through which the cool air in the storage chamber 5 and the outside air introduced into the storage chamber 5 are ventilated, and the sterilization device 20 holds electrolytic water and ventilates the sterilization device 20. Since the cooled air and the electrolyzed water are brought into contact with each other, the air discharged into the storage chamber 5 can be sterilized by the contact with the electrolyzed water, and the sterilization in the storage chamber 5 can be efficiently performed. Will be able to do. In this case, since the mist-like electrolyzed water is not diffused into the storage chamber 5, the visibility in the storage chamber 5 deteriorates or dew condensation occurs on the product due to abnormally high humidity in the storage chamber 5. There is no inconvenience.

  In particular, since the air after being sterilized by the sterilization apparatus 20 in this embodiment is configured to merge with the cold air that has passed through the cooler 8, the air that has passed through the sterilization apparatus 20 is cooled by the cooler. Therefore, it is possible to suppress the inconvenience that the chiller 8 is frosted by the air that has been sterilized and humidified by contact with the electrolyzed water.

  In addition, the sterilization apparatus 20 includes a gas-liquid contact member 30 that is formed of a material that is less reactive with the electrolyzed water, holds the electrolyzed water, and allows cold air or outside air to pass through. The durability of 30 can be improved and the life can be extended. Further, since the sterilization apparatus 20 is provided with an electrolyzed water supply pipe 37 for dropping electrolyzed water generated in the electrolytic bath 36 to the gas-liquid contact member 30, the electrolyzed water is evenly distributed over the entire area of the gas-liquid contact member 30. It is possible to sterilize the cold air and outside air that pass through it uniformly.

  In particular, in the embodiment, the air in the vicinity of the sterilization apparatus side air discharge port 23 is sucked into the cooling chamber 15 by the cool air circulation blower 9 disposed in the cooling chamber 15 of the main body 2. The cool air and the outside air in the case 21 can be positively ventilated to the gas-liquid contact member 30, and it is possible to ventilate the cool-air and the external air to the gas-liquid contact member 30 without providing a special blower for ventilation. Thus, the number of parts and the cost can be reduced.

  Moreover, since electrolyzed water containing hypochlorous acid is received in the water receiving tray 31 in the embodiment, no germs are generated in the tray, and slime is prevented from being generated. Therefore, the frequency of cleaning and maintenance of the water tray 31 is reduced, and the labor for maintenance and the like can be reduced.

  On the other hand, when the defrosting operation of the cooler 8 disposed in the cooling chamber 15 is executed, the sterilization apparatus-side control device performs cooling air based on input of data related to the defrosting operation from the main body-side control device. The inflow amount adjusting valve 27 is fully closed to prohibit the inflow of cold air into the case 21 of the sterilization apparatus 20, that is, into the sterilization air path.

  As a result, it is possible to avoid in advance that a portion of the sensible heat of the air circulating in the storage chamber 5 is used to evaporate the electrolyzed water of the sterilization apparatus 20, and the air circulating in the main body 2. This sensible heat can be effectively used for defrosting the cooler 8. Therefore, an effective defrosting operation of the cooler 8 can be performed.

  In the present embodiment, the sterilization apparatus 20 is detachably attached to the main body 2 of the cooling storage 1 and matches the communication hole formed in the sterilization apparatus 20 with the communication hole formed on the upper surface of the main body 2. Thus, the cool air in the storage chamber 5 in the main body 2 can be easily sterilized by the sterilization apparatus 20. For this reason, the sterilization apparatus 20 can be mounted on multiple models, the versatility can be enhanced, and the sterilization apparatus 20 itself can be easily maintained and repaired.

  In addition, the amount of cold air in the case 21 of the sterilization apparatus 20, that is, in the storage chamber 5 flowing into the sterilization air path can be automatically or arbitrarily adjusted by the cold air inflow amount adjustment valve 27. Therefore, as described above, even if the sterilization apparatus 20 is set to be compatible with multiple models, an appropriate amount of cold air flowing into the sterilization apparatus 20 is realized for each cooling storage 1. It becomes possible. Therefore, also by this, the versatility of the sterilization apparatus 20 can be enhanced, and sterilization corresponding to the cooling capacity of each main body 2 becomes possible.

  In the present embodiment, the sterilization apparatus 20 is located on the air upstream side of the gas-liquid contact member 30 and is formed with an outside air inlet (outside air introduction part) 24 for introducing outside air into the sterilization air path. The outside air inlet 24 is provided with an outside air introduction amount adjusting valve 27 for adjusting the outside air introduction amount. Therefore, for example, the adjustment valve 27 is adjusted so that the ratio of the amount of cool air flowing from the main body 2 to the sterilization air path becomes 10: 1 (cold air amount: outside air amount). Thereby, the volume in which the air in the main body 2 is cooled by the cooler 8 is reduced and the internal pressure is lowered, so that the inconvenience that the door 14 of the main body 2 is difficult to open can be solved. Further, it is possible to eliminate the inconvenience that the outside air randomly enters the main body 2 from the drain outlet provided in the main body 2 or the gap between the doors 14.

  In particular, the outside air introduced into the main body 2 is discharged through the outside air suction port 24 so as to be positively sterilized by active oxygen species in the gas-liquid contact member 30 and then discharged into the main body 2. Therefore, the air in the main body 2 can be further purified.

  In addition, since the pre-filters 25 and 26 are provided in the outside air suction port 24 and the sterilization apparatus side cold air suction port 22 as described above, the cool air flowing into the sterilization air path and the outside air suction port 24 are provided. Impurities such as dust and dirt in the outside air to be introduced can be removed, and this also makes it possible to purify the air in the main body 2. In addition, since dust and dust can be prevented from adhering to the gas-liquid contact member 30, it is possible to prevent the gas-liquid contact member 30 from being clogged and to prolong the life of the filter.

  The sterilization apparatus 20 has a possibility that the electrolyzed water in the water receiving tray 31 becomes low temperature and freezes when cold air is sucked into the sterilization air path. However, in this embodiment, the water tray 31 is provided with a temperature sensor 39 that detects the temperature of the electrolyzed water, and a heater 40 that is energized and controlled based on the output of the temperature sensor 39. Thereby, when the temperature sensor 39 detects, for example, + 5 ° C., the heater 40 is energized to heat the water receiving tray 31 itself or the electrolytic water stored in the water receiving tray 31, thereby freezing the electrolytic water. This inconvenience can be avoided in advance.

  Therefore, although the predetermined water level is detected in the water tray 31, the circulating water 35 cannot suck up the electrolyzed water (and tap water) and appropriately generates the electrolyzed water in the electrolyzer 36. This makes it impossible to perform the sterilization process because the gas-liquid contact member 30 is dried. Accordingly, it is possible to smoothly sterilize the cold air and the outside air of the sterilization air path of the sterilization apparatus 20 with the gas-liquid contact member 30 in which the electrolytic water is impregnated.

  Further, when the temperature sensor 39 detects, for example, + 10 ° C., the heater 40 is turned off. Thereby, even if it is a case where tap water is not supplied to the water receiving tray 31 for some reason, the inconvenience which causes the danger of a fire by emptying can be avoided.

In the above configuration, it is desirable to adjust the concentration of the active oxygen species (hypochlorous acid) in the electrolytic water to a target concentration. The target concentration is usually set to a concentration that inactivates viruses or the like (for example, mold fungi) that are often present at the installation location of the showcase 1 (for example, a supermarket or a convenience store). In this case, for example, the concentration of hypochlorous acid in the electrolytic water is adjusted by changing the current flowing through the electrodes or the voltage applied between the electrodes. As an example, the concentration of hypochlorous acid can be changed to a high concentration by increasing the current flowing through the electrode (for example, 40 mA / cm ^{2 in} terms of current density). According to this, since it is only necessary to change the voltage applied to the electrode without using a new device or the like, cost reduction and space saving can be achieved.

It is a perspective view of the showcase as an Example of the cooling storage of this invention. It is a vertical side view of the showcase of FIG. It is a vertical side view of the sterilization apparatus installed in the main body of the showcase of FIG. It is a front view of the gas-liquid contact member of the bacteria elimination apparatus of FIG.

1 Showcase (cooling storage)
2 Body 3 Thermal insulation wall 5 Storage room 8 Cooler (cooling means)
DESCRIPTION OF SYMBOLS 9 Blower 10 Partition plate 10A Rear wall 11 Opening 12 Front opening 14 Glass door 15 Cooling chamber 18 Cold air inlet 19 Air outlet 20 Sterilizer 21 Case 22 Sterilizer side cold air inlet 23 Sterilizer side air outlet 24 Outside air suction port 25, 26 Pre-filter 27 Cold air inflow adjustment valve 28 Outside air introduction amount adjustment valve 30 Gas-liquid contact member 31 Water receiving tray 33 Water supply pipe 34 Water amount adjustment valve 35 Circulation pump 36 Electrolysis tank 37 Electrolyzed water supply pipe (electrolyzed water dripping) means)
38 Water level sensor 39 Temperature sensor 40 Heater (heating means for preventing freezing)

Claims (5)

In a cooling storage room configured by circulating cool air exchanged with a cooler by a blower in a storage room configured in the body,
A gas-liquid contact means for holding electrolyzed water; a sterilization air path for passing air through the gas-liquid contact means to contact the electrolyzed water; and the storage chamber flowing into the sterilization air path A sterilization means comprising a cold air inflow amount adjusting means for adjusting the amount of cold air ;
Part of the cool air in the storage chamber flowing into the cooler flows into the sterilization air path of the sterilization means, and after passing through the gas-liquid contact means, merges with the cool air that has passed through the cooler. Further , the sterilization means prohibits the inflow of cold air into the sterilization air path by the cold air inflow amount adjusting means during the defrosting operation of the cooler. The sterilization means is located on the air upstream side of the gas-liquid contact means, and introduces an outside air introduction section for introducing outside air into the sterilization air path, and an amount of outside air introduced from the outside air introduction section. The cooling storage according to claim 1, further comprising an outside air introduction amount adjusting means for adjusting . The sterilization means includes a filter for removing cool air flowing into the sterilization air path and / or impurities in the outside air introduced from the outside air introduction section. The cooling storage box according to claim 2 . The sterilization means includes electrolyzed water supplied to the gas-liquid contact means or water for generating the electrolyzed water, and / or a water tray that stores the electrolyzed water from the gas-liquid contact means, and the water tray The cooling storage according to any one of claims 1 to 3, further comprising: anti-freezing heating means for heating the container to prevent freezing . The cooling storage according to any one of claims 1 to 4, wherein the sterilizing means is detachably attached to the main body .

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