JP2019026377A - Freshness keeping device - Google Patents

Abstract

To provide a freshness keeping device capable of maintaining freshness of all stored objects being stored in a storage container.SOLUTION: A freshness keeping device 1 for maintaining freshness of a stored object C that is provided in a storage container 100 in which a circulating flow of air flowing along a ceiling portion 104, side portions 105 and 105, and a bottom portion 106 is formed includes: a photocatalyst surface layer 2 provided on at least one location of the ceiling portion 104, the side portions 105 and 105, and the bottom portion 106 along the circulation flow of air flowing in the storage container 100; and a light source 3 for irradiating the photocatalyst surface layer 2 with light.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a freshness holding device provided for holding the freshness of a stored item in a storage container for storing or transporting the stored item such as fruits and vegetables, flowers, and other fresh foods.

  Conventionally, in storage containers for storing or transporting things such as fruits and vegetables, flowers, and other fresh foods, the internal air is circulated while adjusting the temperature, humidity, etc. using a circulation device such as a refrigerator unit. However, the maturation and growth of fruits and flowers are promoted by ethylene gas generated from the fruits and vegetables, and the freshness of the contents may be reduced.

  Then, like patent document 1, the air which blows off from the blower outlet provided in the bottom part front side of a container (storage container) is taken in in a housing | casing from an air intake port, and the ethylene gas removal part provided in a housing | casing is allowed to pass through. Accordingly, there is disclosed a freshness maintaining device that can adsorb or decompose ethylene gas contained in air. According to this, an ethylene gas in a container is removed using a circulating flow of air in the container. The ethylene gas concentration can be reduced by adsorption or decomposition.

Japanese Patent Laying-Open No. 2006-90088 (page 12, FIG. 2)

  However, in Patent Document 1, since the casing of the freshness maintaining device is provided in front of the air outlet provided in front of the bottom of the container, the design air circulation flow inside the container is obstructed. There has been a problem that the freshness of some of the contents exposed to the ethylene gas staying around the contents decreases due to the non-uniform circulation of air in the container.

  The present invention has been made paying attention to such a problem, and an object of the present invention is to provide a freshness holding device capable of maintaining the freshness of all the items stored in the storage container.

In order to solve the above problems, the freshness maintaining device of the present invention is
A freshness holding device that is provided in a storage container in which a circulating flow of air that flows along the ceiling, sides, and bottom is formed, and holds the freshness of the contents,
The photocatalyst surface layer provided in at least any one of the ceiling part, the side part, and the bottom part along the circulation flow of the air in the storage container, and a light source that irradiates the photocatalyst surface layer with light. .
According to this feature, the photocatalyst surface layer is excited by the light irradiated from the light source and can adsorb or decompose ethylene gas generated from the contained material. This photocatalyst surface layer circulates air inside the storage container. Since it is provided along the flow, the ethylene gas circulating with the air inside the storage container can be uniformly adsorbed or decomposed, so that the ethylene gas concentration inside the storage container is uniformly reduced and stored in the storage container. The freshness of all contained items can be maintained.

The photocatalyst surface layer is provided along the longitudinal direction of at least one of the ceiling portion, the side portion, and the bottom portion of the storage container.
According to this feature, since the circulating flow of air flows along the longitudinal direction of the storage container, the photocatalyst surface layer is provided along the longitudinal direction of the storage container. Thus, ethylene gas can be efficiently adsorbed or decomposed over a wide range.

The photocatalyst surface layer is provided on the ceiling portion and the bottom portion of the storage container.
According to this feature, in the storage container, the photocatalyst surface layer is provided on the ceiling and the bottom where the air circulation flow is stably formed, so that the ethylene gas inside the storage container can be removed using the air circulation flow. It can reliably adsorb or decompose.

The photocatalyst surface layer is formed by coating a base material of a fiber assembly.
According to this feature, since the surface area of the photocatalyst surface layer to be coated can be increased by using the fiber assembly as a base material, it becomes easy to adsorb ethylene gas to the excited photocatalyst surface layer, and ethylene by the photocatalyst surface layer Since the fiber assembly has air permeability while enhancing the gas decomposing ability, it is possible to suitably keep the circulating air flow inside the storage container.

The light source is provided in the vicinity of a corner formed by the ceiling portion and the side portion of the storage container.
According to this feature, the light source is provided in the vicinity of the corner formed by the ceiling portion and the side portion of the storage container, so that the light source does not interfere with the air circulation flow inside the storage container, and the storage container. It is possible to irradiate the photocatalyst surface layer with light without obstructing the loading and unloading.

The bottom portion has a plurality of rails extending in the longitudinal direction, and the photocatalytic surface layer and the light source are provided between the plurality of rails.
According to this feature, the photocatalyst surface layer and the light source can be protected from the contents placed on the rail by providing the photocatalyst surface layer and the light source between the plurality of rails extending in the longitudinal direction at the bottom of the storage container. At the same time, the circulation of air at the bottom of the storage container is not affected by the arrangement of the stored items, and ethylene gas can be reliably adsorbed or decomposed by the photocatalytic surface layer provided between the rails.

The photocatalyst surface layer provided between the plurality of rails is unitized with the light source.
According to this feature, the photocatalyst surface layer provided between the plurality of rails is unitized with the light source, so that the photocatalyst surface layer and the light source can be easily installed and removed between the rails. Can be increased.

It is a perspective view which shows the container in which the freshness holding | maintenance apparatus in Example 1 is provided. It is a partial cross section perspective view which shows the installation position of the freshness holding | maintenance apparatus in Example 1. FIG. 2 is an enlarged view showing the structure of a nonwoven fabric coated with a photocatalyst surface layer in Example 1. FIG. It is a front view which shows the installation position of the freshness holding | maintenance apparatus in Example 1. FIG. It is sectional drawing of the side view which shows the circulation flow of the air in the storage space of the container in Example 1. FIG. It is a partial cross section perspective view which shows the circulation flow of the air in the storage space of the container in Example 1. FIG. It is a front view which shows the state which looked at the accommodation space of the container in Example 2 from the opening side. It is sectional drawing of the side view which shows the structure of the container in Example 2. FIG. It is a perspective view which shows the example of installation of the freshness holding | maintenance apparatus to the duct space in Example 2. FIG.

  EMBODIMENT OF THE INVENTION The form for implementing the freshness holding | maintenance apparatus which concerns on this invention is demonstrated below based on an Example.

  A freshness maintaining apparatus according to Embodiment 1 will be described with reference to FIGS. Hereinafter, the lower left side in FIG. 1 will be described as the front side (front side) of the container in which the freshness maintaining device is provided, and the description will be made with reference to the vertical and horizontal directions when viewed from the front side.

  The freshness holding device is provided in a container 100 (storage container) for storing or transporting the stored items C such as fruits and vegetables, flowers, and other fresh foods. In this embodiment, the container 100 to which the unit cooler 110 (see FIG. 2) is attached will be described as an example of the storage container. However, the storage container to which the freshness maintaining device is applied is an endwall type refrigerated container. Or a warehouse equipped with a refrigerator unit.

  First, the container 100 provided with the freshness holding device will be described. As shown in FIGS. 1 and 5, the container 100 is formed in a rectangular parallelepiped shape that is long in the front-rear direction, and the entire surface is insulated from an aluminum alloy or stainless steel outer plate and inner plate such as hard urethane. It is configured by filling the material. Moreover, the container 100 is provided with the opening part 101 opened to the front, and this opening part 101 can be opened and closed by the doors 102 and 102.

  As shown in FIGS. 4 and 5, the front doors 102 and 102, the rear facing portion 103 facing the doors 102, the upper ceiling portion 104, the left and right side portions 105 and 105, and the lower bottom portion 106. Thus, a substantially rectangular parallelepiped accommodation space S is formed inside the container 100.

  The bottom portion 106 of the container 100 is made of an aluminum alloy that is provided on the bottom surface material 106a (inner plate) and the top surface of the bottom surface material 106a, extends in the front-rear direction (longitudinal direction) and is spaced apart in parallel in the left-right direction. It comprises a plurality of rails 120, 120,. The rail 120 is composed of a base portion 120a whose lower end is fixed to the bottom surface material 106a and extending in the vertical direction, and a plate-like portion 120b extending in the left-right direction from the upper end portion of the base portion 120a, and has a T-shaped cross section. doing. Note that the upper surfaces of the plate-like portions 120b, 120b,... Of the plurality of rails 120, 120,.

  Further, a rectangular duct space D that is partitioned by the bottom surface material 106a of the bottom portion 106 of the container 100 and the adjacent rail 120 and extends in the front-rear direction is formed below the plate-like portion 120b of the rail 120. . Note that through holes 120c (see FIG. 5) penetrating in the left-right direction are formed in the base portion 120a of the rail 120 at predetermined intervals in the front-rear direction, and the left and right duct spaces D are sandwiched between the base portions 120a of the rail 120. Are communicating.

  Next, the freshness holding device 1 provided in the container 100 will be described in detail. As shown in FIGS. 1 and 2, the freshness maintaining device 1 is formed on the surface of a nonwoven fabric 20 (fiber assembly) that is attached along the front-rear direction of the ceiling portion 104 and the side portions 105 and 105 of the container 100. And a plurality of light sources 3, 3,... Provided in the vicinity of a corner formed on the upper side of the accommodation space S by the ceiling portion 104 and the side portion 105 of the container 100.

  As shown in FIG. 3, the photocatalytic surface layer 2 is formed as a Tiosky Coat (registered trademark) layer having a nonwoven fabric 20 as a base material and coated on the surface of the fiber. As shown in FIGS. 2 and 4, the nonwoven fabric 20 having the surface of the photocatalyst 2 formed on the surface thereof is a side portion from the top surface material 104 a (inner plate) of the ceiling portion 104 constituting the accommodation space S of the container 100. By being attached to the side material 105a (inner plate) 105 in an L shape when viewed from the front, a predetermined range including a corner formed above the accommodation space S by the ceiling portion 104 and the side portion 105 of the container 100 is provided. Is provided. In addition, the nonwoven fabric 20 in which the photocatalyst surface layer 2 was formed on the surface may be provided over the full width of the ceiling part 104 in the left-right direction. Moreover, the base material of the photocatalyst surface layer is not limited to a fibrous one, and may be a film or a plate.

  The photocatalyst surface layer 2 formed on the surface of the nonwoven fabric 20 is mainly composed of titanium oxide, and is excited by irradiating the surface with ultraviolet UV (light), and is generated from the contents C (particularly fruits and vegetables) in the excited portion. By adsorbing ethylene gas, it can be decomposed into water and carbon dioxide. The photocatalyst surface layer 2 can decompose organic substances, bacteria, viruses and the like in addition to ethylene gas, and can also ensure high deodorization and antibacterial properties in the accommodation space S of the container 100.

  As shown in FIG. 2 and FIG. 4, the light source 3 is a fluorescent tube (so-called black light) that emits ultraviolet UV, and is formed above the accommodation space S by the ceiling portion 104 and the side portion 105 of the container 100. Are supported at both ends by a pair of brackets 31 extending from the upper side of the side portion 105 toward the accommodation space S side, and a plurality of light sources 3, 3,. ing. Further, on the diagonally lower side in the direction away from the corner of the light source 3, a reflector 30 is provided so as to face the ceiling portion 104 and the side portion 105 of the container 100 and supported by a bracket (not shown). The light source 3 is supplied with power from a power source (not shown) different from the power source for the unit cooler 110. Furthermore, the light source may be an LED light source, an LD light source, an OLED light source, or the like as long as it can irradiate ultraviolet rays. The shape is not limited to a tubular shape, and may be a line shape, a seal shape, a tape shape, or the like. Also good. Further, the wavelength of the light source 3 is not limited to ultraviolet rays, and may be adjusted to the reaction wavelength of the photocatalyst surface layer 2.

  As shown by the arrow in FIG. 4, in the accommodation space S of the container 100, the ultraviolet ray UV irradiated from the light source 3 is reflected by the reflecting plate 30, thereby providing the nonwoven fabric 20 having the photocatalyst surface layer 2 formed on the surface. The predetermined range including the corner formed on the upper side of the accommodation space S by the ceiling portion 104 and the side portion 105 of the container 100 is set to be the irradiation range of the ultraviolet light UV from the light source 3. In addition, the illumination range of the ultraviolet rays UV by the light source 3 may be set wider than a predetermined range in which the above-described nonwoven fabric 20 is provided by adjusting the reflection angle of the ultraviolet rays UV by the reflector 30, for example. Furthermore, although the number and installation positions of the light sources 3 in the container 100 may be adjusted as appropriate, the irradiation range of the ultraviolet rays UV from the light sources 3 includes at least a part of the photocatalytic surface layer 2 provided along the air circulation flow described later. For example, the ceiling portion 104 may be provided.

  Next, the air circulation flow in the accommodation space S of the container 100 will be described in detail. In addition, the air circulation flow in the present embodiment is a flow of air (cold air) circulating through the accommodation space S of the container 100 by the operation of the unit cooler 110.

  As shown in FIG. 5, a ceiling-mounted unit cooler 110 is attached to the ceiling portion 104 of the container 100 on the rear side. The unit cooler 110 mainly includes an evaporator 112, a blower fan 113 disposed on the front side of the evaporator 112, and a casing 114 that houses the evaporator 112 and the blower fan 113. The evaporator 112 is connected to an outdoor unit (not shown) by a refrigerant pipe 111 inserted into the opposite end portion 103 of the container 100, and constitutes a refrigeration cycle.

  As shown by arrows in FIGS. 5 and 6, the air in the accommodation space S of the container 100 is sucked from the suction port 114 b formed on the rear side of the casing 114 constituting the unit cooler 110 by the operation of the blower fan 113. Then, after passing through the evaporator 112 and being cooled by heat exchange, it is blown out from an outlet 114 a formed on the front side of the housing 114.

  The air blown forward from the unit cooler 110 moves above the contents C along the ceiling portion 104 of the container 100 and then moves downward along the doors 102 and 102 in the closed state on the front side. Then, the air is sucked into the duct space D from the front end side of the rail 120 provided on the bottom portion 106 and moves to the rear side along the bottom portion 106.

  The air that has moved to the rear side in the duct space D along the bottom portion 106 is blown out from the rear end side of the rail 120, moves upward along the opposite end portion 103, and the suction port 114 b on the rear side of the unit cooler 110. The main air circulation flow that forms a substantially section-shaped flow along the longitudinal direction of the accommodation space S is formed.

  Further, part of the air moving in the duct space D along the bottom portion 106 of the container 100 moves in the left-right direction through the through hole 120 c formed in the base portion 120 a of the rail 120.

  In addition, the lower air around the accommodation C moves downward between the front and rear left and right accommodations C, and is formed between the plate-like portions 120b of the adjacent rails 120 in the front-rear direction. The air is sucked from the extending gap G (see FIG. 4) and joined to the air flow that moves in the duct space D along the bottom portion 106 of the container 100. It moves to the upper side through the storage object C and joins the circulating flow of the air moving above the storage object C along the ceiling part 104 of the container 100 described above.

  Further, as shown in FIG. 6, a part of the air blown forward from the unit cooler 110 circulates along the side portion 105 along the side of the accommodation C, and a part of the air flows through the doors 102, 102. Air that moves to the front side of the accommodation C along the ceiling 104 and moves downward along the doors 102 and 102 along the ceiling 104 described above (not shown for convenience of explanation). Join the circulation of In addition, although not shown in figure, a part of the air which circulates the side of the accommodation C along the side part 105 moves between the accommodations C arrange | positioned forward and backward, and the air in the circumference | surroundings of the accommodation C mentioned above The air flow that moves in the duct space D along the bottom portion 106 of the container 100 or the circulating flow of the air that moves above the contents C along the ceiling portion 104 by moving upward or downward with the flow of To join.

  Thus, the air around the contents C is uniformly circulated by the circulating flow of air formed along the longitudinal direction of the accommodation space S of the container 100. The container 100 is provided with a ventilation port (not shown) so that air in the accommodation space S can be appropriately supplied and exhausted.

  According to this, as described above, the nonwoven fabric 20 constituting the freshness maintaining device 1 is attached to the ceiling portion 104 and the side portions 105 and 105 along the air circulation flow in the accommodation space S of the container 100, and the nonwoven fabric. Since the photocatalyst surface layer 2 formed on the surface 20 is provided with the light source 3 for irradiating the ultraviolet ray UV, the photocatalyst surface layer 2 is excited by the ultraviolet ray UV irradiated from the light source 3 and adsorbs ethylene gas generated from the contents C. Alternatively, since the photocatalyst surface layer 2 is provided along the air circulation flow in the accommodation space S, the ethylene gas circulating with the air in the accommodation space S can be uniformly adsorbed or decomposed. The ethylene gas concentration in the storage space S is uniformly reduced to maintain the freshness of all the storage items stored in the storage space S. Can.

  Further, since the air circulation flow flows along the longitudinal direction of the accommodation space S, the nonwoven fabric 20 having the photocatalyst surface layer 2 formed on the surface is provided along the longitudinal direction of the ceiling portion 104 and the side portions 105 and 105 of the container 100. As a result, the ethylene gas can be efficiently adsorbed or decomposed over a wide range of the accommodation space S using the circulating air flow.

  Moreover, since the surface area of the photocatalyst surface layer 2 to be coated can be increased by using the nonwoven fabric 20 that is a fiber assembly as a base material, the photocatalyst surface layer 2 was excited by ultraviolet rays UV irradiated from the light source 3. Since the non-woven fabric 20 has air permeability while enhancing the ability of the photocatalyst surface layer 2 to decompose ethylene gas, the non-woven fabric 20 has air permeability, so that the circulating air flow in the accommodation space S can be suitably maintained. Furthermore, not only can the surface area be increased compared to that coated on a flat substrate, but also the peeling of the photocatalyst surface layer 2 can be suppressed, and the decomposition ability of the photocatalyst surface layer 2 is easily maintained for a long period of time.

  Moreover, the nonwoven fabric 20 in which the photocatalyst surface layer 2 was formed on the surface is provided in a predetermined range including a corner formed on the upper side of the accommodation space S by the ceiling portion 104 and the side portion 105 of the container 100. Regardless of the arrangement and quantity of the contents C to be stored in the storage space S, ethylene gas is easily received at the position where the light source 3 is easily irradiated with ultraviolet rays UV and the circulating air flow is stably formed in the storage space S. Can be adsorbed and decomposed, so that the photocatalyst surface layer 2 can reliably adsorb or decompose ethylene gas circulating in the accommodation space S together with air.

  Further, the light source 3 is provided in the vicinity of the corner formed on the upper side of the accommodation space S by the ceiling portion 104 and the side portion 105 of the container 100, so that it does not interfere with the air circulation flow in the accommodation space S. In addition, the photocatalyst surface layer 2 formed on the surface of the nonwoven fabric 20 can be irradiated with light without interfering with the loading and unloading of the contents C with respect to the container 100. Furthermore, the non-woven fabric 20 and the light source 3 on which the photocatalytic surface layer 2 constituting the freshness maintaining device 1 is formed are near the corner formed on the upper side of the accommodation space S by the ceiling portion 104 and the side portion 105 of the container 100. By being provided, it is possible to prevent breakage due to the contact of the stored item C, and it is possible to store the stored item C without changing the design placement surface and upper load limit of the stored item C in the receiving space S. .

  In addition, the freshness maintaining apparatus 1 of the present invention decomposes ethylene gas by the photocatalyst surface layer 2 that is irradiated with ultraviolet rays UV from the light source 3 by using a designed air circulation flow in the accommodation space S of the container 100. Therefore, there is no need to change such as improving the blowing performance of the circulation device of the refrigerator unit such as the unit cooler 110 attached to the container 100. Furthermore, since it is not necessary to supply and exhaust air for exhausting the ethylene gas from the storage space S of the container 100, temperature changes in the storage space S can be suppressed, and the contents C stored in the storage space S can be suppressed. Easy to maintain freshness.

  Next, a freshness maintaining apparatus according to the second embodiment will be described with reference to FIGS. Note that the same components as those shown in the embodiment are given the same reference numerals and redundant description is omitted.

  As shown in FIGS. 7 and 8, in the container 200 (storage container) according to the second embodiment, the left and right ends of the plurality of rails 120, 120,... A ventilation cover 230 extending in the direction is attached. The ventilation cover 230 is made of resin or metal and has a mesh shape, and air permeability is ensured.

  As shown in FIGS. 8 and 9, the duct space D is provided with a freshness maintaining device 201 extending in the front-rear direction. The freshness holding device 201 includes a holder 204 inserted into the duct space D, a photocatalyst surface layer 202 formed on the surface of a cotton body 220 (fiber assembly) attached to the left inner surface of the holder 204, and the photocatalyst surface layer 202. The light source 203 is attached to the right inner surface of the holder 204 so as to be opposed to each other, thereby forming a unit. The cotton body 220 is preferably made of a metal fiber, a resin fiber, a vegetable fiber or the like in a cotton shape and has air permeability.

  As shown in FIGS. 8 and 9, the holder 204 is made of resin or metal and has a substantially C-shaped cross section that opens upward, and a plate-like portion of the rail 120 adjacent to the inside of the holder 204. It communicates with a gap G formed between 120b. FIG. 9 shows a state in which one holder 204 is partially pulled out.

  The photocatalyst surface layer 202 is formed as a Tiosky Coat (registered trademark) layer coated on the surface of a fiber made of an aluminum alloy or stainless steel cotton body 220 extending in the longitudinal direction of the holder 204. Yes. Although not shown, the structure of the cotton body 220 coated with the photocatalyst surface layer 202 is substantially the same as the structure of the nonwoven fabric 20 coated with the photocatalyst surface layer 2 shown in FIG.

  The light source 203 is an LED seal that extends in the longitudinal direction of the holder 204 and emits ultraviolet UV. The irradiation range of the ultraviolet UV by the light source 203 is at least that of the cotton body 220 in which the photocatalyst surface layer 202 is formed. It extends in the longitudinal direction and is set inside the holder 204, in other words, in the duct space D.

  According to this, by providing the cotton body 220 and the light source 203 on the surface of which the photocatalyst surface layer 202 unitized by the holder 204 is provided in the duct space D formed in the bottom portion 106 of the container 200, the plate of the rail 120 is provided. The cotton body 220 and the light source 203 on which the photocatalyst surface layer 202 is formed are protected from the contents C placed on the upper surface of the shaped portion 120b to prevent breakage, and air circulation in the bottom portion 106 of the container 200 However, ethylene gas can be reliably adsorbed or decomposed by the photocatalyst surface layer 202 without being affected by the arrangement of the contents C.

  Further, as shown in FIG. 8, the air on the lower side around the accommodation C moves downward between the accommodations C arranged on the front, rear, left and right, and the plate-like portion of the adjacent rail 120 The air is drawn from a gap G (see FIG. 9) formed between 120b and extending in the front-rear direction, and merges with the flow of air moving along the duct space D (inside the holder 204).

  As described above, the ceiling portion 104 and the side portions 105 and 105 are provided by the freshness maintaining device 1 (the nonwoven fabric 20 and the light source 3 on which the photocatalytic surface layer 2 is formed) provided on the ceiling portion 104 and the side portions 105 and 105 of the container 200. In addition to adsorbing or decomposing ethylene gas with respect to the circulating flow of air moving along the air, a freshness maintaining device 201 (photocatalyst surface layer 202 is formed on the surface) provided in the duct space D formed in the bottom 106 of the container 200. The cotton body 220, the light source 203 and the holder 204) can adsorb or decompose ethylene gas to the circulating flow of air moving along the duct space D (inside the holder 204). The ethylene gas is adsorbed or decomposed more efficiently by using the circulating air flow to reduce the ethylene gas concentration. It is possible.

  Moreover, the photocatalyst surface layer 202 can increase the surface area of the photocatalyst surface layer 202 to be coated by using a cotton body 220 that is a fiber assembly as a base material, and is excited by ultraviolet rays UV irradiated from the light source 203. Since the cotton body 220 has air permeability while enhancing the ability of the photocatalyst surface layer 202 to decompose ethylene gas while making the photocatalyst surface layer 202 easier to adsorb, the circulating flow of air flowing through the duct space D (inside the holder 204) Therefore, the air circulation flow in the accommodation space S can be suitably maintained.

  Further, as shown in FIG. 9, the freshness maintaining device 201 provided in the duct space D is formed by unitizing a cotton body 220 having a photocatalyst surface layer 202 formed on the surface by a holder 204 and a light source 203. Since the holder 204 is moved as indicated by the white arrow 9 and the freshness holding device 201 can be easily installed and removed from the duct space D, workability and maintainability can be improved. In addition, the freshness holding | maintenance apparatus 201 may be divided | segmented into plurality in the front-back direction.

  Further, the ventilation cover 230 is attached to both front and rear end portions of the plurality of rails 120, 120,..., So that the circulation flow of air flowing through the duct space D (inside the holder 204) through the ventilation cover 230 is suitably maintained. Extraction of the freshness holding device 201 from both front and rear ends of 120 can be prevented.

  Although the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments, and modifications and additions within the scope of the present invention are included in the present invention. It is.

  For example, in the above-described embodiment, the containers 100 and 200 in which the freshness maintaining devices 1 and 201 are provided are air along the longitudinal direction of the accommodation space S by blowing air from the unit cooler 110 along the ceiling 104. However, the present invention is not limited to this, and the air circulation method in the accommodation space S of the containers 100 and 200 can circulate the air in the accommodation space S evenly. May be freely configured, for example, by providing a blower outlet at the lower end portion of the opposed end portion 103 of the container 100, 200 and blowing out air along the bottom portion 106, thereby along the longitudinal direction of the accommodation space S. It is also possible to use a bottom flow system that circulates air. Further, the air may be circulated along the short direction of the accommodation space S like a cool tech container.

  Moreover, in the said Example 1, the freshness holding | maintenance apparatus 1 (The nonwoven fabric 20 and the light source 3 in which the photocatalyst surface layer 2 was formed on the surface) is provided with respect to the ceiling part 104 and the side parts 105 and 105 of the container 100, and the said Example 2, the freshness maintaining device 1 (nonwoven fabric 20 having the photocatalyst surface layer 2 formed on the surface and the light source 3) is provided on the ceiling portion 104 and the side portions 105, 105 of the container 200, and the bottom portion 106 (duct space D). On the other hand, although the aspect in which the freshness holding device 201 (the cotton body 220 on which the photocatalyst surface layer 202 is formed, the light source 203, and the holder 204) is provided has been described, the freshness holding device follows the circulation of air in the container accommodation space. As long as it is provided on any one of the door, the opposite end, the ceiling, the side, and the bottom. Note that the storage container provided with the freshness holding device may be a container or a warehouse that does not have a plurality of rails extending in the longitudinal direction at the bottom.

  Moreover, the photocatalyst surface layer 2 may use the top surface material 104a of the ceiling portion 104 of the containers 100 and 200 or the side surface materials 105a and 105a of the side portions 105 and 105 as a base material. Further, the photocatalyst surface layer 202 may have the bottom surface material 106a of the bottom portion 106 of the container 200 or the lower surface side of the base portion 120a and the plate-like portion 120b of the rail 120 as a base material.

  The freshness holding device 201 may not be provided with the holder 204 and may be unitized by covering the periphery of the light source 203 with a cotton body 220 on which the photocatalytic surface layer 202 is formed.

  In addition, the storage space of the container is not limited to fruits and vegetables, flowers, and other fresh foods, but stores, for example, pharmaceuticals, clothing, sundries, etc. as containments using the high deodorizing and antibacterial properties of the photocatalyst surface layer. May be.

1,201 Freshness maintaining device 2,202 Photocatalyst surface layer 3,203 Light source 20 Non-woven fabric (fiber assembly)
30 Reflector 100, 200 Container (storage container)
DESCRIPTION OF SYMBOLS 101 Opening part 102 Door 103 Opposite edge part 104 Ceiling part 104a Top surface material 105 Side part 105a Side surface material 106 Bottom part 106a Bottom material 110 Unit cooler 120 Rail 120a Base part 120b Plate-like part 120c Through-hole 204 Holder 220 Cotton body (fiber assembly) )
230 Ventilation cover C Containment D Duct space G Clearance S Accommodation space UV

Claims (7)

A freshness holding device that is provided in a storage container in which a circulating flow of air that flows along the ceiling, sides, and bottom is formed, and holds the freshness of the contents,
A photocatalyst surface layer provided on at least one of the ceiling part, the side part, and the bottom part along an air circulation flow in the storage container, and a light source that irradiates light to the photocatalyst surface layer. Freshness holding device.   The freshness holding device according to claim 1, wherein the photocatalyst surface layer is provided along a longitudinal direction of at least one of the ceiling portion, the side portion, and the bottom portion of the storage container.   The freshness holding device according to claim 1 or 2, wherein the photocatalyst surface layer is provided on the ceiling and the bottom of the storage container.   The freshness holding device according to any one of claims 1 to 3, wherein the photocatalyst surface layer is formed by coating a substrate of a fiber assembly.   The freshness holding device according to any one of claims 1 to 4, wherein the light source is provided in the vicinity of a corner formed by the ceiling portion and the side portion of the storage container.   The freshness holding device according to any one of claims 1 to 5, wherein the bottom portion includes a plurality of rails extending in a longitudinal direction, and the photocatalyst surface layer and the light source are provided between the plurality of rails.   The freshness holding device according to claim 6, wherein the photocatalyst surface layer provided between the plurality of rails is unitized with the light source.

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