KR102576936B1 - Apparatus for maintaining the freshness of agricultural products in truck storage apparatus - Google Patents

Abstract

The present invention relates to a device for maintaining the freshness of agricultural products stored in a truck storage warehouse, which is installed in the storage warehouse of a truck to maintain the freshness of agricultural products stored in the storage warehouse of a truck, comprising: a plasma module that generates plasma to decompose ethylene gas; It is installed in a storage warehouse of a truck, and the plasma module is installed therein. A first air flow path that introduces air in the storage warehouse through an inlet and decomposes ethylene gas in the introduced air by the plasma module. , a housing having a second air flow path that allows the introduced air to bypass the plasma module and an outlet through which the air that has passed through the first air flow path and the second air flow path joins and is discharged. and an ozone filter disposed downstream of the plasma module in the first air flow path and removing ozone gas generated by the plasma module, wherein air discharged to the outlet through the second air flow path is Provided is a device for maintaining the freshness of agricultural products in a storage warehouse for trucks, which reduces the ozone concentration of the air discharged from the outlet by combining with the air discharged from the outlet through the ozone filter.
Therefore, in order to remove ethylene gas, which reduces the freshness of agricultural products, the ozone gas generated by the plasma module installed in the first air flow path and the air heading to the outlet through the second air flow path that bypasses the plasma module are By joining, there is an advantage in preventing the ozone concentration from increasing locally at the outlet.

Description

Apparatus for maintaining the freshness of agricultural products in truck storage apparatus}

The present invention relates to a device for maintaining the freshness of agricultural products in a truck storage warehouse, and more specifically, to ozone gas generated by a plasma module installed in the first air flow path to remove ethylene gas, which reduces the freshness of agricultural products, and This relates to a device for maintaining the freshness of agricultural products in a truck storage warehouse that lowers the concentration of ozone in the air by combining air heading to the outlet through a second air flow path that bypasses the plasma module and being discharged to the outlet.

Among agricultural products, fruits (apples, kiwi, etc.), fruit and vegetables (tomatoes, strawberries, etc.), leafy vegetables (broccoli, lettuce, etc.), and flowers (roses, carnations, etc.) that produce a lot of ethylene age quickly due to spontaneous ethylene production after harvest. . When such agricultural products are stored in a warehouse, ethylene generated from the stored agricultural products accumulates in the storage. In particular, the accumulation of ethylene progresses more rapidly in places where space is limited, such as truck storage warehouses. Ethylene acts as a hormone that ripens agricultural products and accelerates the aging of agricultural products and reduces their quality. Therefore, it is desirable to decompose and remove ethylene in storage as much as possible.

In this regard, conventional ethylene decomposition machines for removing ethylene in agricultural storage decompose ethylene by irradiating ultraviolet rays or through plasma treatment. However, since this conventional ethylene decomposition machine is not equipped with a means to remove ozone (O3) generated during ethylene decomposition, there is a problem in that ozone exists in the storage, causing discoloration and quality deterioration of stored agricultural products.

Republic of Korea Patent No. 10-2188049

In order to remove ethylene gas, which reduces the freshness of agricultural products, the present invention provides ozone gas generated by a plasma module installed in the first air flow path and the ozone gas directed to the outlet through the second air flow path that bypasses the plasma module. The purpose is to provide a device for maintaining the freshness of agricultural products in a storage warehouse for trucks, which reduces the ozone concentration in the air by allowing air to merge and be discharged through an outlet.

According to one aspect of the present invention, the present invention is a device for maintaining the freshness of agricultural products stored in a truck storage warehouse, which is installed in the storage warehouse of a truck to maintain the freshness of agricultural products stored in the storage warehouse of a truck, by generating plasma and producing ethylene. A plasma module for decomposing gas is installed in the storage warehouse of the truck, the plasma module is installed inside, the air in the storage warehouse is introduced through the inlet, and ethylene gas is decomposed in the introduced air by the plasma module. A first air flow path that allows the introduced air to bypass the plasma module and pass through the plasma module, and the air that has passed through the first air flow path and the second air flow path join to A housing having an outlet for discharge and an ozone filter disposed downstream of the plasma module in the first air flow path and removing ozone gas generated by the plasma module, and the second air flow path. Provided is a device for maintaining the freshness of agricultural products in a storage warehouse for trucks, in which the air discharged through the outlet passes through the ozone filter and joins the air discharged through the outlet, thereby lowering the ozone concentration of the air discharged from the outlet.

The device for maintaining the freshness of agricultural products in a truck storage warehouse according to the present invention has the following effects.

First, in order to remove ethylene gas, which reduces the freshness of agricultural products, ozone gas generated by the plasma module installed in the first air flow path and air heading to the outlet through the second air flow path that bypasses the plasma module By joining, there is an advantage in preventing the ozone concentration from increasing locally at the outlet.

Second, since the ozone concentration heading from the first air flow path to the outlet is reduced by the air in the second air flow path, there is an advantage in that the ozone filter installed to reduce the ozone concentration can be reduced.

Third, there is an advantage of being able to control the amount of ozone heading to the outlet through the first air flow path by controlling the amount of air heading to the outlet through the second air flow path.

Fourth, there is an advantage in that the ozone concentration reduction effect can be improved by installing a reaction member in the first air flow path to allow the ozone generated in the plasma module to react well with the ethylene gas flowing in from the second air flow path.

Figure 1 is a schematic diagram showing a device for maintaining the freshness of agricultural products in a storage warehouse for trucks according to an embodiment of the present invention installed in the storage warehouse for trucks.
Figure 2 is a schematic diagram showing the operation of the agricultural product freshness maintenance device in the truck storage warehouse according to Figure 1.
Figure 3 is a schematic diagram showing a gas flow guide member of the agricultural product freshness maintenance device in the truck storage warehouse according to Figure 1.
Figure 4 is an enlarged schematic diagram showing an example of a reaction member included in the apparatus for maintaining the freshness of agricultural products in the truck storage warehouse according to Figure 1.
Figure 5 is a schematic diagram showing an exploded view of a reaction member included in the agricultural product freshness maintenance device of the truck storage warehouse according to Figure 4.
Figure 6 is a plan view of a reaction member included in the apparatus for maintaining the freshness of agricultural products in the truck storage warehouse according to Figure 4.
FIG. 7 is a cross-sectional view taken along line AA of a reaction member included in the agricultural product freshness maintenance device of the truck storage warehouse according to FIG. 6.
Figure 8 is a schematic diagram showing an enlarged portion B of the reaction member included in the agricultural product freshness maintenance device of the truck storage warehouse according to Figure 7.
FIG. 9 is an enlarged schematic diagram showing another example of a reaction member included in the agricultural product freshness maintenance device of the truck storage warehouse according to FIG. 1.
Figure 10 is an enlarged schematic diagram showing a gas flow guide member included in a device for maintaining the freshness of agricultural products in a storage warehouse for trucks according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail by explaining preferred embodiments of the present invention with reference to the attached drawings.

1 to 9, the apparatus 1000 for maintaining the freshness of agricultural products in a truck storage warehouse according to an embodiment of the present invention includes a housing 1100, an intake device 1200, a plasma module 1300, and a reaction member ( 1400), an ozone filter 1500, a control device 1600, an ozone concentration sensor 1700, and a power supply device 1800. For example, one housing 1100 is installed inside the storage warehouse, but a plurality of housings 1100 may be installed. At this time, the housings 1100 are arranged to be spaced apart from each other. In this embodiment, the housing 1100 is installed at the top of the storage warehouse, but the installation location of the housing 1100 can be changed. And, as an example, two reaction members 1400 are disposed inside the housing 1100.

The agricultural product freshness maintenance device 1000 of the truck storage warehouse prevents accelerated aging of agricultural products by decomposing ethylene (C ₂ H ₄ ) gas generated when agricultural products are stored in the truck storage warehouse, and decomposes the ethylene gas. It is installed to sterilize bacteria and mold present on the surface of the agricultural products with ozone (O ₃ ) generated when doing so. In particular, the apparatus 1000 for maintaining the freshness of agricultural products in a storage warehouse for trucks according to this embodiment adjusts the concentration of ozone by mixing the air passing through different air flow paths formed inside the housing 1100, and then stores it. There is an advantage in discharging it to the warehouse.

The housing 1100 includes an inlet 1110, an outlet 1120, a first air flow path 1130, a second air flow path 1140, a second air flow path opening and closing device 1150, and a flow guide member 1160. ) includes. And the housing 1100 has a storage space inside which the plasma module 1300, the reaction member 1400, and the ozone filter 1500 can be placed. The inlet 1110 is a part having an opening on one side of the housing 1100 to allow air inside the storage warehouse to flow in, and the outlet 1120 discharges the inflowed air back into the storage warehouse. It is a part that has an open structure on the other side of the housing 1100 so that it can be opened.

In this embodiment, the inlet 1110 and the outlet 1120 are formed at positions facing each other. And in this embodiment, the inlet 1110 includes a first inlet 1111, a second inlet 1112, and a third inlet 1113. The first inlet 1111, the second inlet 1112, and the third inlet 1113 are formed to be spaced apart from one side of the housing 1100. In this embodiment, the outlet 1120 has a single open structure, but like the inlet 1110, a plurality of outlet 1120 may be formed to be spaced apart. And the outlet 1120 may be formed in a structure that can be opened and closed.

The first air flow path 1130 is formed on a path connecting the inlet 1110 and the outlet 1120, and is formed in the center of the housing 1100. The second air flow path 1140 is formed at both edges of the housing 1100 around the first air flow path 1130 so as to bypass the components disposed in the first air flow path 1130. Therefore, two are formed. However, the present invention is not limited to this, and only one or three or more second air flow paths 1140 may be formed.

And in order to allow only a small amount of air introduced through the inlet 1110 to flow through the second air flow path 1140, the second air flow path 1140 is connected to the first air flow path 1130. It is formed narrowly compared to . Specifically, 10 to 30% of the air flowing into the housing 1100 flows through the second air flow path 1140, and the air flows through the first air flow path 1130 into the housing ( 1100) The first air flow path 1130 and the second air flow path 1140 are formed so that 70 to 90% of the air introduced inside flows.

In this embodiment, the housing 1100 is arranged in the first air flow path 1130 with the plasma module 1300, the reaction member 1400, and the ozone filter 1500 sequentially spaced apart. The paths of the first air flow path 1130 and the second air flow path 1140 are separated (branched) from each other. However, the first air flow path 1130 and the second air flow path 1140 include a first communication part 1141, a second communication part 1142, a third communication part 1143, and It includes a fourth communication unit 1144. However, the present invention is not limited to this, and the number of portions where the first air flow path 1130 and the second air flow path 1140 communicate can be changed as many times as desired.

The first communication part 1141 allows some of the air introduced through the inlet 1110 to flow into the first air flow path 1130, and the other part to flow into the second air flow path 1140. The first air flow path 1130 and the second air flow path 1140 are formed at a location adjacent to the inlet 1110 to communicate with each other.

And the second communication part 1142 is formed to communicate with the space where the two reaction members 1400 are spaced apart from each other and the second air flow path 1140. Specifically, the second communication unit 1142 allows air flowing along the second air flow path 1140 to flow into the reaction member 1400 disposed in the first air flow path 1130. . That is, the second communication part 1142 is a portion of the first air flow path 1130 where the reaction member 1400 is disposed and a second air flow path adjacent to the portion where the reaction member 1400 is disposed. (1140) The portion is formed to communicate.

In addition, the third communication part 1143 is formed so that the second air flow path 1140 communicates with the space where the reaction member 1400 and the ozone filter 1500 are spaced apart. Specifically, the third communication part 1143 allows air flowing along the second air flow path 1140 to flow into the ozone filter 1500 disposed in the first air flow path 1130. . That is, the third communication part 1143 is a portion of the first air flow path 1130 where the ozone filter 1500 is disposed and a second air flow path adjacent to the portion where the ozone filter 1500 is disposed. (1140) The portion is formed to communicate.

And the fourth communication part 1144 is formed to communicate with the space between the ozone filter 1500 and the outlet 1120 and the second air flow path 1140. Specifically, the fourth communication unit 1144 allows air flowing along the second air flow path 1140 to flow into the air that has passed through the ozone filter 1500. That is, the fourth communication part 1144 is a portion of the first air flow path 1130 where the air that has passed through the ozone filter 1500 is disposed and a portion where the air that has passed through the ozone filter 1500 is disposed. and the adjacent second air flow path portion is formed to communicate. In this embodiment, the first communication part 1141 to the fourth communication part 1144 are formed sequentially.

In Figure 2, the air flowing through the second air flow path 1140 is the second air flow on the left among the second air flow paths 1140 formed on both sides of the first air flow path 1130. It is shown that the furnace 1140 and the first air flow path 1130 move through the second communication part 1142, the third communication part 1143, and the fourth communication part 1144, which are in communication with the furnace 1140 and the first air flow path 1130. It is for convenience. Therefore, air can flow in the direction of the first air flow path 1130 even through the portion where the second air flow path 1140 and the first air flow path 1130 on the right are connected.

And the second air flow path opening and closing device 1150 is installed in the first communication part 1141. In this embodiment, the second air flow path opening and closing device 1150 is installed in the first communication part 1141 as an example, but the present invention is not limited to this and the second air flow path opening and closing device 1150 may not be installed. The second air flow path opening and closing device 1150 is configured to control the amount of air introduced through the inlet 1110 into the second air flow path 1140 of the first communication unit 1141. It plays a role in controlling opening and closing. That is, the amount of air flowing through the second air flow path 1140 changes depending on the degree of opening and closing of the second air flow path opening and closing device 1150. In the drawing, the second air flow path opening and closing device 1150 is shown to be installed only in the first communication part 1141 and the third communication part 1143. However, this is for convenience of illustration, and the second air flow path opening and closing device 1150 is shown in the drawing. The opening and closing device 1150 is also installed in the second communication part 1142 and the fourth communication part 1144, respectively. Of course, the second air flow path opening and closing device 1150 may not be installed.

The flow guide member 1160 is installed in the fourth communication part 1144. One side of the flow guide member 1160 is in communication with the second air flow path 1140, and air that has passed through the ozone filter 1500 is disposed from the portion in communication with the second air flow path 1140. It extends to the center of the first air flow passage 1130. The other side of the flow guide member 1160 is open so that air moving through the second air flow path 1140 is discharged into the space between the ozone filter 1500 and the outlet 1120. Therefore, the air discharged from the flow guide member 1160 reacts by mixing with the air that passed through the ozone filter 1500. Therefore, the ethylene gas contained in the air discharged from the flow guide member 1160 joins the air (ozone) contained in the air that passed through the ozone filter 1500, thereby reducing the amount of ozone discharged from the outlet 1120. Adjust the amount.

The intake device 1200 is installed to introduce air in the storage warehouse into the housing 1100. In this embodiment, the intake device 1200 is a fan, but the type of the intake device 1200 can be changed. In this embodiment, the fan 1200 includes a first fan 1210 installed in the first inlet 1111, a second fan 1220 installed in the second inlet 1112, and a third inlet 1113. ) includes a third fan (1230) installed in the fan. The fan 1200 receives power from the power supply device 1800, and its operation is controlled by the control device 1600.

The plasma module 1300 decomposes ethylene (C ₂ H ₄ ) gas in the air introduced into the housing 1100 using plasma. In this embodiment, the plasma module 1300 is disposed adjacent to and spaced apart from the intake device 1200 in the direction of the outlet 1120 in the first air flow path 1130. And ozone is generated by the operation of the plasma module 1300. The ozone can be used as a substance for sterilizing the agricultural products. The plasma module 1300 may be formed in various structures capable of decomposing ethylene gas contained in air introduced into the housing 1100 through the inlet 1110.

The reaction member 1400 is disposed between the plasma module 1300 and the ozone filter 1500 in the direction from the first air flow path 1130 to the outlet 1120. The reaction member 1400 generates a vortex in the air between the ozone filter 1500 and the plasma module 1300 to react the ethylene gas in the first air flow path 1130 with ozone, thereby efficiently producing ozone gas. Installed for removal. Specifically, the reaction member 1400 branches off the ozone gas flowing into the first air flow path 1130 and the ozone gas generated by the plasma module 1300 and the second air flow path 1140. Ozone gas is removed by reacting ethylene gas in the air flowing in through the second communication unit 1142.

4 to 8, the drawing shows that two reaction members 1400 are disposed between the plasma module 1300 and the ozone filter 1500, but the present invention is not limited thereto and the reaction The number of members 1400 can be changed. 4 to 8 are diagrams of one embodiment of the reaction member 1400. Referring to FIGS. 4 to 8 , the reaction member 1400 includes a first plate 1410, a second plate 1420 disposed to face and spaced apart from the first plate 1410, and the first plate 1410. and a plurality of ball members 1430 disposed between the first plate 1410 and the second plate 1420, and a partition member 1440 disposed between the first plate 1410 and the second plate 1420. However, the present invention is not limited to this, and the partition member 170 may not be disposed.

In addition, in this embodiment, the ball member 1430 is disposed between the first plate 1410 and the second plate 1420 having a plate structure as an example, but referring to FIG. 9, the present invention provides the ball member 1430 The member 1430 may be disposed between the first mesh network 1410′ and the second mesh network 1420′. That is, the ball member 1430 may be surrounded by a mesh network structure rather than a plate structure. In this way, when the first mesh net 1410' and the second mesh net 1420' are disposed on the upper and lower parts of the ball member 1430, the first mesh net 1410' and the second mesh net (1410') 1420`) has a structure on which the ball member 1430 can be seated, so it is a separate first seat on the first plate 1410 and the second plate 1420 as shown in FIGS. 4 to 8. There is an advantage that there is no need to form the hole 1411 and the second seating hole 1421.

First seating holes 1421 in which each of the plurality of ball members 1430 is seated are formed in the first plate 1410. A plurality of first seating holes 1421 are positioned to be substantially uniformly distributed on the first plate 1410. The first seating hole 1421 has a size and shape in which the ball member 1430 can be seated. One side of the ball member 1430 is placed on the first seating hole 1421, and one side of the ball member 1430 protrudes through the first seating hole 1421. In this embodiment, as shown, it is described as protruding to one side of the first plate 1410 through the first seating hole 1421 on one side of the ball member 1430. However, unlike this, the thickness of the first plate 1410 or Depending on the size of the first seating hole 1421, the ball member 1430 may not protrude to one side of the first seating hole 1421. In this embodiment, the first seating hole 1421 is described as being a triangle including an equilateral triangle as shown.

And a ball member protrusion 1431 is formed on the surface of the ball member 1430. However, the present invention is not limited to this, and the ball member 1430 may have a smooth structure without protrusions 1431 formed on its surface. In FIGS. 7 and 8, the ball member protrusion 1431 is omitted for convenience of illustration. And in FIGS. 7 and 8, the bubble shape passing through the reaction member 1400 represents ethylene gas and ozone gas in the form of particles for visual convenience. The ball member protrusion 1431 serves to increase the contact time and area during which ethylene gas and ozone gas pass through the reaction member 1400 by increasing the surface area of the ball member 1430. However, the present invention is not limited to this, and it is possible to form a concave-convex structure or any other structure that can expand the surface area of the ball member 1430. That is, the apparatus 1000 for maintaining the visibility of agricultural products in a truck storage warehouse according to the present embodiment allows ozone gas and ethylene gas to proceed toward the outlet 1120 by the respective components included in the reaction member 1400. As the contact time and contact area increases, reaction efficiency improves.

The ozone filter 1500 is disposed between the reaction member 1400 and the outlet 1120 in the first air flow path 1130. That is, the ozone filter 1500 is disposed downstream of the plasma module 1300. The ozone filter 1500 serves to remove ozone gas generated by the plasma module 1300. In this embodiment, it is assumed that only one ozone filter 1500 is installed. If the ozone concentration in the first air flow passage 1140 is high, the ozone concentration can be reduced by installing a plurality of ozone filters 1500, but in this case, there is a problem that the cost increases and the volume of the device may increase. . However, in the case of the apparatus 1000 for maintaining the freshness of agricultural products in a truck storage warehouse according to the present embodiment, the amount of air flowing through the second air flow path 1140 or the amount of air flowing through the second air flow path 1140 Since the ozone concentration can be controlled by adjusting the amount of air flowing into the first air flow path 1130 through the communication part 1142 and the third communication part 1143, only one ozone filter 1500 is sufficient. It has the advantage of filtering ozone.

The control device 1600 is connected to the second air flow path opening and closing device 1150, the intake device 1200, the plasma module 1300, the ozone concentration sensor 1700, and the power supply device 1800, respectively. It is done. The control device 1600 automatically adjusts the degree of opening and closing of the second air flow path opening and closing device 1150 according to the ozone concentration in the first air flow path 1130 and the storage warehouse. The ozone concentration in the first air flow path 1130 can be determined by separately installing an ozone concentration sensor in the first air flow path 1130 or without air flowing into the second air flow path 1140. 1The ozone concentration discharged from the air flow path 1130 is calculated by measuring the ozone concentration sensor 1700. And the control device 1600 operates the plasma module 1300 when the ethylene concentration in the storage warehouse is higher than the set concentration. In this embodiment, the control device 1600 is installed adjacent to the driver's seat, but the control device 1600 may also be installed in the storage warehouse or the housing 1100.

The ozone concentration sensor 1700 is installed in the storage warehouse to measure the ozone concentration inside the storage warehouse. In this embodiment, the ozone concentration sensor 1700 is installed adjacent to the outlet 1120 of the housing 1100 to detect the ozone concentration of the air discharged from the outlet of the housing 1100. The control device 1600 stops operation of the plasma module when the ozone concentration received from the ozone concentration sensor 1700 is higher than the first set concentration. And the control device 1600 operates the plasma module when the ozone concentration received from the ozone concentration sensor 1700 is less than or equal to the second set concentration.

The power device 1800 supplies power to the second air flow path opening and closing device 1150, the intake device 1200, the control device 1600, and the ozone concentration sensor 1700. In this embodiment, the power device 1800 is an example of a truck battery. However, the present invention is not limited to this and the power device 1800 can be changed to a generator or another separate power source. Additionally, the power supply device 1800 may further include a converter that can change DC power to AC power or AC power to DC power.

Referring to FIG. 10, the apparatus 2000 for maintaining the freshness of agricultural products in a truck storage warehouse according to another embodiment of the present invention includes a housing 2100, an intake device (not shown), a plasma module (not shown), and a reaction member (not shown). ozone filter (not shown), an ozone filter (not shown), a control device (not shown), an ozone concentration sensor (not shown), and a power supply (not shown). Compared to the agricultural product freshness maintaining device 1000 in a truck storage warehouse according to FIGS. 1 to 9, the apparatus 2000 for maintaining the freshness of agricultural products in a truck storage warehouse according to this embodiment has a flow guide member 2160 of the housing 2100. ), but other configurations are similar. Therefore, hereinafter, the flow guide member 2160 will be described in detail, and detailed descriptions of the remaining components will be omitted.

The flow guide member 2160 has a hollow interior formed through which air can flow. And one side of the flow guide member 2160 is in communication with the second air flow path 2140, and the air that has passed through the ozone filter is disposed from the portion in communication with the second air flow path 2140. It extends to the first air flow path (2130). And the other side of the flow guide member 2160 is closed. In addition, the flow guide member 2160 has a plurality of discharge holes 2161 spaced apart from each other on the extended outer peripheral surface through which the air inside can be discharged to the outside. The apparatus 2000 for maintaining the freshness of agricultural products in a storage warehouse for trucks according to this embodiment is not discharged from the other side of the flow guide member 2160, but through the discharge holes 2161 that are formed to be evenly spaced from one side to the other side. Air flowing through the second air flow passage 2140 is discharged. Therefore, there is an advantage that air can be discharged uniformly throughout. However, the present invention is not limited to this, and the discharge hole 2161 is formed non-uniformly in consideration of the size or location of the discharge port (not shown) formed in the housing 2100, the location of the air discharged from the ozone filter, etc. You may.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely illustrative, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true scope of technical protection of the present invention should be determined by the technical spirit of the attached patent claims.

1000, 2000: Produce freshness maintenance device in truck storage warehouse
1100, 2100: Housing
1110: inlet
1111: First inlet
1112: Second inlet
1113: Third inlet
1120: outlet
1130, 2130: First air flow path
1140, 2140: Second air flow path
1141: First communication unit
1142: Second communication unit
1143: Third communication unit
1144: 4th communication unit
1150: Second air flow path opening and closing device
1160, 2160: Flow guide member
2161: discharge hole
1200: intake device
1300: Plasma module
1400: No response
1410: first plate
1411: first seating hole
1420: Second plate
1421: Second seating hole
1430: Ball member
1431: Ball member protrusion
1440: Bulkhead member
1500: Ozone filter
1600: Control device
1700: Ozone concentration sensor
1800: Power supply

Claims (16)

In the truck storage warehouse agricultural product freshness maintenance device installed in the truck storage warehouse to maintain the freshness of agricultural products stored in the truck storage warehouse,
A plasma module that generates plasma to decompose ethylene gas;
A first air flow path that is installed in the storage warehouse of the truck, has the plasma module installed therein, and introduces air in the storage warehouse through an inlet to decompose ethylene gas in the introduced air by the plasma module. and a second air flow path that allows the introduced air to bypass the plasma module and an outlet through which the air that has passed through the first air flow path and the second air flow path joins and is discharged. housing; and
An ozone filter disposed downstream of the plasma module in the first air flow path and removing ozone gas generated by the plasma module,
The air discharged to the outlet through the second air flow path joins the air discharged to the outlet through the ozone filter to lower the ozone concentration of the air discharged from the outlet,
The first air flow path is,
It is formed on a path connecting the inlet and the outlet, and is formed in the center of the housing,
The second air flow path is,
A plurality of units are formed along both edges of the housing centered on the first air flow path,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 1,
It is disposed between the ozone filter and the plasma module in the first air flow path, and is branched from the ozone gas flowing into the first air flow path and the ozone gas generated by the plasma module in the second air flow path. Further comprising a reaction member that generates a vortex in the air between the ozone filter and the plasma module to remove the ozone gas by reacting ethylene gas in the incoming air,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 1,
The housing is,
It further includes a fan installed at the inlet to introduce air in the storage warehouse into the housing,
Further comprising a control device for controlling operation of the fan,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 3,
The housing is,
The first air flow path and the second air flow path are branched so that the air introduced through the inlet can flow into the first air flow path or the second air flow path, and the first air flow path is and a first communication part is formed to communicate with the second air flow path,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 4,
In order to allow only a small amount of air introduced through the inlet to flow through the second air flow path, the second air flow path is formed to be narrower than the first air flow path,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 4,
The housing is,
An opening and closing device capable of adjusting the opening and closing of the first communication unit is installed in the first communication unit to control the amount of air introduced through the inlet into the second air flow path,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 6,
The control device is,
Automatically adjusting the degree of opening and closing of the opening and closing device according to the ozone concentration in the first air flow path and the storage warehouse,
A device that maintains the freshness of agricultural products in a truck storage warehouse. delete In claim 1,
The housing is,
In order to allow the air flowing along the second air flow path to flow into the reaction member disposed in the first air flow path, the first air flow path portion where the reaction member is disposed and the reaction member are A second communication part is formed so that the disposed part and the adjacent second air flow path part communicate,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 1,
The housing is,
In order to allow the air flowing along the second air flow path to flow into the ozone filter disposed in the first air flow path, the first air flow path portion where the ozone filter is disposed and the ozone filter are A third communication part is formed so that the disposed part and the adjacent second air flow path part communicate,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 1,
The housing is,
In order to allow the air flowing along the second air flow path to flow into the air that has passed through the ozone filter, the air that has passed through the ozone filter passes through the first air flow path portion and the ozone filter. A fourth communication part is formed so that the part where one air is disposed and the adjacent second air flow path part communicate,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 11,
It is installed in the fourth communication part, has a hollow inside through which air can flow, one side is in communication with the second air flow path, and the ozone filter is supplied from the part in communication with the second air flow path. Further comprising a flow guide member that extends to the center of the first air flow path portion where the passing air is disposed, and the other side is open,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 11,
It is installed in the fourth communication part, has a hollow inside through which air can flow, one side is in communication with the second air flow path, and the ozone filter is supplied from the part in communication with the second air flow path. It extends to the part of the first air flow path where the passing air is disposed, and the other side is closed, and a plurality of spaced apart discharge holes through which the internal air can be discharged to the outside are formed on the outer peripheral surface of the extended part. Including a flow guide member that is
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 2,
The plasma module, the reaction member, and the ozone filter,
Arranged sequentially on a path from the inlet to the outlet,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 3,
Installed in the storage warehouse, connected to the control device, and further comprising an ozone concentration sensor for measuring the ozone concentration inside the storage warehouse,
The ozone concentration sensor is,
Installed adjacent to the outlet of the housing to detect the ozone concentration of the air discharged from the outlet of the housing,
A device that maintains the freshness of agricultural products in a truck storage warehouse. In claim 15,
The control device is,
If the ozone concentration of the storage warehouse received from the ozone concentration sensor is higher than the first set concentration, the operation of the plasma module is stopped, and if the ozone concentration of the storage warehouse received from the ozone concentration sensor is lower than the second set concentration, the operating the plasma module,
A device that maintains the freshness of agricultural products in a truck storage warehouse.

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