KR102053453B1 - Air conditioning system for low temperature storage house - Google Patents

Abstract

The present invention relates to an air conditioning system for a cold storage, and the configuration of the present invention is installed so as to communicate with the inside and outside of the cold storage to discharge the internal air to the outside, the discharge damper to control the flow of the discharged air Exhaust duct provided; An intake duct having a heat exchanger with the discharge duct and installed so that outside air is sucked into the cold storage, and having a suction damper to control the flow of the sucked air; An air conditioner connected to the discharge duct and the suction duct to adjust the temperature of the air to a preset temperature range according to a signal input from a temperature sensor provided in a cold storage; An inlet duct installed in connection with the air conditioner to allow the temperature controlled air to flow into the cold storage; And when the temperature of the inside of the low temperature reservoir is input from the temperature sensor to a temperature within a predetermined temperature range, to discharge the air inside the low temperature reservoir and to inhale the outside air, or to control the air conditioner by circulating the air in the low temperature reservoir. And a controller programmed to heat or cool the air sucked from the outside or circulated therein.

Description

AIR CONDITIONING SYSTEM FOR LOW TEMPERATURE STORAGE HOUSE

The present invention relates to an air conditioning system for a cold storage. Specifically, in the formation of a cold storage for storing various agricultural products or fresh foods, the internal air is discharged, the external air is introduced, or the internal air is circulated. In addition to maintaining the proper temperature of the storage space and reducing the temperature deviation through heat exchange between the inside and outside air to maintain the freshness of fresh produce or fresh food, metabolites such as ethylene gas discharged from the produce are stored outside the cold store. The present invention relates to an air conditioning system for a cold storage to prevent deterioration due to oxidation, decay or browning of stored agricultural products.

In recent years, as urbanization and income increase due to industrial development and population increase, and the consumption of fresh fruits and vegetables is increasing, the produced agricultural products are kept fresh and supplied to consumers during the non-production period. By doing so, it satisfies the needs of consumers, which can contribute to the price stability of agricultural products.

For example, as a method for storing freshly harvested produce, cold storage is a method of inducing extension of freshness by storing food or produce at a lower temperature than outside temperature. A cold storage warehouse equipped with a facility is called a cold storage, and is typically installed as a warehouse having a ceiling portion and a side portion having a cooler therein.

Here, the cooler is provided with a cold air outlet for discharging cold air, and a suction fan for suctioning the air circulated inside the cold reservoir again, thereby injecting cold air through the cold air outlet into the cold reservoir containing the agricultural products. In addition, the cold air to control the humidity and temperature of the produce, in this process the temperature is raised to the upper air is sucked back into the suction fan.

However, the agricultural products stored in such low-temperature storages are metabolized during storage to release metabolites for life extension, such as carbon dioxide, ethylene gas, water, enzymes, aromatic substances, or hormones. The gas promotes oxidation and decay of the stored produce, and heat generated through the oxidation and decay of the stored produce or methane gas emitted from the oxidized and decayed produce further promotes the oxidation and decay of the stored produce. There was.

This low-temperature storage is intended to extend the marketability of seasonal agricultural products sensitive to temperature, and by storing them in an appropriate temperature range in consideration of the metabolism of various agricultural products to induce shipment control and quality loss to be minimized, thereby improving the added value of agricultural products. To do it.

Conventional cold storage for this purpose is to remove the above-described ethylene gas, methane gas or volatile gas, such as to make a hole in the bottom of the inner wall in the structure, or to provide an expensive ozone generator or to the cold storage sidewall Although a method of installing a fan has been used, such a method has a disadvantage in that it is not widely used due to extremely low economic and structural efficiency.

Republic of Korea Patent Publication No. 10-1296297 (August 14, 2013) Republic of Korea Patent Publication No. 10-2012-0087609 (2012.08.07. Publication)

The present invention has been made to solve the above-mentioned conventional problems, an object of the present invention is to detect the temperature of the inside and outside of the cold storage to automatically discharge the air inside and at the same time the outside air is introduced or By circulating the air in the tank, the air flowing into the cold store is controlled within the preset temperature range, and the temperature inside the cold store is kept within the proper temperature range, thereby preventing deterioration of quality including freshness of the stored agricultural products. To provide an air conditioning system for a cold storage.

In addition, another object of the present invention is to have a structure in which the discharged air and the sucked air in the process of the discharge of the air inside the cold storage and the suction of the outside air to form a heat exchange, thereby reducing the temperature deviation between the cold storage and the outside air stored agricultural products As well as maintaining freshness of fresh foods, as the temperature of the air sucked from the outside enters the air conditioner while it is already heated or cooled, the energy consumption of the air conditioner that heats or cools the intake air is reduced. It is possible to reduce the maintenance cost during the use of cold storage.

In addition, by detecting the temperature rise inside the cold storage caused by the discharge of metabolites such as ethylene gas, methane gas or volatile gas according to the metabolism of the stored agricultural products, the internal temperature of the cold storage is automatically adjusted through the above-described ventilation or air circulation process. It is another object of the present invention to maintain oxidation within a proper temperature range so as to suppress oxidation or decay of stored agricultural products.

Furthermore, the above-mentioned metabolites are discharged together when the air inside the cold store is discharged, and when the air is circulated inside the cold store, the sterilization treatment is performed to decompose the above-described harmful metabolites and discharge the outside of the cold store. It is another object of the present invention to more firmly block oxidation or decay of agricultural products.

Characteristic configuration of the cold storage air conditioning system according to the present invention for achieving the above object is installed to communicate with the inside and outside of the cold storage, to discharge the air inside to the outside, to control the flow of the discharged air A discharge duct having a discharge damper; An intake duct having a heat exchanger with the discharge duct and installed so that outside air is sucked into the cold storage, and having a suction damper to control the flow of the sucked air; An air conditioner connected to the discharge duct and the suction duct to adjust the temperature of the air to a preset temperature range according to a signal input from a temperature sensor provided in a cold storage; An inlet duct installed in connection with the air conditioner to allow the temperature controlled air to flow into the cold storage; And when the temperature of the inside of the low temperature reservoir is input from the temperature sensor to a temperature within a predetermined temperature range, to discharge the air inside the low temperature reservoir and to inhale the outside air, or to control the air conditioner by circulating the air in the low temperature reservoir. And a controller programmed to heat or cool the air sucked from the outside or circulated therein.

Here, the discharge duct has a discharge fan on the ceiling of the storage areas formed in the cold storage, the suction duct has suction fans on the inside, the inlet duct is provided with the inlet grating on the bottom of the storage areas Characterized in that made.

The discharge duct and the suction duct are each provided with a control valve for controlling a direction in which air flows at one end of which the air inside the cold storage is discharged to the outside or the outside air is sucked into the inside, and the control valve is It is characterized in that the connection with the control unit.

In this case, the discharge duct is composed of first and second ducts branched from the other side of the discharge damper to both sides, the control valve is provided on the side of the second duct bordering the first duct, the second duct is The opposite side of the control valve is characterized in that the connection to the air conditioner.

The controller may be configured to close the control valve in a state in which the discharge damper is opened so that the air in the cold reservoir is discharged when the temperature inside the cold reservoir detected by the temperature sensor is greater than or equal to a preset temperature range. When the temperature sensor is detected to be discharged to the outside through the outside, or the temperature of the outside of the cold storage input by the temperature sensor is also above the temperature range of the inside of the already set cold storage, the control valve is opened by closing the discharge damper to open the inside of the cold storage. Air is introduced into the air conditioner through the first and second ducts.

The suction duct may include first and second ducts branched to both sides of the control valve, and the first and second ducts may be connected to the air conditioners on opposite sides of the control valve. Characterized in forming.

Here, when the temperature inside the low temperature reservoir detected by the temperature sensor is greater than or equal to a preset temperature range, the controller opens the suction damper to allow the air outside the low temperature reservoir to be sucked into the inside, but the temperature of the low temperature reservoir is already set. Control the control valve according to the temperature difference with the range so that the air is sucked into the first duct or the second duct, or the temperature outside the cold storage input by the temperature sensor is also set within the cold storage The abnormality is characterized in that the suction damper is closed.

In addition, when the discharge damper and the suction damper is opened, the air flowing into the air conditioner is heated or cooled to flow into the inlet duct. It is characterized by flowing through the duct.

The discharge duct includes an optical plasma sterilization unit in the second duct, and the optical plasma sterilization unit is an optical plasma member that decomposes harmful bacteria or harmful gases in the air discharged from the inside of the cold storage inside the second duct. And, it is installed so as to communicate the outside of the optical plasma member and the low-temperature storage, characterized in that consisting of decomposition ducts to discharge harmful bacteria or harmful gases of air decomposed into the optical plasma member to the outside of the low-temperature storage.

On the other hand, it is characterized in that it comprises a heat exchanger installed in connection with the discharge duct and the suction duct, a plurality of plate-shaped insulating elements are provided so that the air inside and outside the cold storage flowing through the discharge duct and the suction duct to perform heat exchange. .

At this time, the air flowing through the discharge duct and the suction duct crosses the inside of the heat exchanger, and the air sucked from the outside of the cold storage is discharged from one side of the insulating element and the cold storage in which the heat is introduced into the heat exchanger. A primary filter is provided at the other side of the insulating element introduced into the heat exchanger, and a secondary filter is further provided between one side of the insulating element and the primary filter.

Further, the discharge duct is formed in a shape surrounding the suction duct at intervals, the suction duct is characterized in that the outer surface is provided with a gap holding member that is joined to the inner surface of the discharge duct.

According to the configuration of the present invention described above, in the process of storing a variety of agricultural products or fresh food in a plurality of storage area, the internal air is automatically discharged by sensing the temperature inside and outside the cold store through a temperature sensor and a control unit connected thereto. At the same time, the outside air flows in or the outside air is blocked, and the inside air is circulated, and the air flowing into the cold store through the air conditioner is controlled within the preset temperature range. By maintaining the temperature of within the appropriate temperature range, there is an effect that the degradation including the freshness of the stored agricultural products is prevented.

In addition, the air discharged from the heat exchanger and the air sucked in through the heat exchanger exchange heat during the discharge of the air inside the cold storage and the suction of the outside air, thereby reducing the temperature deviation between the inside and the outside of the cold storage, leading to the freshness of the stored produce or fresh food As well as being maintained, as the temperature of the air sucked from the outside enters the air conditioner while it is already heated or cooled, the energy consumption of the air conditioner that heats or cools the intake air can be reduced. In addition, maintenance costs can also be reduced.

In addition, by detecting the temperature rise inside the cold storage caused by the discharge of harmful metabolites such as ethylene gas, methane gas or volatile gas due to the metabolism of stored agricultural products, the internal temperature of the cold storage is automatically increased through the aforementioned ventilation or air circulation process. By maintaining the temperature within an appropriate temperature range, there is also an effect that can easily suppress the oxidation or decay of the stored agricultural products.

In addition, through the primary filter and the secondary filter provided in the heat exchanger to filter the air sucked from the outside of the cold storage can supply fresh air inside the cold storage, the above-mentioned harmful metabolites are discharged When the air is circulated in the cold storage, the circulating air is sterilized through the primary filter provided in the heat exchanger and the optical plasma sterilization unit provided in the exhaust duct to disinfect the above-mentioned harmful bacteria or harmful gases. By being discharged to the outside of the cold storage, there is also an effect that can more firmly block the oxidation or decay of the stored agricultural products.

1 and 2 are a cross-sectional view and a perspective view schematically showing a cold storage to explain the air conditioning system for a cold storage according to the present invention.
3 is a view schematically showing the heat exchange of the air flowing through the exhaust duct and the suction duct through the heat exchanger of the air conditioning system for cold storage according to the present invention.
4 to 6 are schematic cross-sectional views for explaining the flow of air in the cold storage air conditioning system from the configuration of FIG.
7 and 8 are cross-sectional views schematically showing an air conditioning system for a cold storage according to another embodiment of the present invention.

In the description of the present invention, the upper (ceiling) and the lower (bottom) are installed in the upper (ceiling) of the exhaust duct for discharging the air inside the cold storage and the suction duct for sucking the air outside the cold storage. In addition, the inlet duct which is sucked from the outside and the temperature controlled by the air conditioner is introduced into the cold storage will be described on the basis of the use state installed in the lower (bottom) of the cold storage.

In addition, in the description of the present invention, one side is the direction or the direction in which the air inside the cold storage is discharged to the outside or the suction of the outside air through the discharge damper and the suction damper based on the longitudinal center of the discharge duct and the suction duct This part will be referred to, and the other side will be described as referring to a part in the opposite direction or the direction of one side.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment for implementing the object of the present invention and the working relationship according to these configurations, detailed description of the technical configuration in the same or the same category as the prior art will be omitted Shall be.

The present invention in the formation of a low-temperature storage for the storage of various agricultural products or fresh food, by maintaining the appropriate temperature of the internal storage space through the discharge of the internal air, inflow of external air or circulation of the internal air and at the same time By reducing the temperature deviation through heat exchange of the outside air to maintain the freshness of the produce or fresh food, as well as metabolites such as ethylene gas discharged from the produce to the outside of the low-temperature storage room oxidation, decay or browning phenomenon The present invention relates to an air conditioning system for a cold storage to prevent the quality deterioration caused by the.

1 to 3, the configuration of the present invention, the discharge duct 10, the suction duct 20, the air conditioner 30, the inlet duct (installed inside the cold storage 1) 40) and heat exchanger 50, and control part C which controls them.

In the cold storage 1 of the low temperature storage air conditioning system according to an embodiment of the present invention, a plurality of storage areas (S) are provided inside, and detects the temperature of the inside and outside and transmits them to the control unit (C). The temperature sensor T is installed.

The cold storage 1 is divided into a plurality of storage areas (S) therein, according to the type of agricultural products or fresh foods stored, or by separating the various agricultural products or fresh foods in consideration of the harvest time or shipping time of the agricultural products You can keep it.

For example, the cold storage 1 described above may be provided with a door (not shown) to allow access to the internal storage space while being sealed by a packing (not shown) in a rectangular enclosure shape.

On the other hand, the upper portion (ceiling portion) of the cold reservoir 1 is installed along the circumferential direction while communicating with the inside and the outside of the cold reservoir 1 to discharge the air inside the cold reservoir 1 to the outside, and thus discharged. A discharge duct 10 having a discharge damper 11 is provided to control the flow of air.

The discharge duct 10 is a tubular shape having a length, the longitudinal cross-section of the discharge duct 10 may be made of a polygon, including a circular, oval or square, pentagon, discharge of the air inside the cold reservoir (1) through the discharge duct (10) Metabolites such as ethylene gas, methane gas, or volatile gas may be discharged together due to the metabolism of stored agricultural products, thereby preventing oxidation or decay of the stored agricultural products.

Here, the discharge damper 11 is installed on the side wall of the cold storage 1 to be opened and closed at one side of the discharge duct 10 so that the discharge duct 10 can communicate with the inside and outside of the cold storage 1. And, it is opened or closed by the control unit (C) to control the discharge of the air inside the cold storage 1, a conventional rotary damper or fire damper may be applied.

In addition, in the installation of the cold storage 1, the exhaust duct 10 is provided with a discharge fan 12 installed on the ceiling of the storage areas S so as to communicate with the interior of the cold storage 1. It is preferable to, and this is to facilitate the discharge of the air in the cold storage 1, the above-described discharge fan 12 is connected to the control unit (C).

In addition, the discharge duct 10 is a control valve 13 for controlling the direction in which air flows to the other side of the above-described discharge damper 11 at one end of the air inside the cold reservoir 1 discharges to the outside. The control valve 13 is connected to the control unit (C).

In addition, the discharge duct 10 is composed of first and second ducts (10a, 10b) branched from the other side of the discharge damper 11 to both sides, and is configured to extend along the upper portion (ceiling portion) of the cold storage (1) The control valve 13 described above is provided on the side of the second duct 10b which is bounded by the first duct 10a. In this case, the second duct 10b has the air conditioning described later on the side opposite to the control valve 13. Make connection with the machine (30).

In addition, the discharge duct 10 includes the optical plasma sterilization unit 14 in the above-described second duct 10b, which is installed inside the second duct 10b and has a low temperature. The optical plasma member 14a for decomposing harmful bacteria or harmful gases in the air discharged from the reservoir 1 and the optical plasma member 14a and the outside of the cold storage 1 are installed to communicate with the optical plasma member 14a. It consists of a decomposition duct (14b) for discharging harmful bacteria or harmful gas of the air decomposed to the outside of the cold storage (1).

At this time, the optical plasma member (14a) may be composed of a UV lamp coated with a semiconductor photocatalyst on the surface, such as, through the optical plasma sterilization unit 14, when circulating air in the cold storage (1) By disinfecting the circulating air, the above-mentioned harmful bacteria or harmful gases are decomposed and discharged to the outside of the low-temperature storage room 1, so that oxidation or decay of the stored agricultural products can be more firmly prevented, and the above-described decomposition duct 14b is A fan (not shown) may be provided inside to facilitate the discharge of decomposed harmful bacteria or harmful gases.

On the other hand, the upper portion (ceiling portion) of the low temperature reservoir 1 is installed along the circumferential direction while communicating with the inside and the outside of the low temperature reservoir 1 so that the air outside the low temperature reservoir 1 is sucked into the inside. A suction duct 20 having a suction damper 21 is provided to control the flow of the sucked air.

The suction duct 20, like the discharge duct 10 described above, has a tubular shape having a length, the longitudinal section may be formed of a polygon including a circular, elliptical or square, pentagon, heat exchanger 50 to be described later In order to be connected to the above-described discharge duct 10, the air inside the cold reservoir 1 discharged through the discharge duct 10 and the air sucked from the outside of the cold reservoir 1 form heat exchange.

Accordingly, the freshness of the stored agricultural products or fresh foods is maintained by reducing the temperature deviation between the inside and the outside of the cold storage 1 as well as the air conditioner 30 while the temperature of the air sucked from the outside is already heated or cooled. By introducing into), it is possible to reduce the energy consumption of the air conditioner (30) for heating or cooling the intake air can also reduce the maintenance costs in the process of using the cold storage (1).

Here, the suction damper 21, like the discharge damper 11 described above, is installed on the side wall of the cold storage 1 so as to be openable and closeable on one side of the suction duct 20 so that the suction duct 20 is the cold storage 1 In order to be able to communicate with the inside and outside of the), and open or closed by the control unit (C) to control the suction of the outside air of the cold storage (1), a conventional rotary damper or a fire damper may be applied.

In addition, in the installation of the cold storage 1, the suction duct 20 is preferably provided with suction fans 22 installed therein, which facilitates air outside the cold storage 1. In order to be able to inhale, the above-described suction fan 22 is connected to the control unit (C).

In addition, the suction duct 20 is provided with a control valve 23 for controlling the direction in which air flows to the other side of the above-described suction damper 21 at one end portion where air outside the cold storage 1 is sucked into the inside. This control valve 23 is connected to the control unit (C).

In addition, the suction duct 20 is composed of first and second ducts 20a and 20b branched to both sides with respect to the control valve 23 on the other side of the suction damper 21. 20a and 20b are connected to an air conditioner 30, which will be described later, on each side opposite to the control valve 23.

That is, as shown in Figure 1, the first duct 20a of the suction duct 20 is configured to extend along the upper periphery (ceiling portion) of the cold reservoir 1, the side opposite to the control valve 23 position described later Directly connected to the air conditioner 30, the second duct 20b of the suction duct 20 has a relatively short length and the opposite side of the control valve 23 position is directly connected to the air conditioner 30 Will be.

On the other hand, the air conditioning system for the cold storage 1 of the present invention is installed in the cold storage 1 so as to be connected to the above-described discharge duct 10 and the suction duct 20 to the signal input from the temperature sensor (T). Accordingly, the air conditioner 30 adjusts the temperature of the air flowing into the cold storage 1 to the temperature range of the air which is already set.

Such an air conditioner 30 is to adjust the temperature, humidity, air flow, and cleanliness of the air to the most optimal state in a room or a specific place in accordance with the purpose of use, in the present invention, inside the cold storage 1 It is the same or similar to the conventional air conditioner that controls the temperature of the air to be introduced, the main purpose, but also may control the above-mentioned humidity, air flow or cleanliness depending on the stored agricultural products or fresh food, Detailed description will be omitted.

On the other hand, in the lower portion (bottom portion) of the cold storage 1, the air is installed to be connected to the above-described air conditioner 30, the air adjusted to the temperature already set by the air conditioner 30 inside the cold storage 1 It is provided with an inlet duct 40 to be introduced into.

The inlet duct 40 is a tubular shape having a length, the longitudinal section of the inlet duct 40 may be made of a polygon including a circular, oval or square, pentagon, the lower portion of the cold storage 1 from the air conditioner 30 described above It is preferable to be installed so as to extend through the bottom portion and extend to the bottom portion of each of the plurality of storage areas S.

At this time, the inlet duct 10, in the installation for the cold storage 1, is provided by installing the inlet grating 41 to communicate with the interior of the cold storage 1 at the bottom of the above-described storage areas (S). It is preferable to allow, and this is to allow the temperature controlled air to be introduced into the cold storage (1), it is provided with an inlet fan (not shown) connected to the control unit (C) inside the cold storage (1) The inflow of air into the inside can be made easier.

In the description of the present invention, as described above, through the configuration of the suction duct 20 and the inlet duct 40, it was described as to be introduced into the cold storage 1 by adjusting the temperature of the air sucked from the outside. However, the present invention is not limited thereto, and the suction duct 20 and the inlet duct 40 are regarded as an integral configuration, and the inlet duct 40 is integrally extended from the suction duct 20 through the air conditioner 30. It is, of course, possible to penetrate the lower portion (bottom portion) of the cold storage 1.

On the other hand, the discharge duct 10 and the suction duct 20 is installed in the upper portion (ceiling portion) of the cold storage 1 is installed so as to be connected to the discharge duct 10 and the suction duct 20 and discharge duct ( 10) is provided with a heat exchanger (50) for the air discharged to the outside of the cold reservoir (1) and the air sucked into the cold reservoir through the suction duct 20 to perform heat exchange.

At this time, the first duct 10a of the discharge duct 10 and the first duct 20a of the suction duct 20 are discharge air and intake air flowing through the heat exchanger 50 as shown in FIG. 3. It is preferable to be connected to the heat exchanger 50 to form a step in the up, down, or left and right directions so as to cross each other and flow to form heat exchange.

The heat exchanger 50 is a plate heat exchanger provided to stack or adjoin a plurality of heat transfer elements 51 (plate heat exchange elements), which are commonly used in a room or a specific place requiring air conditioning. Although a detailed description thereof will be omitted, the temperature difference between the inside and the outside air of the cold storage 1 is provided by the heat exchanger 50 having the above-described heat exchanger 50 in the cold storage air conditioning system of the present invention, thereby performing heat exchange. In addition, the freshness of the stored agricultural products or fresh foods is maintained, as well as the air conditioning for heating or cooling the intake air as the temperature of the air sucked from the outside enters the air conditioner 30 while it is already heated or cooled. It is obvious that the energy consumption of the machine 30 can be reduced, so that the maintenance cost can be reduced during the use of the cold storage 1. Place found.

In particular, the heat exchanger 50 configured in the present invention is discharged from the one side of the insulating element 51 and the cold storage (1) that the air sucked from the cold storage (1) is introduced into the heat exchanger (50). The primary filter P is provided at the other side of the insulation element 51 through which air flows into the heat exchanger 50, and the secondary filter is disposed between one side portion of the insulation element 51 and the primary filter P. It is characterized by further including (M).

Here, the primary filter (P) is a pre-filter (Pre Filter) capable of collecting 80% or more of dust of 3㎛ to 10㎛ in the air is a basic filter generally used in the room or a specific place for the purpose of air conditioning, The secondary filter M is a high performance medium filter having a collection efficiency of 95% or more, and is used as a final filter indoors or in a specific place for the purpose of air conditioning.

Through this, the air sucked from the outside of the cold storage 1 can be filtered by the primary filter P and the secondary filter M to supply fresh air into the cold storage, and to circulate the air inside the cold storage. In this case, the air discharged from the cold storage 1 is filtered with the primary filter P, and then sterilized by the above-described optical plasma sterilization unit 14 so as to be re-introduced into the cold storage 1, thereby storing agricultural products. Or fresh fresh food can be more firmly maintained.

On the other hand, the air conditioning system for the cold storage 1 of the present invention is connected to the discharge duct 10, the suction duct 20, the air conditioner 30 and the inlet duct 40 described above to control the cold storage The control unit C is configured to achieve air conditioning of (1). The control unit C described above with reference to FIGS. 4 to 6 will be described in detail as follows.

The control unit C of the air conditioning system for the cold storage 1 according to the present invention is that the temperature inside the cold storage 1 in which agricultural products are stored in the storage areas S from the above-described temperature sensor T has already been reached. When a signal that is greater than or equal to the set temperature range is input, the temperature sensor T detects the discharge of the internal air and the intake of the external air according to the temperature of the external temperature of the cold storage 1 input. It is programmed to circulate the air in the cold storage 1 and to control the air conditioner 30 to heat or cool the air sucked from the outside or circulated therein.

That is, when the temperature inside the cold storage 1 detected and input by the temperature sensor T is greater than or equal to a preset temperature range, the control unit C opens the control valve 13 with the discharge damper 11 open. It is closed so that the air in the cold storage 1 is discharged to the outside through the first duct 10a.

At this time, the controller C controls the discharge of the air inside the cold storage 1 described above to the outside through the first duct 10a, and also opens the suction damper 21 to open the cold storage 1 Allow outside air to be sucked into the interior.

In this process, the air discharged from the inside of the cold store 1 and the air sucked from the outside at the same time form heat exchange through the heat exchanger 50 and the inside of the cold store 1 is ventilated, and thus, the cold store ( 1) The freshness of the stored agricultural products or fresh foods is maintained by reducing the temperature deviation of the internal and external air, as well as the temperature of the air sucked from the outside is introduced into the air conditioner 30 while it is already heated or cooled, It is possible to reduce the energy consumption of the air conditioner 30 for heating or cooling the intake air.

In particular, the control unit C controls the control valve of the suction duct 20 according to the degree of temperature difference with the temperature range of the internal temperature of the cold storage 1, in which the temperature outside the cold storage 1 detected by the temperature sensor T is already set. The control unit 23 controls the air outside the cold storage 1 sucked into the suction damper 21 to be sucked into the first duct 20a or the second duct 20b.

More specifically, when the temperature inside the cold storage 1 detected and input by the temperature sensor T is greater than or equal to a preset temperature range, the controller C determines that the air inside the cold storage 1 is the first duct described above. When discharged to the outside through the (10a), but the temperature outside the cold storage (1) is far outside the already set internal temperature range by controlling the control valve 23 of the suction duct 20 to the first duct (20a) By allowing the air outside the cold storage 1 to be sucked in, the heat exchanger 50 flows to achieve heat exchange with the air discharged from the inside.

In addition, when the temperature outside the cold storage 1 does not differ significantly from the preset internal temperature range, the cold storage 1 is controlled by the second duct 20b by controlling the control valve 23 of the suction duct 20. By allowing the outside air to be sucked, it is possible to immediately flow into the air conditioner 30 in a state where the heat exchanger 50 does not flow.

For example, when the temperature range inside the cold storage 1 that is already set is 1 ° C to 5 ° C, the temperature outside the cold storage 1 is -15 ° C or lower when the temperature inside the cold storage 1 is 5 ° C or more. If the temperature is 20 ° C., the control unit C, as described above, the air outside the cold storage 1 through the control of the control valve 23 of the suction duct 20 is the first duct 20a of the suction duct 20. Heat exchange with the air discharged to the discharge duct 10 through the heat exchanger 50 to be sucked into the air conditioner 30 while being heated or cooled to some extent and adjusted to a range of 1 ° C. to 5 ° C. To be possible.

In addition, when the temperature outside the cold storage 1 is −5 ° C. or 10 ° C., as described above, the controller C controls the cold storage 1 through the control of the control valve 23 of the suction duct 20. ) The outside air is sucked into the second duct 20b of the suction duct 20 to be introduced into the air conditioner 30 without heat exchange with the discharged air, thereby being heated or cooled by the air conditioner 30. In the controlled state in the range of 1 ℃ to 5 ℃ set to be introduced into the cold storage (1) through the inlet duct (40).

Of the control of the control unit C according to the temperature range set in advance and the degree of external temperature difference, the air outside the cold storage 1 described above is sucked into the second duct 20b of the suction duct 20, The amount of energy consumed as the air conditioner 30 heats or cools the introduced air is sucked into the first duct 20a to heat or cool the air in a state of being heated or cooled to some extent through heat exchange. It is desirable to apply this to indicate a temperature difference that will be at or above the level.

On the other hand, the control unit (C) described above, as shown in Figure 6, in the state in which both the above-described discharge damper 11 and the suction damper 21 is closed, the air in the cold storage 1 that is more than the temperature range already set. The air is supplied to the air conditioner (30) without being discharged to the outside, and is adjusted to a temperature range inside the already set cold storage (1), and then the cold storage (through the inlet duct 40) again ( 1) It is characterized in that the cold storage (1) to be introduced into the internal circulation of the air.

This is preferably applied when the temperature outside the cold storage 1 is more than the temperature range inside the cold storage 1 that is already set. In detail, the temperature inside the cold storage 1 detected by the temperature sensor T is input. If the temperature is above the preset temperature range and the temperature outside the cold storage 1 is also above the preset internal temperature range, the controller C closes both the discharge damper 11 and the suction damper 21 to store the cold storage ( 1) Shut off external exhaust of internal air and internal intake of external air.

In this state, the control valve 13 of the discharge duct 10 is opened, and the air inside the cold storage 1 is introduced into the air conditioner 30 through the first and second ducts 10a and 10b and cooled. , Through the inlet duct 40 to be re-introduced into the cold storage (1).

Here, when opening the discharge damper 11 described above, the harmful bacteria or harmful gas discharged by the above-mentioned metabolism of agricultural products together with the air inside the cold storage 1 discharged are discharged, but the discharge damper 11 is thus discharged. Harmful bacteria or harmful gases contained in the air inside the cold storage 1 introduced into the air conditioner 30 while the light is blocked are passed through the second duct 10b of the discharge duct 10 while the optical plasma member ( Decomposed by 14a) can be discharged to the outside of the cold storage 1 through the decomposition duct (14b).

As such, the agricultural products stored in the cold storage 1 through the control unit C connected to the discharge duct 10, the suction duct 20, the air conditioner 30 and the inlet duct 40 to control them. Detects the temperature rise inside the low temperature reservoir (1) due to the release of metabolites such as ethylene gas, methane gas or volatile gas due to the metabolism of the low temperature reservoir (1) By automatically maintaining within the appropriate temperature range, it is possible to easily inhibit the oxidation or decay of the stored agricultural products.

In addition, in the process of storing a variety of agricultural products or fresh food in a plurality of storage area (S), the temperature sensor (T) and the control unit (C) connected to it by sensing the temperature inside and outside the cold storage (1) automatically The air inside is discharged and at the same time the outside air is introduced or the inside air is circulated while blocking the inflow of the outside air, and through the air conditioner (30) into the cold storage (1) By adjusting the incoming air within the predetermined temperature range, the temperature inside the cold storage 1 is maintained within the temperature range, thereby preventing the quality degradation including freshness of the stored agricultural products.

Cold storage air conditioning system according to another embodiment of the present invention, the exhaust duct 10, the suction duct 20, the air conditioner 30, the inlet duct 40 and the control unit (C) As described above.

However, as shown in FIGS. 7 and 8, instead of the heat exchanger 50 described above, the discharge duct 10 and the suction duct 20 are formed in a double tube shape so that It is characterized by natural heat exchange during discharge and intake of outside air.

That is, the discharge duct 10 is formed in the shape of wrapping around the suction duct 20 to be installed in the cold storage 1, through which the discharge duct 10 and the suction duct 20 forms a heat exchange structure. By reducing the temperature difference between the inside and outside of the cold storage 1, the freshness of the stored agricultural products or fresh foods is maintained, as well as the air conditioner 30 while the temperature of the air sucked from the outside is already heated or cooled. As it is introduced into the), it is possible to reduce the energy consumption of the air conditioner 30 for heating or cooling the intake air.

In addition, the suction duct 20 is formed in a shape that is wrapped at intervals inside the discharge duct 10 is installed in the cold storage 1, in this case, the suction duct 20, the discharge duct 10 on the outer surface And a spacing member 24 which is joined to the inner side of the side wall, and the spacing member 24 is joined to the inner wall surface of the discharge duct 10 by welding or the like to suction the inner wall surface of the discharge duct 10. The space between the outer surfaces of the duct 20 is maintained to partition the space in which the air inside the cold storage 1 is discharged, and to the outer surface of the suction duct 20 by welding or the like to protrude outward. It can be provided.

1: low temperature storage 10: exhaust duct
10a: first duct 10b: second duct
11: discharge damper 12: discharge fan
13: control valve 14: optical plasma sterilization unit
14a: optical plasma member 14b: decomposition duct
20: suction duct 20a: first duct
20b: 2nd duct 21: suction damper
22: suction fan 23: control valve
24: space keeping member 30: air conditioner
40: inlet duct 41: inlet grating
50: heat exchanger 51: heating element
C: control unit M: secondary filter
P: Primary filter S: Storage area
T: Temperature sensor

Claims (12)

A discharge duct 10 installed to communicate the inside and the outside of the cold storage 1 and having a discharge damper 11 for discharging the air inside and controlling the flow of the discharged air; An intake duct 20 having heat exchange with the discharge duct 10 and installed to allow the outside air to be sucked into the cold storage 1, and having a suction damper 21 to control the flow of the sucked air; Air conditioning to adjust the temperature of the air to the temperature range of the air is already set in accordance with the signal input from the temperature sensor (T) provided in the cold storage (1) by connecting to the discharge duct 10 and the suction duct 20 Group 30; An inlet duct 40 connected to the air conditioner 30 to allow the temperature controlled air to be introduced into the cold storage 1; And when the temperature of the inside of the cold storage 1 from the temperature sensor (T) is a signal of more than the predetermined temperature range, the cold storage (1) to achieve the discharge of the internal air and the intake of external air, or cold storage ( 1) a controller (C) programmed to circulate the air therein and to control the air conditioner (30) to heat or cool the air sucked from the outside or circulated therein; Installed in connection with the discharge duct 10 and the suction duct 20, and provided with a plurality of plate-shaped insulating elements 51 and the inside of the cold storage (1) flowing through the discharge duct 10 and the suction duct 20 and Including the heat exchanger 50 to make the outside air heat exchange,
The discharge duct 10 is provided with a discharge fan 12 on the ceiling of the storage areas (S) formed in the cold storage (1),
The suction duct 20 has suction fans 22 therein,
The inlet duct 40 is cold storage air conditioning system, characterized in that the inlet grating 41 is formed on the bottom of the storage area (S). delete The method of claim 1,
The discharge duct 10 and the suction duct 20 are control valves 13 for controlling the direction in which air flows to one end of the air inside the cold storage 1 discharges to the outside or the outside air is sucked into the inside. 23, respectively,
The control valve (13,23) is a cold storage air conditioning system, characterized in that the connection with the control unit (C). The method of claim 3, wherein
The discharge duct 10 is composed of first and second ducts 10a and 10b branched from both sides of the discharge damper 11 to both sides,
The control valve 13 is provided on the side of the second duct 10b bordering the first duct 10a,
The second duct (10b) is a cold storage air conditioning system, characterized in that the side opposite the control valve (13) is connected to the air conditioner (30). The method of claim 4, wherein
When the temperature inside the cold storage 1 input by the temperature sensor T is detected by the temperature sensor T, the controller C is above a preset temperature range,
In the state in which the discharge damper 11 is opened, the control valve 13 is closed so that air in the cold storage 1 is discharged to the outside through the first duct 10a,
The control valve 13 in a state in which the discharge damper 11 is closed when the temperature of the outside of the cold storage 1 detected and input by the temperature sensor T is equal to or greater than a temperature range inside the cold storage 1 that is already set. The air conditioning system for cold storage, characterized in that to open the air inside the cold storage (1) to the air conditioner (30) through the first and second ducts (10a, 10b). The method of claim 3, wherein
The suction duct 20 is composed of first and second ducts (20a, 20b) branched to both sides with respect to the control valve 23,
The first and second ducts (20a, 20b) is a cold storage air conditioning system, characterized in that the opposite side of each of the control valve (23) is connected to the air conditioner (30). The method of claim 6,
When the temperature inside the cold storage 1 input by the temperature sensor T is detected by the temperature sensor T, the controller C is above a preset temperature range,
Open the suction damper 21 to allow the air outside the cold reservoir 1 to be sucked into the air, but control the control valve 23 according to the temperature difference with the temperature range of the internal temperature of the cold reservoir 1 already set. Is sucked into the first duct 20a or the second duct 20b, or
Cold storage air, characterized in that for closing the suction damper 21 when the temperature of the temperature sensor (T) detected and input outside the temperature range of the inside of the cold storage (1) already set. Harmony system. The method according to claim 5 or 7,
When the discharge damper 11 and the suction damper 21 are opened, the air flowing into the air conditioner 30 is heated or cooled to flow into the inlet duct 40,
When the discharge damper (11) and the suction damper (21) is closed, the air flowing into the air conditioner (30) is cooled and flows into the inlet duct (40), characterized in that the air conditioning system. The method of claim 5,
The discharge duct 10 is provided with an optical plasma sterilization unit 14 in the second duct 10b,
The optical plasma sterilization unit 14 is an optical plasma member 14a for decomposing harmful bacteria or harmful gases in the air discharged from the inside of the cold storage 1 inside the second duct 10b;
Decomposition duct is installed to communicate the outside of the optical plasma member (14a) and the low-temperature storage (1) so that harmful bacteria or harmful gases of air decomposed into the optical plasma member (14a) is discharged to the outside of the low-temperature storage (1) ( 14b) cold storage air conditioning system characterized in that consisting of. delete The method of claim 1,
The air flowing through the discharge duct 10 and the suction duct 20 crosses the inside of the heat exchanger 50.
One side of the insulating element 51 into which the air sucked from the cold storage 1 outside is introduced into the heat exchanger 50 and the air discharged from the cold storage 1 are transferred into the heat exchanger 50. On the other side of the insulating element 51 introduced to the primary filter (P), respectively
A secondary filter (M) further comprises a secondary filter (M) between one side of the insulating element (51) and the primary filter (P). The method of claim 1,
The discharge duct 10 is made of a shape wrapped around the suction duct 20 at intervals,
The suction duct 20 is a cold storage air conditioning system, characterized in that the outer surface is provided with a space maintaining member (24) which is joined to the inner surface of the discharge duct (10).

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