KR20200014551A - Dryer for blowing cooled air - Google Patents

Abstract

The present invention relates to a cold air dryer drying agricultural products (hereinafter, an object to be dried) with the air of room temperature to prevent thermal deformation of the object to be dried, which may occur in high temperature drying, and nutrient breakage caused by thermal deformation. According to the present invention, the cold air dryer comprises: a body unit having a space formed therein to receive an object to be dried; a refrigeration cycle unit installed in the body unit and including a compressor which compresses and discharges refrigerant, a condenser which condenses the refrigerant discharged from the compressor, an expansion valve which expands the refrigerant condensed in the condenser, and an evaporator which is disposed to allow the refrigerant expanded in the expansion valve to be evaporated through heat exchange with internal air of the body unit while the refrigerant passes through the body unit; a plurality of vortex generation fans installed in the body unit at predetermined intervals to generate a vortex in the body unit, and inclined by a predetermined angle to move cold air generated from the refrigeration cycle unit to the upper part of the body unit; a discharge unit formed on the lower part of the body unit and discharging humidity removed from the object to be dried to the outside; and a dehumidification unit installed on the upper part of the body unit and sucking the air inside the body unit to remove humidity.

Description

Dryer for blowing cooled air

The present invention relates to a cold air dryer, and more particularly, to dry agricultural and aquatic products (hereinafter, to be dried) by using air at room temperature to prevent nutrient destruction due to thermal deformation and thermal deformation of dried products that may occur at high temperature drying. It relates to a cold air dryer.

Generally, aquatic product drying methods include natural drying methods using hot sunlight and wind, hot air drying methods, freeze vacuum drying methods, and cold air drying methods.

The natural drying method is sensitive to temperature and climatic seasons, which not only has problems with the stable supply and storage of the product, but also is not suitable for producing uniform products.

The hot air drying method uses oil and electricity as energy sources to heat the dry object using a high temperature of 70 degrees or higher, thereby exchanging the air in the dryer, which is saturated steam, with external air, and proceeding with drying.

This requires a high temperature required for drying, has a high energy consumption for generating high heat, and also has a problem of high energy loss by releasing heated air into the atmosphere.

In addition, the hot air drying method does not bond to the drying of fish because the characteristics of the dry matter such as nutrients and fats, which are the main components of the dry matter, are discolored, discolored, decolored, taste and fragrance nutrients are lost and oxidized due to the oxidative fermentation action of high temperature drying.

In the case of the freeze vacuum drying method, an excellent dry matter can be obtained, but a large expensive facility is required, and there is a problem in that the amount of dry matter can be obtained in comparison with its size.

On the other hand, the cold air drying method is a method of drying the dry object using the air at room temperature, Patent Publication No. 10-1340151 "Cold air dryer" (registration date: 2013.12.26) has been proposed.

In the conventional cold air dryer, a compressor, a condenser, an expansion valve, and an evaporator are basically provided to discharge moisture by using a temperature difference between the condenser and the evaporator in the dryer, and a heat exchanger exchanges the air in the drying room with the outside by using a damper to control the temperature in the drying chamber. By operating the dryer to increase the temperature in the dryer by using the electric heater to thaw and the compressor operating temperature, the energy consumption is high, and the taste, aroma, quality, and functionality of the food are good, but there is a high cost and a high energy consumption rate.

In addition, in the conventional cold air dryer, the difference in humidity inside the drying chamber occurs according to the position of the blower fan suctioned into the drying chamber, thereby causing a difference in the dryness of the dried product, and thus, the drying time until the drying of the dried product is completed. There was an increasing problem.

The present invention has been made to solve the above problems, by generating a vortex in the air supplied to the drying chamber to reduce the temperature and humidity difference in the interior space of the drying chamber uniform at the same temperature irrespective of the position of the dry matter contained therein The main object is to provide a cold air dryer that can be dried easily.

The cold air dryer according to the present invention includes a main body portion having a space in which a dry object to be dried is formed, a compressor installed in the main body portion, a compressor for pressurizing and discharging a refrigerant, a condenser for condensing the refrigerant discharged from the compressor, A refrigeration cycle unit including an expansion valve configured to expand the refrigerant condensed in the condenser, an evaporator disposed to evaporate through heat exchange with internal air of the body portion while the refrigerant expanded in the expansion valve passes through the inside, and the body portion A vortex generating fan installed in a plurality of spaced intervals within the main body to generate vortices therein, the vortex generating fan being inclined at a predetermined angle so that the cool air generated from the refrigeration cycle unit moves to an upper portion of the main body, and the main body Is formed in the lower portion, to discharge the moisture removed from the dried to the outside Chulbu doedoe and mounted to the upper body portion, characterized in that it comprises a dehumidifier for removing the moisture by suction the air inside the main body of the.

In addition, the cold air dryer is characterized in that it further comprises a control unit for controlling the temperature and humidity inside the body portion by controlling the operation of the refrigeration cycle unit, the vortex generating fan and the dehumidifying unit.

The dehumidifying unit may further include an intake member for sucking air in the main body, a dehumidifying member for removing moisture from the air passing through the intake member, and air dehumidified from the dehumidifying member. And an exhaust member for flowing in.

The cold air dryer according to the present invention generates vortices in the main body of the outside air sucked through the refrigeration cycle unit to uniformize the temperature and humidity of the inside of the main body, so that even if the positions of the dry items contained in the main body are different. It provides the effect of improving the quality by drying to improve the quality.

In addition, the air sucked into the main body through the vortex generating fan installed to be inclined upward in the main body to move to the dehumidifying unit installed on the upper side of the main body to dry the dry matter, and the humid air is moved to the dehumidifying unit to remove moisture Since the inside of the main body can be kept dry, there is an effect that can provide an environment that is easy to dry the dry matter.

In addition, when the temperature and humidity inside the main body is higher or lower than the set temperature and humidity, the temperature and humidity in the main body through the control unit for controlling the operation of the refrigeration cycle unit, the vortex generating fan and the dehumidifying unit to the set temperature and humidity It provides an effect that can maintain to improve the drying efficiency.

1 is a block diagram showing a cold air dryer according to an embodiment of the present invention.
2 is a block diagram showing a refrigeration cycle unit according to an embodiment of the present invention.
Figure 3 is a block diagram showing a vortex generating fan according to an embodiment of the present invention.

Hereinafter, the technical spirit of the present invention will be described in more detail with reference to the accompanying drawings.

The accompanying drawings are only examples as illustrated in order to describe the technical idea of the present invention in more detail, and thus the technical idea of the present invention is not limited to the accompanying drawings.

However, in the following description of the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

1 is a block diagram showing another cold air dryer according to an embodiment of the present invention.

As shown in FIG. 1, the cold air dryer 1000 according to the present invention includes a main body 100, a refrigeration cycle unit 200, a vortex generating fan 300, a discharge unit 400, and a dehumidifying unit 500. Include.

First, the inside of the main body portion 100 provides a space for receiving agricultural products (including fish such as fish and squid, fruit such as dried persimmon, pepper ginseng, livestock products, vegetables, etc.), the following dry matter.

At this time, the main body portion 100 provides a structure in which at least one shelf for accommodating the goods to be stacked therein is stacked, the door may be provided to open and close the front, air supply and exhaust ports are provided, respectively, Vents for blowing air may be provided.

Next, as shown in FIG. 2, the refrigeration cycle unit 200 is installed in the main body part 100, and the compressor 210, the condenser 220, the expansion valve 230, and the evaporator 240 are disposed. Include.

At this time, the refrigeration cycle unit 200 is to provide the cold air in the main body portion 100 in the same principle as the principle of providing cold air to the setting space using a conventional air conditioner.

At this time, the refrigerant used in the refrigeration cycle unit 200 refers to a medium that takes heat from a low temperature object as a working fluid and transfers heat to a high temperature object.

Hereinafter, the refrigerant has a boiling point at a temperature of 10 ° C. or less (eg, a temperature range of −40 ° C. to 10 ° C.) such as ammonia, freon (dichlorodifluoromethane), metal chloride, liquid helium, liquid hydrogen, and the like. As a substance, it refers to a substance which is easily vaporized at a low temperature.

Here, the compressor 210 compresses a refrigerant circulated to form a refrigeration cycle from a gas of low temperature and low pressure to a gas of high temperature and high pressure and discharges it to the condenser 220, and the condenser 220 is discharged from the compressor 210. The refrigerant is condensed into a liquid refrigerant of high temperature and high pressure.

In addition, the expansion valve 230 expands to a low temperature low pressure refrigerant while flowing the high temperature and high pressure refrigerant condensed in the condenser 220 and flows into the evaporator 240.

In addition, the evaporator 240 evaporates the refrigerant passing through the expansion valve 230 while being heat-exchanged with the air inside the body part 100.

By the above-described configuration, the air introduced from the outside of the main body unit 100 is introduced through the condenser 220 to exchange heat with the refrigerant in the evaporator 240 to provide cold air into the main body unit 100.

Next, as shown in Figure 3, the vortex generating fan 300 is installed in a plurality of spaced apart a predetermined interval inside the main body portion 100 so that the vortex occurs in the air inside the main body portion 100, Cool air generated from the refrigeration cycle unit 200 is installed to be inclined at an angle to move to the upper portion of the main body portion 100.

Low temperature cold air generated from the refrigeration cycle unit 200 is moved to the lower side inside the main body portion 100, the cold air moved to the lower portion of the main body portion 100 by the drive of the vortex generating fan 300 Will move to the top.

More specifically, as shown in FIG. 3, when the main body portion 100 is formed into a rectangular parallelepiped, the first vortex generating fan 310 positioned on the first side surface 110 may move the second side surface 120. The second vortex generating fan 320 which is installed to be inclined upward while facing the second side 120 is installed to be inclined upward while facing the third side 130, and the third side 130. The second vortex generating fan 330 positioned at is inclined upward while facing the fourth side 140.

In addition, the fourth vortex generating fan (not shown) installed on the fourth side 140 is installed to be inclined upwardly toward the first side 110 and the first to third vortex generating fans 310, 320, and 330. By the driving of the fourth vortex generating fan, air in the main body part 100 is generated in a vortex phenomenon (swirl) around the main body part 100, and moves above the main body part 100.

In addition, even if the main body 100 is formed not only in a rectangular parallelepiped but also in various polygonal cylinders or cylinders, a plurality of vortex generating fans 300 are installed in a spiral shape on the side of the main body 100 but inclined upward. 100) it is possible to move the upper air while rotating inside.

That is, the cold air dryer 1000 of the present invention moves to the upper side while generating a vortex in the air inside the body portion 100 through the vortex forming fan 300 and the nature of the low temperature gas sinks, the body portion 100 By providing air of the same temperature and humidity to the entire interior space, it is possible to provide an effect that can exhibit a uniform drying efficiency even if the location of the contained objects in the interior are different.

In addition, the discharge part 400 is formed below the main body part 100, and the moisture removed from the dry matter is collected and discharged to the outside of the main body part 100.

The air inside the main body 100 is vortexed by the vortex generating fan 300 to remove water from the dry matter contained in the main body 100, and the water dropped from the dry to lower the main body 100. Collected by the discharge plate 410 formed in the, the water collected in the discharge plate 410 is discharged to the outside through the discharge pipe 420 is formed through one side of the main body portion 100.

Next, the dehumidifying part 500 is installed above the main body part 100, and removes moisture by sucking air in the main body part 100.

In this case, the dehumidifying unit 500 includes an intake member 510, a dehumidifying member 520, and an exhaust member 530, as shown in FIG. 1.

First, the intake member 510 is provided with a suction fan to suck the air in the main body portion 100, and moves the air containing moisture in the main body portion 100 to the dehumidifying member 520.

The dehumidifying member 520 is provided with a heat insulating material on the inner wall to remove moisture of the air passing through the intake member 510, and a thermoelectric element is provided inside to remove moisture in the air by using heat.

In addition, the exhaust member 530 is connected between the dehumidifying member 520 and the main body 530 to re-introduce the air from which the moisture is removed from the dehumidifying member 520 into the main body 100.

At this time, the exhaust member 530 is connected to the lower portion of the main body 100, the high-temperature air from which moisture is removed from the dehumidifying member 520 is re-introduced into the lower portion of the main body portion 100, the refrigeration cycle unit The low-temperature gas provided at 200 and the high-temperature gas heated at the dehumidifying member 520 exchange heat so that the temperature of the entire body part 100 can maintain a set temperature (preferably 15 to 40 ° C). do.

When the temperature is lower than the above-described set temperature (15 to 40 ° C.), that is, when the temperature inside the main body part 100 is lower than 15 ° C., the dry matter occurs and the internal temperature is higher than 40 ° C. Problems such as discoloration, discoloration, taste, and fragrance nutrients are destroyed due to the oxidative fermentation effect of the dry matter such as nutrients and fat powder as ingredients.

In this case, the control unit 600 may further include a refrigeration cycle unit 200, a vortex generating fan 300, and a dehumidifying unit 500 to control the temperature and humidity inside the main body unit 100.

When the temperature inside the main body unit 100 is lower than the set temperature, the control unit 600 may control the operation of the refrigeration cycle unit 200 to increase the temperature inside the main body unit 100, and the main body unit ( If the internal temperature is higher than the set temperature, the operation of the dehumidifying unit 500 is controlled to prevent the air heated in the dehumidifying unit 500 from being introduced into the main body unit 100, thereby keeping the inside of the main body unit 100. It is possible to lower the temperature of.

At this time, the humidity represents the ratio of the amount of water vapor contained in the atmosphere and the maximum amount of water vapor the atmosphere can contain at the temperature at that time, in the present invention, the set humidity (30% to 80%) inside the main body 100 It can be maintained so that drying can take place.

That is, when the humidity inside the main body unit 100 is lower than the set humidity, the to-be-dried object dries too much and dries, thus losing control of the product. The control unit 600 controls the operation of the dehumidifying unit 500 to control the main body unit 100. ) Increasing the humidity in the interior, when the humidity inside the main body 100 is higher than the set humidity, the drying efficiency of the dry object is reduced, the drying time is increased, the refrigeration cycle unit 200 through the control unit 600 The operation stops and increases the dehumidifying power of the dehumidifying unit 500 to lower the humidity inside the main body unit 100.

As described above, in the cold air dryer 1000 of the present invention, the dehumidifying part 500 is installed above the main body part 100, and the water in the liquid state dehydrated in the dry matter is lowered in the main body part 100 by its own weight. Discharged through the discharge unit 400 installed in the, the humid air of the gas state containing water is discharged to the outside through the dehumidifying unit 500 located at the top by the vortex generating fan 300 to the inside of the main body 100 Maintaining the air in a low temperature state, of course, it is easy to dry to provide an effect that can increase the drying efficiency of the dry matter.

The present invention is not limited to the above-described embodiments, and the scope of application is not limited, and various modifications can be made without departing from the gist of the present invention as claimed in the claims.

100: main body 420: discharge pipe
110: first side 500: dehumidifying unit
120: second side 510: intake member
130: third side 520: dehumidifying member
140: fourth side 530: exhaust member
200: cycle unit 600: control unit
210: compressor
220: condenser
230: expansion valve
240: evaporator
300: Vortex Generating Fan
310: first vortex generating fan
320: second vortex generating fan
330: third vortex generating fan
400: discharge part
410: discharge plate

Claims (3)

A main body portion having a space for receiving a dry object to be dried;
A compressor installed in the main body to pressurize and discharge the refrigerant, a condenser for condensing the refrigerant discharged from the compressor, an expansion valve for expanding the refrigerant condensed in the condenser, and a refrigerant expanded in the expansion valve. A refrigeration cycle unit including an evaporator disposed to evaporate through heat exchange with the internal air while passing through the main body;
A vortex generating fan installed in a plurality of spaced intervals within the main body to generate a vortex inside the main body, and installed at an angle to incline at a predetermined angle so that cool air generated from the refrigeration cycle unit moves to an upper portion of the main body;
A discharge part formed under the main body part and discharging moisture removed from the dried material to the outside; And
And a dehumidifier installed on the main body to remove moisture by sucking air inside the main body.
The method of claim 1,
The cold air dryer,
And a control unit for controlling the operation of the refrigeration cycle unit, the vortex generating fan, and the dehumidifying unit to control temperature and humidity inside the main body unit.
The method of claim 1,
The dehumidifying unit,
An intake member for sucking air in the main body, a dehumidifying member for removing moisture from the air passing through the intake member, and an exhaust member for reintroducing air dehumidified from the dehumidifying member into the main body; Cold air dryer comprising a.

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