KR20230053321A - Heat pump cooling food dryer - Google Patents

Abstract

The present invention relates to a food dryer for drying food and, more specifically, to a technical field of a heat pump-cooling food dryer which dries food by using cold and warm air selectively through an evaporator and a compressor, wherein condensers are installed inside and outside the dryer, respectively, to absorb energy from the air inside and outside the dryer for drying. The temperature and moisture content of the air inside the dryer are controlled through the evaporator and the temperature and humidity sensor installed inside the dryer. Accordingly, energy is automatically absorbed through the outdoor or indoor condenser so as to dry the food to have optimal water content according to the food, and at the same time, to perform drying at the preset temperature and humidity according to the food by the temperature and humidity sensor.

Description

Heat pump cooling food dryer {Heat pump cooling food dryer}

The present invention relates to a food dryer for drying food, and more specifically, to dry food by selectively using cool air and warm air through an evaporator and a compressor, but absorbing energy from air inside and outside the dryer to dry the food. Condensers are installed inside and outside the dryer, and the temperature and moisture content of the air inside the dryer are adjusted through an evaporator and a temperature and humidity sensor installed inside the dryer to dry food with an optimal moisture content according to the food. Technology related to a heat pump-cooled food dryer that automatically absorbs energy through an outdoor condenser or an indoor condenser so that drying can be performed at the temperature and humidity according to the food set by the temperature and humidity sensor at the same time is the field

Recently, food dryers have been in the limelight as well-being home appliances that can be used in various ways such as snacks or food ingredients by easily drying various foods such as fruits and vegetables, as well as meat and fish (hereinafter, also referred to as 'objects to be dried').

In particular, by installing a fan and an air heater in the cabinet, the hot air is horizontally or vertically contacted and circulated between trays containing the objects to be dried, thereby evaporating moisture in the objects to be dried. A method of drying the object to be dried with hot air by vertically stacking several trays (strainers) in multiple stages on the upper side of the base where a drying-type cabinet dryer, fan, and air heater are installed. Laminate dryers are the mainstream.

For example, in the food dryer disclosed in Korean Utility Model Publication No. 20-0354535, as shown in FIG. 1, outside air is sucked in through the intake port 4-1 by the rotation of the fan 15 and the heater 12 ), and the air heated in this way passes through the half plates 11 of the drying rack stacked sequentially and is blown upward to dry the object to be dried, and then moves downward through the central through hole 9'. and repeats the process of being heated and circulated again by being introduced into the heater 12 again through the circulation hole 9, and a small amount of air is exhausted to the outside through the exhaust port 4 by natural convection. .

As another example, in the food dryer disclosed in Korean Registered Patent Publication No. 10-1446071, as shown in FIG. ), and then moves downward through the through passage 33a formed in the ventilation hole 33 of the cover body 31 and flows into the blower case 13 again, and at the same time, the ventilation hole 33 It consists of a structure in which external air is introduced through a through slot (33c) formed in the upper part of.

In these conventional food dryers, heated air (hot air) is repeatedly circulated and evenly delivered to the items to be dried, and since most of the retained heat is used for temperature rise and moisture evaporation of the items to be dried, the temperature difference between drying zones is reduced to reduce the temperature of the items to be dried. It has the advantage of fast drying, uniformity, and low energy loss.

However, due to the structural characteristics that most of the hot air except for heat radiation loss is not discharged, the amount of moisture containing moisture evaporated from the object to be dried is very small in the early stages of the drying process, causing fogging and condensation inside, which causes high temperature and high humidity. Since the hot air is continuously circulated, the drying efficiency is significantly reduced and it takes a long time to dry the object to be dried. In severe cases, water and water droplets fall on the object to be dried and contaminate it. There is a problem with the bay on the inside.

In other words, when drying in hot air at high temperature and humidity, the best quality as in natural drying with appropriate sunlight and wind cannot be obtained, and problems inevitably occur that degrade the quality of the product due to dampness, distortion, or distortion.

In addition, when the moisture content of the object to be dried is high, water and water droplets fall down due to its own weight during the drying process. There are bound to be limitations.

Therefore, in order to prevent fogging and water drop formation caused by high-temperature and high-humidity air during the initial drying process of the object to be dried, and to improve drying efficiency, hot air and moisture are automatically generated according to the moisture content or drying condition of the object to be dried. A technology capable of arbitrarily adjusting the displacement of the engine is required.

As a prior art for solving this problem, the complex food drying apparatus disclosed in Korean Patent Laid-Open Publication No. 10-2021-0056709, as shown in FIG. a dry housing sealable against; It is provided inside and outside the drying chamber, and the inside of the drying chamber is provided at a low temperature or A temperature control unit capable of providing a high temperature; and a pressure control unit capable of adjusting the internal pressure of the drying housing, wherein the temperature control unit includes a compressor, a first condenser provided in any one of a plurality of first branch pipes connected to the compressor, a plurality of first branch pipes and pipes. A second condenser connected through, a first evaporator provided on any one of a plurality of second branch pipes connected to the second condenser, and a second evaporator provided on the other of the second branch pipes connected to the second condenser. consists of a structure

The Korean Patent Laid-open Publication discloses that a condenser and an evaporator are provided in a drying chamber at the same time to selectively perform hot air drying and freeze drying of food. By applying a plurality of expansion valves, it is possible to perform the rapid freeze-drying and low-temperature storage functions separately. Drying is made possible.

However, the above Korean Patent Publication is excellent in removing moisture in the drying chamber, but in order to properly maintain the moisture in the drying chamber, outside air must be sucked, so dry food requiring an appropriate moisture content is not dried smoothly. there is.

Republic of Korea Patent No. 10-1670714 (2016.10.25.) Republic of Korea Patent Publication No. 10-2021-0056709 (2021.05.20.)

The present invention is a technique devised to solve the problems according to the prior art described above. Conventional food dryers can perform the functions of hot air drying, quick freeze drying, and low temperature storage of food, but drying the object to be dried, that is, food. It is difficult to discharge the moisture generated in the process, and there is a problem that drying is not performed smoothly by the moisture generated. To solve this problem, a condenser is installed outside to remove the residual moisture, However, it is difficult to maintain moisture inside the drying chamber, resulting in a problem that dry food containing appropriate moisture cannot be prepared;

The food is dried by selectively using cool air and warm air through an evaporator and a compressor, and condensers are installed inside and outside the dryer so that the food can be dried by absorbing the energy of air inside and outside the dryer, and the condensers are selectively It collects moisture, that is, water, generated from the evaporator installed in the dryer and supplies it to the condenser installed indoors or outdoors to minimize the deterioration of the condenser. The main purpose is to maintain the moisture content according to the food by adjusting the moisture inside the dryer and provide it through a heat pump cooling type food dryer capable of drying.

In order to realize the above-described object, the present invention has a drying space 110 in which food is dried and a facility space 120 partitioned to communicate with the drying space 110 at the rear of the drying space 110 is formed. A body housing 100; and a compressor 200 installed in the facility space 120; and an indoor condenser 300 installed in front of the facility space 120 and connected to the compressor 200 through a refrigerant pipe. and an evaporator 400 installed in the facility space 120, installed behind the indoor condenser 300, and connected to the indoor condenser 300 through a refrigerant pipe; and installed in the facility space 120 However, a supply fan 500 installed in front of the indoor condenser 300 to blow air into the drying space 110; and installed outside the main housing 100, the compressor 200 and the indoor The branch pipe installed in the refrigerant pipe to which the condenser 300 is connected is connected to the compressor 200, and the branch pipe installed in the refrigerant pipe connecting the evaporator 400 and the indoor condenser 300 to the evaporator 400. An outdoor condenser 600 connected to; and installed in a refrigerant pipe connecting the evaporator 400 and the indoor condenser 300, between the branch pipe connected to the outdoor condenser 600 and the evaporator 400. an expansion valve 700 installed; and at least one first temperature and humidity sensor 800 installed on one side or the other side of an upper surface of the drying space 110; and a control unit 900 installed in the body housing 100 to control the air volume, temperature and humidity of the air supplied into the drying space 110 based on the temperature and humidity measured by the first temperature and humidity sensor 800. ); Suggests a heat pump cooling type food dryer characterized in that it is configured to include.

In addition, the control unit 900 of the present invention controls the circulation of the refrigerant in either the indoor condenser 300 or the outdoor condenser 600 based on the temperature and humidity measured by the first temperature and humidity sensor 800. It is characterized by doing.

In addition, the present invention is installed in the facility space 120, and is characterized in that it is configured to include a passage partition wall 130 installed on both sides of the indoor condenser 300 and the evaporator 400.

In addition, the present invention is installed in the facility space 120, the collection unit 140 installed below the evaporator 400; and installed in the facility space 120 and collected in the collection unit 140 It is characterized in that it is configured to include; drain pump 150 for discharging water to the outside.

In addition, in the present invention, one side is connected to the drain pump 150, the other side is installed to surround the outdoor condenser 600, and a plurality of spray nozzles 240 face the outdoor condenser 600 on the other side. On the other hand, it is configured to include; a cooling pipe 230 equipped with a discharge valve 250 that can be opened and closed at the other end, and the injection nozzle 240 is characterized in that it can be opened and closed by the control unit 900.

In addition, the control unit 900 of the present invention controls the discharge valve 250 to be opened when controlling the circulation of the refrigerant to the indoor condenser 300, and controls the circulation of the refrigerant to the outdoor condenser 600 In this case, it is characterized in that the injection nozzle 240 is controlled to be opened.

In addition, the present invention is installed between the drying space 110 and the facility space 120, the sterilization filter unit 160 installed in a place where air is not blown by the supply fan 500; including The sterilization filter unit 160 includes a HEPA filter 161; and an air filter 162 installed in front of the HEPA filter 161; and a sterilization unit 163 installed in front of the air filter 162.

In addition, the sterilization unit 163 of the present invention includes a plurality of LED chips 163a installed on the rear surface to irradiate ultraviolet rays; and a wide angle installed outside the LED chip 163a to surround the LED chip 163a. lens 163c; and a plurality of ventilation holes 163b penetrating at locations where the LED chip 163a is not installed.

The heat pump-cooled food dryer according to the present invention presented as described above installs condensers inside the dryer, that is, in the drying space and outside the dryer, and installs an evaporator inside the dried meat, that is, in the drying space, so that the inside and outside of the dryer are installed. By using the thermal energy of, energy can be saved, and drying can be achieved through warm air and cold air by selectively using condensers installed inside and outside the dryer, so that both hot air drying and freeze drying can be achieved. .

In addition, the present invention collects water generated from the evaporator installed inside the dryer so that it can be sprayed to the condenser installed inside and outside the dryer, and at the same time measures the temperature and humidity inside the dryer through a temperature and humidity sensor to minimize performance degradation of the condenser. In addition, the moisture content of the air inside the dryer can be automatically adjusted, so that dry food having an appropriate moisture content can be easily manufactured.

1 is a longitudinal sectional view showing an example of a food dryer according to the prior art.
Figure 2 is a longitudinal sectional view showing another example of a food dryer according to the prior art.
Figure 3 is a configuration arrangement showing another example of a food dryer according to the prior art.
Figure 4 is a schematic plan view showing a food dryer according to a preferred embodiment of the present invention.
Figure 5 is a detailed schematic diagram showing a food dryer according to a preferred embodiment of the present invention.
Figure 6 is a detailed schematic view of the food dryer showing the flow of refrigerant when warm air is operated according to a preferred embodiment of the present invention.
Figure 7 is a detailed schematic diagram of a food dryer showing the flow of refrigerant during operation of cold air according to a preferred embodiment of the present invention.
Figure 8 is a detailed schematic diagram of a food dryer showing the flow of water supplied to the indoor condenser according to a preferred embodiment of the present invention.
Figure 9 is a detailed schematic diagram of a food dryer showing the flow of water supplied to the outdoor condenser according to a preferred embodiment of the present invention.
Figure 10 is a front view showing a sterilization unit according to a preferred embodiment of the present invention.
11 is a schematic partial cross-sectional view of a sterilizing filter unit according to a preferred embodiment (a) and another embodiment (b) of the present invention.

The present invention relates to a food dryer for drying various foods such as fruits or vegetables or meat or fish. ) is installed, and an outdoor condenser 600 is installed outside the drying space 110 to recover the energy contained in the air inside and outside the dryer, that is, inside and outside the drying space 110, and dry food to obtain energy. can be reduced, and food can be dried by selectively using cold air and warm air through the indoor condenser 300 and the outdoor condenser 600, while the first temperature and humidity sensor 800 inside the drying space 110 ) is installed to detect the moisture contained in the food, that is, the moisture evaporated from the food, so that drying can be performed at a predetermined temperature and humidity according to the food, and the water generated from the evaporator 400 is transferred to the indoor condenser 300 ) and the outdoor condenser 600 to minimize the performance degradation of the indoor condenser 300 and the outdoor condenser 600 and at the same time to automatically maintain the moisture inside the drying space 110, appropriate moisture It is a technology related to a heat pump cooling type food dryer that can easily produce dry food having a high content.

The configuration for achieving the present invention as described above is a body housing in which a drying space 110 in which food is dried and a facility space 120 partitioned to communicate with the drying space 110 at the rear of the drying space 110 are formed. (100); and a compressor (200) installed in the facility space (120); and an indoor condenser (300) installed in front of the facility space (120) and connected to the compressor (200) through a refrigerant pipe; and An evaporator 400 installed in the facility space 120, installed behind the indoor condenser 300, and connected to the indoor condenser 300 through a refrigerant pipe; and installed in the facility space 120, A supply fan 500 installed in front of the indoor condenser 300 to blow air into the drying space 110; and installed outside the main body housing 100, the compressor 200 and the indoor condenser ( 300) is connected to the compressor 200 through a branch pipe installed in the refrigerant pipe connected thereto, and is connected to the evaporator 400 through a branch pipe installed in the refrigerant pipe connecting the evaporator 400 and the indoor condenser 300. installed in the refrigerant pipe connecting the evaporator 400 and the indoor condenser 300, and installed between the branch pipe connected to the outdoor condenser 600 and the evaporator 400 an expansion valve 700; and at least one first temperature and humidity sensor 800 installed on one side or the other side of an upper surface of the drying space 110; and a control unit 900 installed in the body housing 100 to control the air volume, temperature and humidity of the air supplied into the drying space 110 based on the temperature and humidity measured by the first temperature and humidity sensor 800. ); Suggests a heat pump cooling type food dryer characterized in that it is configured to include.

In addition, the control unit 900 of the present invention controls the circulation of the refrigerant in either the indoor condenser 300 or the outdoor condenser 600 based on the temperature and humidity measured by the first temperature and humidity sensor 800. It is characterized by doing.

In addition, the present invention is installed in the facility space 120, and is characterized in that it is configured to include a passage partition wall 130 installed on both sides of the indoor condenser 300 and the evaporator 400.

In addition, the present invention is installed in the facility space 120, the collection unit 140 installed below the evaporator 400; and installed in the facility space 120 and collected in the collection unit 140 It is characterized in that it is configured to include; drain pump 150 for discharging water to the outside.

In addition, in the present invention, one side is connected to the drain pump 150, the other side is installed to surround the outdoor condenser 600, and a plurality of spray nozzles 240 face the outdoor condenser 600 on the other side. On the other hand, it is configured to include; a cooling pipe 230 equipped with a discharge valve 250 that can be opened and closed at the other end, and the injection nozzle 240 is characterized in that it can be opened and closed by the control unit 900.

In addition, the control unit 900 of the present invention controls the discharge valve 250 to be opened when controlling the circulation of the refrigerant to the indoor condenser 300, and controls the circulation of the refrigerant to the outdoor condenser 600 In this case, it is characterized in that the injection nozzle 240 is controlled to be opened.

In addition, the present invention is installed between the drying space 110 and the facility space 120, the sterilization filter unit 160 installed in a place where air is not blown by the supply fan 500; including The sterilization filter unit 160 includes a HEPA filter 161; and an air filter 162 installed in front of the HEPA filter 161; and a sterilization unit 163 installed in front of the air filter 162.

In addition, the sterilization unit 163 of the present invention includes a plurality of LED chips 163a installed on the rear surface to irradiate ultraviolet rays; and a wide angle installed outside the LED chip 163a to surround the LED chip 163a. lens 163c; and a plurality of ventilation holes 163b penetrating at locations where the LED chip 163a is not installed.

Hereinafter, the present invention will be described in detail with reference to FIGS. 4 to 11 showing embodiments of the present invention.

The main body housing 100, which is a major component for achieving the present invention,

A drying space 110 in which food is dried inside and a facility space 120 partitioned to communicate with the drying space 110 at the rear of the drying space 110 are formed, and the facility space 120 after A compressor 200, an indoor condenser 300, an evaporator 400, a supply fan 500, an expansion valve 700 and a controller 900 to be described in detail are installed in the drying space 110 later in detail. At least one first temperature and humidity sensor 800 to be described is installed to dry food in the drying space 110 through warm air or cold air.

The body housing 100 of the present invention has a structure in which the drying space 110 and the facility space 120 are sealed against the outside, that is, the outside of the drying space 110 and the facility space 120. Accordingly, when adjusting the internal pressure of the drying space 110 and the facility space 120 by a pressure control unit (not shown), which will be described in detail later, the pressure can be efficiently controlled.

At this time, the body housing 100 of the present invention is formed at the rear of the facility space 120 and may be configured to include an external door 180 that is opened and closed by a control unit 900 to be described in detail later. When formed, outside air may be introduced into the equipment space 120 by opening the external door 180 when outside air needs to be introduced, not when food is dried only by internal air circulation.

In addition, the body housing 100 of the present invention has a plurality of support frames (not shown) for supporting trays (not shown) for holding food inside the drying space 110, and the tray is pulled in at the front. An entrance door (not shown) that can be taken out is formed, and a maintenance door (not shown) for maintenance of the facility space 120 is formed at the rear.

In addition, the food dryer of the present invention is installed between the drying space 110 and the facility space 120, and the air inside the facility space 120 is blown by a supply fan 500 to be described in detail later. It is configured to include a sterilizing filter unit 160 installed in a place where air is not blown into the drying space 110.

The sterilization filter unit 160 sterilizes and purifies the air inside the drying space 110 when it is moved to the inside of the facility space 120 for circulation, thereby preventing the generation of foreign substances in the facility space 120. At the same time, it prevents the proliferation of viruses and realizes the effect of enabling drying through cleaner air.

Specifically, the sterilization filter unit 160 is installed between the drying space 110 and the facility space 120, but installed where air is not blown by the supply fan 500 to be described in detail later The HEPA filter 161 and the air filter 162 installed in front of the HEPA filter 161, that is, on the drying space 110 side, and the front of the air filter 162, that is, on the drying space 110 side. It is configured to include a sterilization unit 163 installed in.

That is, the sterilization filter unit 160 is located inside the drying space 110 as the air inside the facility space 120 is moved to the drying space 110 when the supply fan 500, which will be described in detail later, is operated. After the air is purified, it is allowed to enter the facility space 120, and foreign substances are first removed through the air filter 162 after passing through the sterilization unit 163 by the HEPA filter 161, and the virus contaminants are adsorbed and removed, and the front surfaces of the air filter 162 and the HEPA filter 161 are sterilized through the sterilization unit 163, thereby increasing the lifespan and preventing the growth of contaminants. do.

The sterilization unit 163 includes a base frame 163d and a plurality of LED chips 163a installed on the rear surface of the base frame 163d to irradiate ultraviolet rays. The performance of the air filter 162 and the HEPA filter 161 is not only maintained, but also the performance of the air filter 162 and the HEPA filter 161 is maintained by oxidizing and removing foreign substances and contaminants that are adsorbed and collected by the air filter 162 and the HEPA filter 161 through ultraviolet rays. It realizes the effect of removing odors generated from food through the ultraviolet rays.

In addition, the sterilization part 163 penetrates the wide-angle lens 163c installed outside the LED chip 163a so as to surround the LED chip 163a and the position where the LED chip 163a is not installed. It is composed of a plurality of ventilation holes 163b formed, and the air inside the drying space 110 passed through the ventilation holes 163b is filtered through an air filter 162 and a HEPA filter 161 When foreign substances and contaminants are collected in the air filter 162 and the HEPA filter 161, odors and contaminants generated from food are removed through ultraviolet rays irradiated from the LED chip 163a.

In addition, the wide-angle lens 163c may be composed of a generally used wide-angle lens, and may also be composed of a convex lens or a concave lens. , Ultraviolet rays are irradiated at a wider angle than normal lenses to sterilize the surface on which contaminants are accumulated on the air filter 162 and the HEPA filter 161, and when configured with a convex lens, a smaller angle than the wide-angle lens Although ultraviolet rays are irradiated, it is possible to concentrate the ultraviolet rays, so that contaminants, that is, viruses, can be easily removed.

At this time, when the wide-angle lens 163c is composed of a concave lens, as shown in the drawing, it is installed to surround the outer surfaces of all of the LED chips 163a arranged in a row to irradiate ultraviolet rays in a wider range. can

The compressor 200, which is a major component for achieving the present invention,

It is installed in the facility space 120, and is installed outside the facility space 120 according to need or capacity and can be installed with the indoor condenser 300 and the outdoor condenser 600 to be described in detail later, , Low-temperature/low-pressure refrigerant gas, ie, gas, is received from the evaporator 400 to be described in detail later, compressed into high-temperature/high-pressure gas, and sent to the indoor condenser 300 or the outdoor condenser 600.

At this time, when the compressor 200 of the present invention is installed in the facility space 120, it is composed of a heat pump and generates compression heat when compressing low-temperature/low-pressure gas, so that the temperature of the air inside the facility space 120 rises. Thus, as it can be used to control the temperature of the air blown into the drying space 110, the effect of saving energy is realized.

The indoor condenser 300, which is a major component for achieving the present invention,

It is installed in front of the facility space 120 and is connected to the compressor 200 through a refrigerant pipe, condensing the high-temperature/high-pressure gas delivered from the compressor 200 into a low-temperature/high-pressure liquid to generate heat, , The low-temperature/high-pressure liquid is sent to the expansion valve 700, which will be described in detail later, and the low-temperature/low-pressure liquid is sent to the evaporator 400, which will be described in detail later.

At this time, the indoor condenser 300 of the present invention raises the temperature of the air inside the facility space 120 and the air introduced into the facility space 120 from the drying space 110, to be described later in detail. Warm air can be supplied to the drying space 110 through the supplied fan 500 so that food can be dried.

The expansion valve 700 of the main component to achieve the present invention is

It is installed in the refrigerant pipe connecting the evaporator 400 and the indoor condenser 300 to be described in detail later, and a branch pipe (not shown) connected to the outdoor condenser 600 to be described in detail later and an evaporator to be described in detail later. It is installed between the evaporators 400, and receives the low-temperature/high-pressure liquid from the indoor condenser 300 or the outdoor condenser 600 to be described in detail later, converts it into low-temperature/low-pressure liquid, and transfers it to the evaporator 400. send.

The evaporator 400 of the main components for achieving the present invention

It is installed in the facility space 120, is installed behind the indoor condenser 300, and is connected to the indoor condenser 300 through a refrigerant pipe, and the expansion valve described above is between the indoor condenser 300 and the indoor condenser 300. 700 is installed to receive the low-temperature/low-pressure liquid converted by the expansion valve 700 and convert it into low-temperature/low-pressure gas to lower the temperature of the air inside the facility space 120 and at the same time (120) The water vapor contained in the air inside is condensed and converted to water, and the low-temperature/low-pressure gas is sent to the compressor (200).

At this time, the evaporator 400 of the present invention converts low-temperature/low-pressure liquid into gas and absorbs heat from the air inside the facility space 120 to lower the temperature of the air inside the facility space 120 to dry the space. Cool air can be supplied to (110).

In connection with the above, the food dryer of the present invention is installed in the facility space 120, installed below the evaporator 400, and water vapor in the air inside the facility space 120 is condensed by the evaporator 400. It is configured to include a collection unit 140 for collecting the collected water, and a drain pump 150 installed in the facility space 120 to discharge the water collected in the collection unit 140 to the outside.

That is, the food dryer of the present invention condenses the water vapor contained in the air inside the facility space 120 and the drying space 110 through the collection unit 140 and the drain pump 150 and discharges it to the outside. As a result, the humidity of the air inside the drying space 110 is lowered so that the food can be dried smoothly.

At this time, the food dryer of the present invention has one side connected to the drain pump 150, the other side installed to surround the indoor condenser 300, and a plurality of indoor spray nozzles ( 220) is provided, while the other end is characterized in that it is configured to include an indoor cooling pipe 210 formed to the outside of the body housing 100.

In addition, in the food dryer of the present invention, water vapor in the air inside the drying space 110 and facility space 120 condensed in the evaporator 400 passes through the drain pump 150 to the surface of the indoor condenser 300. As it is sprayed onto the indoor condenser 300, it is vaporized again by the heat generated in the indoor condenser 300 to cool the indoor condenser 300 to minimize degradation of the indoor condenser 300, and a supply fan (which will be described in detail later) 500) is supplied back to the drying space 110 or is discharged to the outside without being sprayed on the surface of the indoor condenser 300 through the drain pump 150, thereby reducing the humidity of the air inside the drying space 110. The effect that can be adjusted is realized, and the opening and closing of the indoor spray nozzle 220 is performed through the control unit 900 to be described in detail later, so that the humidity of the air inside the drying space 110 can be controlled.

That is, in the food dryer of the present invention, when the humidity of the air inside the drying space 110 is measured through the first temperature and humidity sensor 800 and the controller 900 to be described in detail later, the drain pump maintains a preset humidity. 150 and the indoor spray nozzle 220 are opened and closed so that the humidity of the air inside the drying space 110 is controlled.

The supply fan 500, which is a major component for achieving the present invention,

It is installed in the facility space 120 and is installed in front of the indoor condenser 300 to blow air into the drying space 110, when the refrigerant is circulated through the indoor condenser 300, the drying space 110 ) to supply warm air, and when the refrigerant is circulated to the outdoor condenser 600 to be described in detail later, cool air from the evaporator 400 is supplied to the drying space 110 to dry the food with warm air or cold air. make it possible

In addition, to explain, the evaporator 400, the indoor condenser 300, and the supply fan 500 of the present invention are arranged and installed in series in the facility space 120, and thus cool air or indoor air by the evaporator 400 Warm air from the condenser 300 is supplied to the drying space 110 to dry food, and when warm air or cold air is supplied to the drying space 110, the air inside the drying space 110 is supplied to the facility space ( 120), heat is exchanged, and circulated again, so that food can be dried using the energy contained in the air inside the drying space 110.

At this time, the food dryer of the present invention is installed in the facility space 120 and is configured to include a passage partition wall 130 installed on both sides of the indoor condenser 300 and the evaporator 400, the passage partition wall ( 130), the air inside the facility space 120 heat-exchanged in the evaporator 400 and the air inside the facility space 120 heat-exchanged in the indoor condenser 300 are supplied to the fan 500 to supply warm or cool air to the drying space ( 110) to realize the effect of smoothly supplying.

The outdoor condenser 600, which is a major component for achieving the present invention,

It is installed outside the main housing 100, that is, outside the drying space 110 and the facility space 120, and is installed in a refrigerant pipe (not shown) to which the compressor 200 and the indoor condenser 300 are connected. A branch pipe (not shown) is connected to the compressor 200, and a branch pipe (not shown) installed in a refrigerant pipe (not shown) connecting the evaporator 400 and the indoor condenser 300 to the evaporator 400 and As it is connected, as described above, an expansion valve 700 is installed between the evaporator 400 and sends the low-temperature/high-pressure liquid to the expansion valve 700.

At this time, since the outdoor condenser 600 of the present invention is in contact with the outside of the main housing 100, that is, outdoor air, heat exchange is performed, so it can be said that the energy of the external air is recovered. Accordingly, the food dryer of the present invention recovers the energy of indoor air and outdoor air to dry food, thereby realizing the effect of saving energy.

In addition, in the outdoor condenser 600 of the present invention, as the refrigerant circulates, only heat exchange by the evaporator 400 is performed inside the facility space 120, and cool air is blown in the facility space 120 by the supply fan 500. It is supplied to the drying space 110 so that food can be dried by cold air.

In connection with the above, the food dryer of the present invention is installed so that one side is connected to the drain pump 150 and the other side surrounds the outdoor condenser 600, and the other side faces the outdoor condenser 600. While the injection nozzle 240 is provided, it is characterized in that it is configured to include a cooling pipe 230 provided with a discharge valve 250 that can be opened and closed at the other end.

In more detail, one side of the cooling pipe 230 is connected to the other side of the indoor cooling pipe 210 described above, and when the indoor spray nozzle 220 is not opened, condensation occurs in the evaporator 400 and the collector ( 140) to allow the collected water to be discharged to the outside of the main body housing 100, and to control the opening and closing of the spray nozzle 240 through the control unit 900 to be described in detail later to operate the outdoor condenser 600. allow it to cool.

In other words, in the food dryer of the present invention, water vapor in the air inside the drying space 110 and facility space 120 condensed in the evaporator 400 passes through the drain pump 150 to the surface of the outdoor condenser 600. is vaporized by the heat generated in the outdoor condenser 600 and cools the outdoor condenser 600 to minimize performance deterioration of the indoor condenser 300, and the drying space 110 and facility space (120) The humidity of the air inside the drying space 110 can be adjusted by removing moisture from the inside air.

In addition, when the food dryer of the present invention adjusts the humidity of the air inside the drying space 110, when it is desired to maintain the humidity of the air inside the drying space 110, the control unit 900, which will be described in detail later The drain pump 150 is operated and the indoor spray nozzle 220 of the indoor cooling pipe 210 is opened so that the indoor condenser 300 is cooled and the humidity is maintained at the same time, and the inside of the drying space 110 In case of lowering the air humidity, the drain pump 150 is operated through the control unit 900, and the spray nozzle 240 of the cooling pipe 230 is opened to cool the outdoor condenser 600 and the drying space. (110) and the equipment space (120) to remove moisture from the air inside.

At this time, when the food dryer of the present invention wants to increase the humidity of the air inside the drying space 110, open the outer door 180 of the main housing 100 described above to allow outside air to enter the facility space 120. Humidity can be increased by inflow, and in order to prevent moisture from being discharged to the outside, the indoor spray nozzle 220 is opened and water is sprayed to the indoor condenser 300, so that the drying space 110 and the facility space (120) The humidity of the air inside the drying space 110 and the facility space 120 is controlled by increasing the moisture content of the air inside.

In addition, even if the refrigerant is circulated through the outdoor condenser 600, the controller 900 determines that the performance of the outdoor condenser 600 will not deteriorate due to low external temperature, and the inside of the drying space 110 When the humidity of the air is to be lowered, the discharge valve 250 is opened by the control unit 900, thereby reducing the humidity of the air inside the drying space 110.

The first temperature and humidity sensor 800, which is a main component for achieving the present invention,

It is installed on one side or the other side of the upper surface of the drying space 110, and at least one may be installed. In the case of a plurality of installations, the drying space 110 is an average of the measured values in the controller 900 to be described in detail later. ) The temperature and humidity values are determined, and the control unit 900 compares the temperature and humidity values of the drying space 110 with the preset temperature and humidity values at the time of drying food, and as described above, the drying space ( 110) The temperature and humidity of the inside air can be controlled.

At this time, the first temperature and humidity sensor 800 of the present invention is installed on one or the other side of the upper surface of the drying space 110 or on one or the other side of the lower surface, and is installed at a corner formed on the upper surface of the drying space 110. Preferably, this is measured after the warm air or cold air supplied to the drying space 110 by the supply fan 500 described above is sufficiently convexed in the drying space 110, so that the inside of the drying space 110 is more accurate. This is to ensure that the temperature and humidity of the air can be measured.

The control unit 900, which is a major component for achieving the present invention,

It is installed in the main housing 100 to control the air volume, temperature and humidity of the air supplied into the drying space 110 based on the temperature and humidity measured by the first temperature and humidity sensor 800, as described above. As described above, when the first temperature and humidity sensor 800 is composed of a plurality, the average value of the measured temperature values and average values is determined as the temperature value and humidity value of the air inside the drying space 110, and the determined drying space 110 ) The outdoor condenser 600 or the indoor condenser 300 compares the temperature and humidity values of the internal air with the preset temperature and humidity values when drying food to maintain the preset temperature and humidity values when drying food ), the flow path of the refrigerant pipe is controlled so that the refrigerant can be circulated, and the drain pump 150, the indoor spray nozzle 220, the spray nozzle 240, and the discharge valve 250 are controlled.

That is, the control unit 900 of the present invention controls the flow of the refrigerant so that the refrigerant can be circulated in either the indoor condenser 300 or the outdoor condenser 600 based on the temperature and humidity measured by the first temperature and humidity sensor 800. Controls the temperature of the air inside the drying space 110 and controls the opening and closing of the drain pump 150 and the indoor spray nozzle 220 or spray nozzle 240 to control the humidity of the air inside the drying space 110. do.

In other words, the control unit 900 of the present invention includes a storage unit (not shown) for storing predetermined drying temperatures and humidity for each food item, and the drying space measured through the first temperature and humidity sensor 800 ( 110) Operation of the indoor condenser 300 or outdoor condenser 600 and the indoor spray nozzle 220 according to the circulation of the refrigerant described above so that the temperature and humidity of the internal air can be maintained at the preset drying temperature and humidity for each food. And control of the spray nozzle 240 and the discharge valve 250, and control the supply fan 500.

At this time, the refrigerant pipe or branch pipe connecting the compressor 200, the indoor condenser 300, the outdoor condenser 600, the expansion valve 700, and the evaporator 400 includes the indoor condenser 300 or the outdoor condenser 600. ), a solenoid valve controlled by the controller 900 is installed so that the refrigerant can be selected and circulated.

In addition, the food dryer of the present invention is installed on the outer surface of the main housing 100, and the second temperature and humidity sensor ( 170), the temperature measured by the first temperature and humidity sensor 800 after receiving the temperature and humidity values of the external air measured by the second temperature and humidity sensor 170 from the control unit 900 It is preferable to more efficiently control the opening and closing amount and opening/closing time of the external door 180 as described above by comparing the value and the humidity value.

That is, according to this, the control unit 900 of the present invention enables control to be performed according to the temperature and humidity of the place where the food dryer of the present invention is used, and as a result, allows control to be performed differently for each season, time, and country, so that food In particular, it is possible to save energy by controlling the drying temperature and humidity preset for each food item to be more effectively matched.

In connection with the above, the control of the food dryer of the present invention will be described in more detail below.

First, when drying food using warm air is required, when the drying temperature and humidity for each food item are selected and determined by the user, the temperature and humidity of the air inside the drying space 110 are measured through the first temperature and humidity sensor 800. The information is transmitted to the control unit 900, and the control unit 900 compares the temperature and humidity of the air inside the drying space 110 measured through the first temperature and humidity sensor 800 with the drying temperature and humidity for each food product, so that the temperature rise is required. In this case, the solenoid valve is controlled so that the refrigerant can be circulated from the compressor 200 toward the indoor condenser 300.

Thereafter, heat is generated in the indoor condenser 300 by the circulation of the refrigerant, heat is absorbed in the evaporator 400, and at the same time, water vapor inside the facility space 120 is condensed and collected in the collector 140, and the control unit 900 As the supply fan 500 is controlled by the supply fan 500 and dehumidified warm air is supplied to the drying space 110, the food inside the drying space 110 is dried by the warm air.

At this time, when the humidity of the air inside the drying space 110 needs to be lowered by the first temperature and humidity sensor 800, the drain pump 150 is controlled by the control unit 900 so that the water collected in the collection unit 140 cools the room. It is moved to the cooling pipe 230 through the pipe 210, and the discharge valve 250 is opened by the controller 900 to discharge and remove water to the outside.

On the other hand, when the humidity of the air inside the drying space 110 needs to be increased by the first temperature and humidity sensor 800, the external door 180 provided at the rear of the main body housing 100 is opened by the control unit 900 to allow the outside to pass through. Air is introduced into the facility space 120 and the moisture contained in the external air is condensed through the evaporator 400 and collected in the collector 140, and at the same time the drain pump 150 is controlled by the control unit 900 to collect The water collected in the unit 140 is sucked into the indoor cooling pipe 210, and the indoor spray nozzle 220 is opened by the controller 900, and the water is sprayed to the indoor condenser 300 and evaporated to the outside air. The contained moisture is supplied to the drying space 110 in the form of water vapor to increase the humidity.

In addition, when the humidity of the air inside the drying space 110 needs to be maintained by the first temperature and humidity sensor 800, the drain pump 150 is controlled by the control unit 900 so that the water collected in the collection unit 140 is discharged indoors. It is injected into the indoor condenser 300 through the injection nozzle 220, and the external door 180 remains closed to maintain the humidity of the air inside the drying space 110 and dry the food.

Next, when drying of food using cold air is required, when the drying temperature and humidity for each food item are selected and determined by the user, the temperature and humidity of the air inside the drying space 110 are measured through the first temperature and humidity sensor 800. The control unit 900 compares the temperature and humidity of the air inside the drying space 110 measured through the first temperature and humidity sensor 800 with the drying temperature and humidity for each food product, and the temperature decreases. If necessary, the solenoid valve is controlled so that the refrigerant can be circulated from the compressor 200 toward the outdoor condenser 600.

Thereafter, heat is generated in the outdoor condenser 600 by the circulation of the refrigerant, heat is absorbed in the evaporator 400, and at the same time, water vapor inside the facility space 120 is condensed and collected in the collector 140, and the control unit 900 As the supply fan 500 is controlled by the supply fan 500 and dehumidified cold air is supplied to the drying space 110, the food inside the drying space 110 is dried by the cold air.

At this time, when the humidity of the air inside the drying space 110 needs to be lowered by the first temperature and humidity sensor 800, the drain pump 150 is controlled by the control unit 900 so that the water collected in the collection unit 140 cools the room. It is moved to the cooling pipe 230 through the pipe 210, and the discharge valve 250 is opened by the control unit 900 to discharge and remove the water to the outside, or the water moved to the cooling pipe 230 is the control unit 900 and is sprayed to the outdoor condenser 600 through the spray nozzle 240 opened.

On the other hand, when the humidity of the air inside the drying space 110 needs to be increased by the first temperature and humidity sensor 800, the control unit 900 allows the circulation of the refrigerant to the indoor condenser 300, and the body housing 100 The external door 180 provided at the rear is opened, and external air flows into the facility space 120, and the moisture contained in the external air is condensed through the evaporator 400 and collected in the collection unit 140, and at the same time the control unit The drain pump 150 is controlled by 900, and the water collected in the collector 140 is sucked into the indoor cooling pipe 210, and the indoor spray nozzle 220 is opened by the controller 900 to cool the indoor condenser. As water is sprayed to 300 and evaporated, moisture contained in the external air is supplied to the drying space 110 in the form of water vapor, thereby increasing the humidity.

Thereafter, when the control unit 900 determines that the humidity of the air inside the drying space 110 is appropriate by the first temperature and humidity sensor 800, that is, when it is within the preset humidity and error range, the control unit 900 Again, the circulation of the refrigerant is circulated to the outdoor condenser 600 so that food is dried by cold air.

In addition, when the humidity of the air inside the drying space 110 needs to be maintained by the first temperature and humidity sensor 800, the refrigerant is circulated to the indoor condenser 300 by the controller 900 and simultaneously by the controller 900. The drain pump 150 is controlled so that the water collected in the collector 140 is sprayed to the indoor condenser 300 through the indoor spray nozzle 220, and the outer door 180 remains closed so that the drying space ( 110) After maintaining the humidity of the internal air, the control unit 900 repeats the circulation of the refrigerant to the outdoor condenser 600, so that the preset humidity is adjusted within the error range during drying of food continuously, and the food is stored. can be dried.

In addition, the food dryer of the present invention receives the temperature value and humidity value of the outside air measured by the second temperature and humidity sensor 170 installed on the outer surface of the main housing 100 from the control unit 900, and the outside air enters the outside door The opening and closing amount and opening and closing time of the external door 180 can be smoothly controlled so that the amount introduced through the 180 can be adjusted, so that the temperature and humidity of the air inside the drying space 110 can be more smoothly adjusted to the preset It will be apparent that the drying temperature and humidity can be adjusted for each type of food, and the opening and closing amount and opening and closing time of the external door 180 can be controlled according to preset values according to the temperature and humidity of the outside air.

In connection with the above, the food dryer of the present invention may be configured to include a pressure pump (not shown) installed in the main housing 100 to lower the pressure inside the drying space 110 and the facility space 120, The negative pressure is generated inside the main housing 100, that is, inside the drying space 110 and the facility space 120 by the vacuum pump to prevent odors generated from food from being discharged to the outside, and to reduce negative pressure The air discharged to form is discharged through the outer door 180, but the smell is removed and discharged.

To this end, the external door 180 has a sterilization filter unit 160 installed between the drying space 110 and the facility space 120, so that the air inside the main housing 100 is discharged to the outside. Foreign substances and odors are removed through the filter 162 and the HEPA filter 161 .

At this time, as described above, the external door 180 is also sucked in external air to match the moisture of the air inside the main housing 100, that is, the moisture of the drying space 110. At this time, the HEPA filter 161 Although the installation direction of the air filter 162 is opposite, contaminants such as foreign substances and viruses are removed from the HEPA filter 161 so that food can be dried safely, and auxiliary sterilization is placed at the rear of the HEPA filter 161 After a unit (not shown) is additionally installed to introduce air from the outside, the effect of sterilizing the HEPA filter 161 and increasing the usage period can be obtained.

That is, the sterilizing filter unit 160 installed in the external door 180 includes the HEPA filter 161 installed in the external door 180 formed at the rear of the body housing 100 and the front side of the HEPA filter 161. It is configured to include an air filter 162 installed in the air filter 162, a sterilization unit 163 installed in front of the air filter 162, and an auxiliary sterilization unit installed in the rear of the HEPA filter 161 to realize the above effects. do.

As a result, the heat pump-cooled food dryer of the present invention can save energy by recovering external air energy by installing the indoor condenser 300 and the outdoor condenser 600 inside and outside the main housing 100, respectively. In addition, warm air drying and cold air drying can be selectively performed, and a drying space according to a preset drying temperature and humidity for each food product using the first temperature and humidity sensor 800, the indoor condenser 300, and the outdoor condenser 600 (110) The temperature and humidity of the inside air can be adjusted so that food can be dried more stably and smoothly, and through the second temperature and humidity sensor 170, external air energy can be recovered according to the temperature and humidity of the outside air. By making it happen smoothly, it is possible to obtain an effect of smoothly drying food while saving energy according to characteristics of each country, season, time, and space, that is, temperature and humidity of external air.

The above has been described with reference to preferred embodiments of the present invention, and is not limited to the above embodiments, and to the extent that those skilled in the art in the art to which the present invention belongs through the above embodiments do not deviate from the gist of the present invention. It can be implemented with various changes in .

100: main housing 110: drying space
120: facility space 130: passage bulkhead
140: collection unit 150: drain pump
160: sterilization filter unit 161: HEPA filter
162: air filter 163: sterilization unit
163a: LED chip 163b: ventilation hole
163c: wide-angle lens 163d: base frame
170: second temperature and humidity sensor 180: external door
200: compressor 210: indoor cooling pipe
220: indoor spray nozzle 230: cooling pipe
240: injection nozzle 250: discharge valve
300: indoor condenser 400: evaporator
500: supply fan 600: outdoor condenser
700: expansion valve 800: first temperature and humidity sensor
900: control unit

Claims (10)

A body housing 100 having a drying space 110 where food is dried and a facility space 120 partitioned to communicate with the drying space 110 at the rear of the drying space 110; and
A compressor 200 installed in the facility space 120; and
An indoor condenser 300 installed in front of the facility space 120 and connected to the compressor 200 through a refrigerant pipe;
An evaporator 400 installed in the facility space 120, installed behind the indoor condenser 300, and connected to the indoor condenser 300 through a refrigerant pipe;
A supply fan 500 installed in the facility space 120 and installed in front of the indoor condenser 300 to blow air into the drying space 110;
It is installed on the outside of the main housing 100 and is connected to the compressor 200 through a branch pipe installed in a refrigerant pipe to which the compressor 200 and the indoor condenser 300 are connected. An outdoor condenser 600 connected to the evaporator 400 through a branch pipe installed in the refrigerant pipe connecting the indoor condenser 300;
An expansion valve 700 installed in a refrigerant pipe connecting the evaporator 400 and the indoor condenser 300 and installed between the branch pipe connected to the outdoor condenser 600 and the evaporator 400;
at least one first temperature and humidity sensor 800 installed on one side or the other side of the upper surface of the drying space 110; and
A control unit 900 installed in the body housing 100 to control the air volume, temperature and humidity of the air supplied into the drying space 110 based on the temperature and humidity measured by the first temperature and humidity sensor 800 A heat pump-cooled food dryer characterized in that it is configured to include;
According to claim 1,
The controller 900 is
Based on the temperature and humidity measured by the first temperature and humidity sensor 800, the heat pump cooled food dryer characterized in that the control so that the refrigerant is circulated in either the indoor condenser 300 or the outdoor condenser 600 .
According to claim 2,
The heat pump cooling food dryer
Heat pump cooling type food dryer, characterized in that it is configured to include a flow path partition wall 130 installed in the facility space 120 and installed on both sides of the indoor condenser 300 and the evaporator 400.
According to claim 3,
The heat pump cooling food dryer
Doedoe installed in the facility space 120, the collection unit 140 installed below the evaporator 400; and
Heat pump cooling type food dryer, characterized in that it is configured to include; drain pump 150 installed in the facility space 120 to discharge the water collected in the collection unit 140 to the outside.
According to claim 4,
The heat pump cooling food dryer
One side is connected to the drain pump 150, the other side is installed to surround the outdoor condenser 600, and a plurality of injection nozzles 240 are provided on the other side to face the outdoor condenser 600, while the other side It is configured to include; a cooling pipe 230 equipped with a discharge valve 250 that can be opened and closed at the end,
The injection nozzle 240 is
A heat pump cooling food dryer, characterized in that it can be opened and closed by the control unit 900.
According to claim 5,
The controller 900 is
When the refrigerant is circulated through the indoor condenser 300, the discharge valve 250 is controlled to be opened,
Heat pump cooling type food dryer, characterized in that when controlling the circulation of the refrigerant to the outdoor condenser (600), the injection nozzle (240) is controlled to be opened.
According to claim 6,
The heat pump cooling food dryer
It is installed between the drying space 110 and the facility space 120, and is installed in a place where air is not blown by the supply fan 500. Heat pump cooled food dryer.
According to claim 7,
The sterilization filter unit 160
HEPA filter 161; and
an air filter 162 installed in front of the HEPA filter 161; and
A heat pump cooling type food dryer, characterized in that it is configured to include; a sterilization unit 163 installed in front of the air filter 162.
According to claim 8,
The sterilization unit 163
A plurality of LED chips (163a) installed on the rear side to irradiate ultraviolet rays; heat pump cooling type food dryer characterized in that it is configured to include.
According to claim 9,
The sterilization unit 163
A wide-angle lens 163c installed outside the LED chip 163a to surround the LED chip 163a;
Heat pump cooling type food dryer, characterized in that it is configured to include; a plurality of ventilation holes (163b) formed through the LED chip (163a) is not installed.

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