KR101381195B1 - Continuous farm product dryer using heat pump system - Google Patents

Abstract

The present invention relates to a continuous agricultural product dryer using a heat pump system, a plurality of conveyor transfer unit is arranged in a row to move the drying cart carrying the dry matter, one end is the input portion and the other end is the discharge portion; It is composed of a plurality of drying chambers are provided on each of the plurality of conveyor moving parts between the input and discharge parts formed with a moving passage for moving the drying cart, one of each of the plurality of drying chambers of the plurality of drying chambers is provided with a refrigerant A heat pump system for supplying condensation heat to one drying chamber and latent heat of evaporation to the other drying chamber for circulation while drying; A thermostirrer which is installed in each of the two sets of drying chambers in which the hip pump system is installed so that air is stirred between the drying chambers; And a plurality of blowers installed on top of each of the plurality of drying chambers, so that drying of the to-be-dried material is efficiently performed, thereby improving drying quality and reducing drying costs.

Description

Continuous agricultural product dryer using heat pump system {CONTINUOUS FARM PRODUCT DRYER USING HEAT PUMP SYSTEM}

The present invention relates to a continuous agricultural product dryer using a heat pump system, and in detail, there is an input unit and an outlet unit on a plurality of conveyor transfer unit for transporting the goods, and on the plurality of conveyor transfer unit between the input unit and the discharge unit Each of the plurality of drying chambers is installed to constitute a dryer, and one heat pump system and a heat stirrer are installed in each of the plurality of drying chambers, and a plurality of blowers are installed in each of the plurality of drying chambers, thereby providing the heat pump system. The present invention relates to a continuous agricultural product dryer using a heat pump system in which drying cost is reduced and drying quality is improved by efficient use of heat by a heat stirring device.

Naturally produced aquatic products or products made in industrial processes necessarily contain a certain amount of water, and it is called drying to reduce the moisture content by controlling the water content to be a good condition to use. The drying process is widely used in the production process of all industries such as food, chemical, textile, ceramics, paper, wood, metal parts and waste, and is almost essential in the final dry product, processing, post-treatment and transportation process.

Dryers used in this drying process is mainly in the form of direct or indirect energy input such as fuel, hot air, steam, electric and electromagnetic waves, artificial light, so far, hot air dryer, far-infrared dryer, microwave dryer, dehumidifying dryer, vacuum There are various types of dryers that are used for practical drying, such as dryers, freeze dryers, dehumidifying dryers and vented dryers. Due to the nature of drying, these dryers are process equipments that consume a lot of energy, and industrial equipment with high energy saving expectations is expected. About 30% of the annual energy consumption of the drying equipment owners in the industrial sector is consumed in the drying process, and the energy cost of drying in Korea consumes enormous energy amounting to about 300 billion of duty-free oil.

However, the excessive energy consumption by the dryer, as a result of rising energy costs in the era of high oil prices, has severely hampered productivity and caused environmental problems such as reduced profits and air pollution caused by the use of fossil energy. Therefore, the development of highly efficient dryers should be actively reviewed.

If you supply a dryer that improves the drying efficiency by 30-50% or more than the general-purpose methods of the above-mentioned dryers, the energy saving cost can be reduced by 100 billion won. As a result, national revenues are increased by savings, and as the usage decreases, annual greenhouse gas emissions of 1 million tons of carbon dioxide are reduced.

(Previous Document 1) Korean Patent Publication No. 10-2010-0037772 (Previous Document 2) Korean Patent Publication No. 10-2011-0022334

The present invention has been made to improve the above-mentioned problems, the object of which is a plurality of conveyor conveying unit having the input and discharge of the object, a plurality of each installed on the conveyor transport between the input and discharge part Two drying chambers, a heat pump system and a heat stirrer, each of which is installed for each of the two drying chambers, and each conveyor conveying unit is configured by efficiently using heat supplied while the refrigerant is circulated by the heat pump system and the thermal stirrer. It is to provide a continuous agricultural product dryer using a heat pump system through which the dry items passing through each of the plurality of drying chambers are efficiently dried, the drying efficiency of the dry items can be increased and the drying cost can be reduced.

Another purpose is to prevent air movement between each drying chamber by the arched silicon pads installed at the front and the rear of each low water chamber to maintain airtightness, and to install perforated plates on both inner wall surfaces of each drying chamber between the arched silicon pads. It is to provide a continuous agricultural product dryer using a heat pump system to facilitate the movement of air in each drying chamber.

Continuous agricultural product dryer using the heat pump system of the present invention to achieve the object as described above, is arranged in a row to move the drying cart carrying the goods, one end is the input portion and the other end is the discharge portion It consists of a plurality of conveyor transfer unit, and a plurality of drying chambers are formed on each of the plurality of conveyor moving parts between the input unit and the discharge unit is formed a moving passage for moving the drying cart, two of the plurality of drying chambers A heat pump system for supplying condensation heat to one drying chamber and latent heat of evaporation to the other drying chamber for drying the dry goods while one refrigerant is circulated; A thermostirrer which is installed in each of the two sets of drying chambers in which the hip pump system is installed so that air is stirred between the drying chambers; And a plurality of blowers provided on an upper portion of each of the plurality of drying chambers.

In addition, the heat pump system is composed of a refrigerant line to move the refrigerant by connecting between the compressor, the condenser, the evaporator, the expansion valve and the compressor to the expansion valve, it is preferable to repeat the condensation and evaporation of the refrigerant.

The heat stirrer is provided with a suction damper, an exhaust damper and a stirring damper respectively on a drawing leading from one drying chamber to the other drying chamber, and the suction damper and the exhaust damper are provided with suction ducts and exhaust ducts extending from the respective drying chambers. Each is connected, it is preferable to connect between the suction duct and the exhaust duct with a stirring duct.

In addition, each of the plurality of conveyor transfer unit, the base frame; A conveyor motor installed at one side of the base frame; And a chain conveyor installed on the base frame and rotating in a chain connected to the motor shaft of the conveyor motor.

In addition, it is preferable to further include a safety switch which is respectively provided at both ends of the base frame in which the chain conveyor is installed so as to limit the transfer of the drying cart to be transported on the chain conveyor.

In addition, an arc-shaped silicon pad is attached to the upper and both inner wall surfaces of the front and rear of each interior of the drying chamber, which are the drying cart movement passages of the drying chamber, so as to be in close contact with the upper and both sides of the drying cart, respectively. It is preferable to maintain the perforations, and perforated plates are installed on both inner wall surfaces of the interior of the drying chamber between the arcuate silicon pads so that blower air can be uniformly supplied in the drying chamber.

According to the continuous agricultural product dryer using the heat pump system of the present invention, by using the internal heat source of the dryer, there is an effect of enabling a high-temperature drying of about 60 ° C.

In addition, there is an effect that the drying cost is reduced by the efficient use of heat by heat exchange inside the drying chamber by the heat pump system and heat stirring by the heat stirring device.

In addition, since the dryer is not exposed to high temperature for a long time by repeated operation of the warm drying by the condenser and the cooling dehumidifying drying by the evaporator of the heat pump system, the drying quality of the dried product is improved.

1 is a schematic overall side view of a continuous agricultural product dryer using a heat pump system according to the present invention
2 is a side view and a front view of a drying chamber of a continuous agricultural product dryer using a heat pump system according to the present invention.
3 is a schematic installation diagram of a heat pump system of a continuous agricultural product dryer using a heat pump system according to the present invention;
4 is a schematic installation diagram of a thermal stirring apparatus for a continuous agricultural product dryer using a heat pump system according to the present invention
Figure 5a is a side cross-sectional view and a cross-sectional view of the AA line longitudinal section of the drying chamber of the continuous agricultural product dryer using a heat pump system according to the present invention from one side
Figure 5b is a side cross-sectional view of the drying chamber of the continuous agricultural product dryer using the heat pump system according to the present invention from the other side and BB longitudinal cross-sectional view of the cross-sectional view
6 is a conceptual diagram showing the heat exhaust relationship of the continuous agricultural product dryer using a heat pump system according to the present invention
7 is a conceptual diagram showing the heat and air stirring relationship of the continuous agricultural product dryer using a heat pump system according to the present invention
8 is a conceptual diagram showing the heat agitation and exhaust relationship of the continuous agricultural product dryer using a heat pump system according to the present invention

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the continuous agricultural product dryer using a heat pump system according to the present invention will be described in detail. It is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to inform.

1 is a schematic overall side view of a continuous agricultural product dryer using a heat pump system according to the present invention, Figure 2 is a side view and a front view of a drying chamber of the continuous agricultural product dryer using a heat pump system according to the present invention. It is shown.

As shown in FIG. 1 and FIG. 2, the present invention basically forms the basic structure of the conveyor conveyance unit 1, the drying chamber 2, the heat pump system 3, the heat stirrer 4, and the blower 5. do.

The conveyor conveying unit 1 is arranged in a plurality of lines arranged so as to face each other in close proximity, each consisting of a base frame (6), a conveyor motor (7) and a chain conveyor (8).

That is, when the base frame 6 is installed, the conveyor motor 7 is installed on one side of the base frame 7, and the motor shaft of the conveyor motor 7 is connected to each other so that the chain is connected to the upper part of the base frame 6. It is connected through the chain conveyor 8 and the bearing 9 which were wound up, and when the conveyor motor 7 is rotated, the chain conveyor 8 also rotates. When the chain conveyor 8 rotates in this way, the drying cart 10 thereon moves from one side of the conveyor conveying part 1 to the other.

In the drying cart 10, it is possible to load a drying box for accommodating the dry goods as needed.

On the other hand, when the drying cart 10 moves on the conveyor 1, safety switches 22 which are limit switches are respectively provided at both ends of the base frame 6 on which the chain conveyor 8 is wound. By 22, the drying cart 10 is limited to movement.

The front conveyor conveying part 1a of the plurality of conveyor conveying parts 1 becomes the input part of the drying cart 10 in which the dry object to start drying is accommodated, and the rear conveyer conveying part 1b is the drying completed. It becomes the discharge part of the drying cart 10 in which the to-be-built thing is accommodated.

The drying chamber (2) is installed on each conveyor transfer section (1c) between the front and rear conveyor transfer section (1a) (1b) that is the input and discharge unit, the drying cart just above each conveyor transfer section (1c) below A moving passage 10a through which 10 passes is formed.

The heat pump system 3 is installed by connecting the two drying chambers at the top of each of the two drying chambers arranged side by side among the plurality of drying chambers 2, as shown in FIG. 3. When the compressor 11, the condenser 12, the evaporator 13 and the expansion valve 14 is composed of a refrigerant line between the compressor 11, the condenser 12, the evaporator 13 and the expansion valve 14 Are connected to each other. However, on the refrigerant line going from the condenser 12 to the evaporator 13 of the heat pump system 3 used in the agricultural product dryer of the present invention and the refrigerant line going from the expansion valve 14 to the compressor 11, heat stirring described later. The apparatus 4 is provided, respectively.

The heat pump system is operated through a Carnot cycle of compression → condensation → expansion → evaporation process, and the refrigerant introduced from the outlet of the evaporator 13 compresses the refrigerant having a low temperature and low pressure through the compressor 11 to high temperature and high pressure. Refrigerant is condensed to the subcooling area while passing through the condenser 12 (heat dissipation), and the condensation energy is dried by heating the dry matter in the drying chambers 2a, 2c, and 2e on one side every two drying chambers. The refrigerant is expanded at low temperature and low pressure by the expansion valve 14 to be introduced into the evaporator 13, and the evaporator 13 performs an evaporation process (absorption) in the other drying chambers 2b, 2d, and 2f every two drying chambers. It is a cycle of repeating the process of cooling and dehumidifying and drying the dry items.

The thermal stirrer 4 is a device for efficiently drying by stirring the heat sources generated in the heat pump system with each other in the drying chamber 3. As shown in FIG. 4, one drying chamber 2a of two drying chambers is illustrated. The suction damper 15a, the stirring damper 16a, and the exhaust damper 17a are installed side by side on the island leading to the other drying chamber 2b from the side, and the suction damper 15a, the stirring damper 16b, and the exhaust damper ( Stirring ducts 18a leading to the respective drying chambers 2a and 2b are provided while connecting 17c with each other. In addition, an exhaust damper 17b, an agitation damper 16b, and a suction damper 15b are disposed side by side in a phase leading from the one drying chamber 2a to the other drying chamber 2b of the two drying chambers. Stirring ducts 18b leading to each of the drying chambers 2a and 2b are provided while connecting 17b), the stirring damper 16b, and the suction damper 15b to each other. Looking at the connection in detail, an exhaust duct 24a connected to the exhaust damper 17a from the drying chamber 2b is installed, and the exhaust duct 24a is connected to the stirring duct 18a and the stirring duct 18a. Is again connected to the suction duct 23a from the suction damper 15a to the drying chamber 2a. In addition, an exhaust duct 24b connected to the exhaust damper 17b from the drying chamber 2a is installed, the exhaust duct 24b is connected to the stirring duct 18b, and the stirring duct 18b is again a suction damper. It is connected with the suction duct 23b which leads from 15b to the drying chamber 2b.

The blower 5 is installed in the plurality of drying chambers 2 in the plurality of drying chambers 2, respectively, each one, and serves to circulate the air to evenly distribute the air in the drying chamber (2) for drying the dry matter. Done.

5A is a side cross-sectional view and a cross-sectional view taken along line AA of the cross-sectional view of a drying chamber of a continuous agricultural product dryer using a heat pump system according to the present invention, and FIG. 5B is a continuous agricultural product dryer using a heat pump system according to the present invention. The cross-sectional side view and the BB line longitudinal cross-sectional view of the said cross section which looked at the drying chamber of other side are shown.

As shown in FIGS. 5A and 5B, an arc-shaped silicon formed by stacking a plurality of soft silicon pads on the upper and both inner wall surfaces of the front and rear of each interior of the drying chamber, which are the moving passages 10a of the plurality of drying chambers 2. The pads 19 are attached to each other so that when the drying cart 10 arrives in position in the drying chamber 2, the upper and both sides of the front and rear sides of the drying cart 10 closely adhere to the arcuate silicon pad 19. Thus, the drying cart 10 is to maintain the airtight between the drying chamber and both drying chamber in the correct position.

In addition, the inner periphery of each of the drying chambers between the arcuate silicon pads 19 is attached to the perforated plate 20 through which a number of holes h are drilled, respectively, through the holes H perforated in the perforated plate 20. The blower air should pass through and evenly supplied into the drying chamber. That is, as shown in FIG. 5A and FIG. 5B, the air flow is indicated by an arrow, and the perforated plate 20 has a structure in which the blower 5 circulates air into the drying chamber, and the blower air is formed on both inner walls of the drying chamber 2 and the perforated plate. Guided to the air passage (duct) formed between the (20) is supplied into the drying chamber (2) through a hole (h) perforated in the perforated plate 20 to form a uniform air flow, and supplied into the drying chamber (2) The air is returned to the blower 5 through the return air passage 21.

Next will be described the operation of the continuous agricultural product dryer using the heat pump system of the present invention configured as described above.

In the dryer system of the present invention, the heat pump may maximize energy efficiency through alternation. By simultaneously implementing “heated COP in condenser” and “dehumidification COP in evaporator”, not only energy efficiency but also the drying quality of the dried product can be improved by maintaining the dry environmental conditions where the dryer is not exposed to high temperature for a long time by alternating operation. .

1) Heating COP: When the refrigerant (R134a) condenses in the condenser, the enthalpy of the refrigerant drops. At this time, the enthalpy dropped is used to heat the air circulating in one of the two drying chambers, and this heated heat is used as energy for drying the dry matter.

2) Dehumidification COP: When the refrigerant moves from one drying room to another drying room and the refrigerant (R134a) evaporates in the evaporator, the circulating air is lowered as much as the enthalpy from which the refrigerant is raised, and the circulating air is lowered below the dew point temperature. Absolute humidity drops and dehumidifies.

As described above, the temperature rise through the heating of one drying chamber and the dehumidification through the cooling of the other drying chamber are alternately repeated (alternatively) in the two drying chambers, thereby heating COP " + " dehumidifying COP in the evaporator " It can be implemented at the same time.

In one drying chamber in which a condenser is used, the temperature of the blown air is raised to increase the water diffusion of the dry items and lower the relative humidity of the blown air. At this time, when blown air having a relatively low humidity passes through one of the drying chambers, the dried material is dried by evaporating moisture from the dried product, and the blown air having a higher relative humidity drops the relative humidity of the blown air through exhaust or heat stirring. Drop.

In the other drying chamber in which the evaporator is used, the blower air passing through the one drying chamber passes through the evaporator and the temperature decreases, so that the relative humidity increases. At this time, the wet air dropped below the dew point temperature is dehumidified by water, and the absolute humidity is lowered as the dehumidified water. The dehumidified air falls in relative humidity through heat stirring or exhaust. Blowing air, whose relative humidity has fallen, is transferred to one drying chamber for drying.

The distribution and flow of air is very important in drying. Uneven distribution and flow of air leads to a lot of uneven drying. Therefore, in order to prevent non-uniform drying, the distribution and flow of air should be smooth and even. To this end, the perforated plate 20 is used as described above to uniformly distribute the blowing air into the drying chamber.

As described above, in the continuous agricultural product dryer of the present invention, it is important to exhaust or stir the air heat source circulated by the heat pump for drying the dried product, and the following describes the relationship between the exhaust and the stirring of the air heat source.

6 is a conceptual diagram showing the heat exhaust relationship of the continuous agricultural product dryer using a heat pump system according to the present invention.

As shown in Fig. 6, forcibly discharging the circulating air supersaturated by the artificial operation in the drying chambers 2a and 2b of the continuous agricultural product dryer of the present invention is called exhaust. Exhaust can be seen in two aspects:

  One of them is a circulation air containing moisture discharged from a dry matter or a dehumidified circulating air dehumidified in an evaporator while the air heat source circulates in the drying chambers 2a and 2b on the conveyor conveying section 1 of the dryer, thereby increasing the relative humidity. Repeatedly this results in supersaturated air or near supersaturation. Even if such air is circulated again in the drying chamber, it cannot contain water vapor. At this time, the suction dampers 15a and 15b of the thermal stirrer 4 are opened to suck the outside air through the suction ducts 23a and 23b and the stirring duct 18a and saturated steam using the pressure difference of the blower 5. The exhaust dampers 17a and 17b are opened to force exhaust through the exhaust ducts 24a and 24b and the stirring duct 18b.

The other can be explained in the following heat pump cycle.

Heat of condensation = q + A _ω

Heat of evaporation = q

(Where A _ω is the work of the compressor), so the heat of condensation is always greater than the heat of evaporation.

Therefore, the heat of condensation must be discharged by the compressor for one day. This is done in part in the process of exhaust, and in part in the thermal agitation described below.

Figure 7 shows a conceptual diagram showing the heat stirring and air stirring relationship of the continuous agricultural product dryer using a heat pump system according to the present invention.

As shown in FIG. 7, the heat of one drying chamber 2a of the conveyor conveying unit 1 of the continuous agricultural product dryer of the present invention is heated to the other drying chamber 2b, and the medium air is returned to the original drying chamber ( The drying method back to 2a) is called thermal stirring.

Thermal stirring can be seen in two aspects: the drying chamber 2a on the warming side and the drying chamber 2b on the dehumidifying side.

The drying chamber 2b on the dehumidification side is dried while the air is cooled and dehumidified in the evaporator, and the air after the dehumidification has a low temperature even though the air is circulated through the drying chamber, so the absolute humidity is insufficient. In order to solve this problem, the high temperature heat of the drying chamber 2a on the condensation side is transferred using the stirring dampers 16a, 16b, the stirring ducts 18a, 18b, and the blower 5 of the heat stirring apparatus 4. When the thermal stirring, the absolute humidity is increased to enter the drying chamber (2a), it is very helpful to evaporate the moisture from the dry matter. Another reason for thermal stirring in the drying chamber 2b on the dehumidifying side is that the temperature of the drying chamber 2b on the dehumidifying side becomes lower gradually with time because the evaporator rotates. At this time, to compensate by heat stirring.

As described in the exhaust relationship of the heat source, the drying chamber 2a on the condensation side should discharge a certain amount of heat, which is efficiently received by the drying chamber 2b on the dehumidification side.

Next, looking at the heat stirring in the drying chamber (2a) of the condensation side, it is more efficient in terms of energy saving to circulate the heat to be discharged from the drying chamber (2a) of the condensation side through heat stirring than to discharge to the exhaust. The reason is that when exhausting, exhausting air with high saturation or relative humidity is efficient for drying, but it is necessary to apply a corresponding heat to the temperature at which the low temperature outside air enters.

8 is a conceptual diagram showing the heat agitation and exhaust relationship of the continuous agricultural product dryer using a heat pump system according to the present invention.

As shown in FIG. 8, in the continuous agricultural product dryer of the present invention, each drying chamber 2 is designed so that exhaust and heat stirring can be performed separately. In other words, it can be exhausted only, thermal stirring only, and the thermal stirring and the exhaust can be carried out at the same time. This can be carried out separately from the drying chamber 2a on the condensation side and the drying chamber 2b on the dehumidifying side. When performing the operation, a mode favorable for drying is selected to operate in a controlled manner.

The thermal stirring is carried out in the passage above the one drying chamber 2a through the stirring damper 16a, and in the thermal stirring device 4 above the other drying chamber 2b, and then again via the thermal stirring exhaust damper 17a. It returns to one drying chamber 2a of the. Exhaust can be carried out in two modes, which can be operated as an external exhaust that falls directly into the outside air without undergoing thermal stirring and a thermal stirring exhaust that passes through the thermal stirring and discharges to the outside air.

When the exhaust air comes in through the suction duct 23a and the stirring duct 18a by opening the suction damper 15a, some circulating air flows into the upper passage of one drying chamber 2a by the pressure difference of the blower 5, At this time, the exhaust damper 17b is opened to be immediately discharged to the outside through the exhaust duct 24b and the stirring duct 18b. In addition, when the exhaust gas is exhausted from the drying chamber 2b on the dehumidification side, the exhaust gas is directly exhausted because the temperature of the drying chamber 2a on the condensation side is dropped when heat stirring.

Another method of exhaustion is heat stirring exhaust, which means that when the suction damper 15a is opened, some circulating air is moved to the upper passage of one drying chamber 2a by the pressure difference of the blower 5, and one drying chamber 2a after heat stirring. By closing the agitation damper (16a) of the), it is a method of exhausting to the outside without returning to the original one drying chamber 2a. This method requires exhausting when the relative humidity of the condensation-side drying chamber 2a is increased and heat stirring, but when the relative humidity drops. The heat is supplied to the drying chamber 2b on the dehumidifying side to dry the drying chamber 2b on the dehumidifying side. Use to help and evacuate.

As described above with reference to the drawings illustrating a continuous agricultural product dryer using a heat pump system according to the present invention, the present invention is not limited by the embodiments and drawings disclosed herein, the description of the present invention Of course, various modifications may be made by those skilled in the art within the scope of the idea.

1,1a, 1b, 1c: Conveyor conveying part 2,2a, 2b, 2c, 2d, 2e, 2f: Drying chamber
3: heat pump system 4: heat stirring device
5: blower 6: base frame
7: conveyor motor 8: chain conveyor
9: bearing 10: drying cart
10a: movement passage 11: compressor
12 condenser 13 evaporator
14: expansion valve 15a, 15b: suction damper
16a, 16b: Agitated damper 17a, 17b: Exhaust damper
18a, 18b: stirring duct 19: arched silicon pad
20: punched plate 21: return air passage
22: safety switch 23a, 23b: suction duct
24a, 24b: exhaust duct h: hole

Claims (7)

On a plurality of conveyor conveyances arranged in a row to move the drying carts carrying the goods, one end being an input and the other end being an outlet, and a plurality of each conveyor transport between the input and the discharge Each of them consists of a plurality of drying chambers are provided with a moving passage through which the drying cart is moved,
A heat pump system in which one of two drying chambers of the plurality of drying chambers is installed to supply the condensation heat to one drying chamber and the latent heat of evaporation to the other drying chamber for drying the dry goods while the refrigerant circulates;
A thermostirrer which is installed in each of the two sets of drying chambers in which the hip pump system is installed so that air is stirred between the drying chambers; And
Includes; a plurality of blowers installed on top of each of the plurality of drying chambers,
The thermostirrer is provided with a suction damper, an exhaust damper and a stirring damper respectively on a drawing leading from one drying chamber to the other drying chamber, and the suction damper and the exhaust damper are respectively connected to the suction duct and the exhaust duct from each drying chamber. The continuous agricultural product dryer using the heat pump system, characterized in that the connection between the suction duct and the exhaust duct with a stirring duct. The method of claim 1,
The heat pump system includes a compressor, a condenser, an evaporator, an expansion valve, and a refrigerant line configured to move the refrigerant by connecting the compressor to the expansion valve, so that the condensation and evaporation of the refrigerant is repeated. Continuous product dryer using the system. delete The method of claim 1,
A plurality of each conveyor transfer unit,
A base frame;
A conveyor motor installed at one side of the base frame; And
A chain conveyor installed on the base frame and rotating in a chain connected to a motor shaft of a conveyor motor;
Each made of a continuous agricultural product dryer using a heat pump system, characterized in that for transporting the dry matter loaded in the drying cart. 5. The method of claim 4,
And a safety switch installed at each end of each of the base frames on which the chain conveyor is installed, to limit the transfer of the drying cart being transported on the chain conveyor. The method according to any one of claims 1, 2, 4, and 5,
An arc-shaped silicon pad is attached to the upper and both inner wall surfaces of the front and rear of each interior of the drying chamber, which are the drying cart moving passages of the drying chamber, so as to be in close contact with the upper and both sides of the drying cart to maintain the airtightness between the drying chambers. Continuous agricultural products using a heat pump system, characterized in that to make. The method according to claim 6,
Perforated plates are respectively installed on both inner wall surfaces of the interior of the drying chamber between the arcuate silicon pads so that blower air can be uniformly supplied to the drying chamber.

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