KR101592991B1 - Recycling apparatus for useless and high humidity heat and recycled dry air supply system - Google Patents

Abstract

Disclosed are a high humidity waste heat recycling apparatus which can change high humidity waste heat, used by a dryer, into dry air at high temperatures at the minimum costs and a recycled dry-air supply system which can minimize time and energy for drying by recycling high humidity waste heat used by the dryer by using the high humidity waste heat recycling apparatus. The high humidity waste heat recycling apparatus includes an air change unit and a refrigerant change unit. The recycled dry-air supply system includes the high humidity waste heat recycling apparatus, a drying apparatus, and a circulation pipe.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a recycling apparatus for recycling high-

The present invention relates to a high-humidity waste heat recycling apparatus, and more particularly, to a high-humidity waste heat recycling apparatus capable of drying and converting high-humidity waste heat used in a dryer at a minimum cost into high-temperature air.

The Korean agricultural economy under the Free Trade Agreement (FTA) system is in trouble because of the rising cost of international oil prices and rising costs of agricultural materials. In addition, the aging of the agriculture population causes the problem of quality deterioration of agricultural products as well as long-term storage of hard-to-produce agricultural products. Among the various methods of storing agricultural products for a long period of time, general farmers prefer to use a dryer because it is not complicated to store after drying.

In order to dry agricultural products using high temperature and dry air, a dryer is essentially used. The dryer to be used may be an electric dryer, a hybrid dryer using a heat pump, a cold air dehumidifying dryer using a cold air, and a oil dryer. All of them use a considerable amount of fossil fuel to convert the external air into high temperature and low humidity air, and then apply it to the dryer. The high temperature air used for drying is simply blown into the air, It is generated using outside air.

Recently, it is required to develop a fuel saving type dryer that can minimize the amount of fossil fuel used from the viewpoint of the nation that manages the total amount of greenhouse gas.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a high-humidity waste heat recycling apparatus capable of converting high-humidity waste heat used in a dryer into dry high-temperature air at a minimum cost.

Another object of the present invention is to provide a recycled dry air supply system capable of minimizing the time required for drying and energy consumed in drying by recycling the high-humidity waste heat used in the dryer using the high-humidity waste heat recycling apparatus It is on.

According to an aspect of the present invention, there is provided an apparatus for recycling high-humidity waste heat comprising an air conversion unit and a refrigerant conversion unit. The air conversion unit includes at least one cooler for removing moisture contained in the high-humidity waste heat and a condenser for raising the temperature of the high-humidity waste heat. The high-temperature waste heat passing through the cooler and the condenser is converted into hot and dry air. The refrigerant conversion unit compresses the refrigerant discharged from the cooler to a high temperature and transfers the refrigerant to the condenser, and the refrigerant discharged from the condenser is cooled and transferred to the cooler.

According to another aspect of the present invention, there is provided a recycled dry air supply system including the high-humidity waste heat recycling apparatus, the drying apparatus, the circulation pipe, and the apparatus for regulating the flow rate of high-temperature waste heat. The recycling apparatus is as set forth in claim 5. The drying apparatus includes a drying chamber for drying the object to be dried, a heating device for heating the introduced air, and an air inflow device for forcibly introducing the air into the heating device. The circulation pipe delivers the high-humidity waste heat discharged from the drying apparatus to the high-humidity waste heat recycling apparatus, and circulates the high-temperature and low-moisture air discharged from the high-humidity waste heat recycling apparatus to the drying apparatus. The high-humidity waste heat inflow amount adjustment device is installed in a circulation pipe between the drying device and the high-humidity waste heat recycling device to regulate the amount of high-humidity waste heat that moves from the drying device to the high-humidity waste heat recycling device.

The high-humidity waste heat recycling apparatus and the recycled dry air supply system according to the present invention have an advantage that dry air used for removing moisture generated from a drying object can be generated with minimum energy.

1 shows an embodiment of a recycled dry air supply system to which a high-humidity waste heat recycling apparatus according to the present invention is applied.
2 is a conceptual diagram of a high-humidity waste heat recycling apparatus according to the present invention.
3 is a block diagram of the refrigerant conversion unit shown in FIG.
Fig. 4 shows a photograph of the construction and embodiment of three condensers and one cooler.

In order to fully understand the present invention and the operational advantages of the present invention and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings, which are provided for explaining exemplary embodiments of the present invention, and the contents of the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference symbols in the drawings denote like elements.

1 shows an embodiment of a recycled dry air supply system to which a high-humidity waste heat recycling apparatus according to the present invention is applied.

Referring to FIG. 1, the recycled dry air supply system 100 includes a high-humidity waste heat recycling apparatus 110 mounted on a conventional drying apparatus 120.

One of the key ideas of the present invention is the high-temperature waste heat recycling apparatus 110, which is an embodiment of the recycling dry air supply system 100 according to the present invention shown in FIG. 1, It is possible that the embodiment is converted and used independently. For convenience of explanation, the conventional drying apparatus 120 described below is assumed to be used for drying the agricultural product, but it is also possible to use the drying apparatus 120 for drying various articles other than agricultural products.

The conventional drying apparatus 120 is implemented with a drying chamber 121, an air inlet 122 for sucking outside air, and a heating unit 123 for heating the introduced outside air. In the present invention, the natural law that the heated air can contain more moisture than the unheated air, that is, the experimentally confirmed natural law about the temperature of the air and the amount of water that the air can contain do. The air heated by the heating device 123 (solid line) is forced into the drying chamber 121 by the suction force of the air introducer 122. Here, a blower may be used as the air inlet 122. The conventional dryer does not utilize the high-humidity waste heat by releasing the high-humidity waste heat (dotted line) passing through the drying chamber 121 directly to the outside.

The high-moisture waste heat recycling apparatus 110 according to the present invention converts high-temperature waste heat (circulating air, dotted line) that is discharged from the drying chamber 121 and flows through the circulation pipe 130 into hot-dried air (gothic line) And sent to the drying chamber 121 through the air inlet 122, so that the high-humidity waste heat can be recycled.

The recycled dry air supply system 100 according to the present invention may be used in combination with the air (dash-dotted line) flowing into the external air inflow device 140 as shown in FIG. 1, An embodiment in which only the recycling apparatus 110 is used to generate hot and dry air will be possible. Since the temperature of the air introduced into the heating device 123 through the air inlet 122 is higher than that of the outside air and the humidity is lower than that of the outside air, no matter which embodiment is selected, It is easy to see that fossil fuels can be minimized.

If the amount of high-humidity waste heat discharged from the conventional drying apparatus 120 is excessive, if the high-humidity waste heat recycling apparatus 110 recycles all the excessive amount of high-humidity waste heat, the power consumption efficiency and the recycling efficiency of the high- May occur. In order to solve such a problem, the recycled dry air supply system 100 according to the present invention is provided with a high-temperature waste heat inflow amount adjustment device (hereinafter referred to as " high-humidity waste heat inflow amount adjustment device ") in a circulation pipe 130 connecting the existing drying device 120 and the high- 150) should be applied.

The high-humidity waste heat inflow amount adjustment device 150 causes all the high-humidity waste heat discharged from the conventional drying device 120 to flow into the high-humidity waste heat recycling device 110, or a part of the high-humidity waste heat flows to the high- And a portion of the remainder can be bypassed to the outside of the recycled dry air supply system 100. The entire high-humidity waste heat may be discharged to the outside of the recycled dry air supply system 100, if necessary.

The operation of the external air inflow device 140 and the high-humidity waste heat inflow amount adjustment device 150 included in the recycled dry air supply system 100 shown in FIG. 1 can be controlled using a control device (not shown). That is, the control unit (not shown) can adjust the opening / closing of the external air inflow device 140 so as to control whether the external air is to be introduced into the recycled dry air supply system 100 and the amount of external air to be introduced The amount of the high-humidity waste heat flowing into the high-humidity waste heat recycling apparatus 110 can be controlled by controlling the high-humidity waste heat input amount regulating device 150 to control the moving path and the movement amount of the high- .

Hereinafter, the internal construction of the high-humidity waste heat recycling apparatus 110 according to the present invention shown in Fig. 1 will be described.

2 is a conceptual diagram of a high-humidity waste heat recycling apparatus according to the present invention.

Referring to FIG. 2, the high-humidity waste heat recycling apparatus 110 includes an air conversion unit 210 for converting high-temperature waste heat passing through the inside into hot and dry air, and a refrigerant regulating the temperature of the refrigerant used in the air conversion unit 210 And a conversion unit 220.

The air conversion unit 210 converts the gaseous water contained in the high-humidity waste heat flowing in the arrow direction between the cooling pipes arranged in a zigzag pattern at regular intervals with cool refrigerant flowing into the inside thereof into a state of liquid state, And a condenser 212 for raising the temperature of the high-humidity waste heat flowing in the arrow direction between the condenser pipes 211 arranged in a staggered arrangement with a constant interval and flowing the refrigerant changed into the high-temperature state by condensing. Although three condenser 212 are shown in FIG. 2, embodiments using four or more, of course, are possible.

The refrigerant conversion unit 220 compresses the refrigerant discharged from the cooler 211 to a high temperature and transfers the refrigerant to the condenser 212. The refrigerant is cooled by the condenser 212 and is transferred to the cooler 211.

L3 is a pipe through which the refrigerant is discharged from the condenser 212 and L4 is a pipe through which the refrigerant is discharged from the condenser 212. [ And a pipe into which the refrigerant flows.

3 is a block diagram of the refrigerant conversion unit shown in FIG.

3, the refrigerant conversion unit 220 includes a compressor 221, dry air 222, a capillary tube 223, an electronic expansion valve 224, a high-temperature capillary tube 225, and a filter 226 .

The compressor 221 compresses the refrigerant discharged from the cooler 211 to increase the temperature of the refrigerant, and then transfers the refrigerant to the condenser 212. The freeze-drying unit 222 lowers the temperature of the hot refrigerant discharged from the condenser 212 to liquefy by using dry air having a boiling point of -41 ° C. The capillary tube 223 passes a liquefied high-pressure refrigerant in the freeze-drying section 222 through a narrow passage, applies a resistance to the refrigerant to lower the pressure of the refrigerant, and controls the flow rate of the refrigerant.

In the expansion valve 224, liquid refrigerant is sprayed from the capillary tube 223, and the refrigerant expands in enthalpy and is changed into a low-temperature low-pressure refrigerant. The high-temperature capillary tube 225 lowers the temperature of the refrigerant and controls the flow rate of the refrigerant by passing the high-temperature refrigerant discharged from the condenser 212 through the narrow passage while reducing the pressure of the refrigerant by applying a resistance to the refrigerant. The filter 226 removes the impurities contained in the refrigerant flowing through the electronic expansion valve 224 and the high-temperature capillary tube 225, and then transfers it to the cooler 211.

Although not shown in FIG. 3, a control unit for controlling the operation of the compressor 221, the freeze-drying unit 222, the capillary tube 223, the electronic expansion valve 224, the high-temperature capillary tube 225, Can be installed.

Fig. 4 shows a photograph of the construction and embodiment of three condensers and one cooler.

Referring to the left drawing of FIG. 4, the red pipe is a pipe implementing a condenser and the blue pipe is a cooler.

Referring to Figures 2 and 4, in the embodiment using one cooler and three condensers, the positions of the cooler and the condenser can be defined as follows. The cooler is located at the bottom of the row. The first condenser 1 is located at the top of the same column as the cooler. The second condenser (2) is located at the lower end of the column where the cooler and the first condenser (1) are located. The third condenser (3) is located at the top of the same column as the second condenser (2).

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the present invention.

110: High-humidity waste heat recycling device
120: Conventional drying device
130: Circulation piping
140: External air inflow device
150: High-humidity waste heat inflow regulation device
210:
211: Cooler
212: condenser
220: Refrigerant conversion section
221: Compressor
222: freeze-drying section
223: capillary tube
224: Electronic expansion valve
225: High temperature capillary tube
226: Filter

Claims (7)

delete delete delete An air converter for converting at least one of a cooler for removing moisture contained in the high-humidity waste heat and a condenser for raising the temperature of the high-humidity waste heat into the high-temperature dry air passing through the cooler and the condenser; And
And a refrigerant conversion unit for compressing refrigerant discharged from the cooler to a high temperature and delivering the refrigerant to the condenser, and for cooling the refrigerant discharged from the condenser to transfer the refrigerant to the cooler,
The air-
A cooler located at the bottom of the row;
A first condenser located at the top of the same column as the cooler;
A second condenser located at the lower end of the other row; And
And a third condenser located at the top of the same column as the second condenser,
The refrigerant-
A compressor for compressing the refrigerant discharged from the cooler to increase the temperature of the refrigerant and deliver the refrigerant to the condenser;
A freeze-drying unit for reducing the temperature of the hot refrigerant discharged from the condenser by using dry air to liquefy the refrigerant;
A capillary for passing a high-pressure refrigerant liquefied in the freeze-drying unit through a narrow passage to reduce a pressure of the refrigerant by applying a resistance to the refrigerant, and controlling a flow rate of the refrigerant;
An electronic expansion valve for changing a refrigerant sprayed from the capillary in a liquid state to a low-temperature low-pressure state and delivering the refrigerant to the cooler;
A high-temperature capillary for passing a high-temperature refrigerant discharged from the condenser through a narrow passage to reduce the pressure of the refrigerant by applying a resistance to the refrigerant, thereby controlling the temperature of the refrigerant and controlling the flow rate of the refrigerant; And
A filter for removing impurities contained in the refrigerant flowing through the electronic expansion valve and the high-temperature-preventing capillary tube, and then transferring the impurities to the cooler;
Further comprising a high-temperature waste heat recycling apparatus. The refrigerant conversion unit according to claim 4,
A control unit for controlling operations of the compressor, the freeze-drying unit, the capillary, the electronic expansion valve, the capillary tube for high temperature, and the filter
Further comprising a high-temperature waste heat recycling apparatus.
The high-humidity waste heat recycling apparatus according to claim 5,
A drying device having a drying chamber for drying the object to be dried, a heating device for heating the introduced air, and an air inflow device for forcibly introducing air into the heating device;
Circulating piping for transferring high-humidity waste heat discharged from the drying apparatus to the high-humidity waste heat recycling apparatus and circulating high-temperature and low-humidity air discharged from the high-humidity waste heat recycling apparatus to the drying apparatus; And
A high-humidity waste heat inflow amount regulating device installed in a circulation pipe between the drying device and the high-humidity waste heat recycling device for regulating the amount of high-humidity waste heat traveling from the drying device to the high-humidity waste heat recycling device;
Wherein the recycled dry air supply system comprises: The recycling dry air supply system according to claim 6,
An external air inflow device for introducing outside air into the drying device;
Further comprising the step of supplying the recycled dry air supply system.

Images