KR101288041B1 - Drying device with a unitary cylinder using swirling air current - Google Patents

Abstract

PURPOSE: A multi-stage integrated dryer using a swirling current is provided to reduce the size by integrating through inserting a second cyclone a hot air drying cylinder into a current drying cylinder. CONSTITUTION: A multi-stage integrated dryer (100) using a swirling current comprises a current drying cylinder (10), a first cyclone (20), a how air drying unit (30), a heat exchanger (40), and a hot air supply pipe (50). The current drying cylinder firstly dries a dried object (70) at room temperature through the swirling current at a high speed in increased room temperature and discharges to the outside. The how air drying unit includes a second cyclone (31) with a second exhaust pipe (311) inducing the hot air to the heat exchanger. The second cyclone is arranged in the center of the current drying cylinder.

Description

DRYING DEVICE WITH A UNITARY CYLINDER USING SWIRLING AIR CURRENT}

The present invention relates to a multistage-integrated drying apparatus using swirling airflow having a compact structure that increases drying efficiency and minimizes energy loss by combining hot drying and high temperature drying, and more specifically, through swirling airflow at room temperature. The surface moisture of the dry matter is dried at room temperature, and the dry matter is collected by evaporating and drying the moisture contained therein through hot air, but the thermal energy of the exhausted hot air is discarded and reused in the supply hot air through a heat exchanger to greatly save energy. The present invention relates to a multistage-integrated drying apparatus using a swirling airflow structure.

Generally, the drying apparatus is configured to draw hot air into the inside of the drying apparatus, dry the drying target, and then discharge the dried material through the cyclone.

Such a conventional drying apparatus 9 has a drying tank 1 having a shredding blade 1a on its bottom surface and a lower portion thereof so as to supply hot air into the drying tank 1 as shown in FIG. 7. Blower fan (3) and the heater (5) and the cyclone (7) connected to the upper end of the drying tank (1) for discharging the dry matter.

However, such a device uses a large amount of energy from the thermal energy regardless of the moisture content and material state of the material to dry by using a hot air at all times. In addition, since the diameter of the drying tank 1 is large, the area of the outer wall surface which may be in contact with the cold external air is increased, which causes heat loss from the apparatus to the outside.

In addition, the conventional drying apparatus is composed of a single drying tank, there is a problem that the size of the drying tank to be significantly increased in order to increase the residence time of the dry matter, and also due to the drying tank is increased in size of the blower fan and heater There was a problem that consumes a lot of operating energy.

The present invention has been made in view of the above problems, and an object of the present invention is to dry the surface moisture of the dry matter through room temperature swirl air, and then to evaporate and dry the moisture contained therein through hot air The heat energy of the exhaust hot air is collected, but the waste heat is discarded to provide a multistage-integrated drying apparatus using a swirling airflow structure that can significantly save energy by reusing the supply hot air through a heat exchanger.

A second object of the present invention is to provide a multistage-integrated drying apparatus using a swirling airflow capable of reducing the size of the scale by inserting and integrating a second cyclone or hot air drying cylinder into the airflow drying cylinder.

It is a third object of the present invention to provide a multistage-integrated drying apparatus using swirl airflow that can increase drying efficiency and increase energy saving effect through multistage room temperature drying and single or multistage evaporation drying.

According to a feature of the present invention for achieving the object as described above, the first invention relates to a multistage-integrated drying apparatus using a swirling air flow, for this purpose, the object to be dried 70 through a high-speed swirling air flow at room temperature First air-temperature drying cylinder 10 to be discharged to the upper by drying; And, the dry matter 70 flowing from the airflow drying cylinder 10 is supplied through the first connecting pipe 60 to dry at room temperature The wet air is discharged to the lower portion, the first cyclone 20 is discharged to the outside through the first discharge pipe 21 is connected to the center; and the dry matter flowing from the first cyclone 20 ) Is supplied through the second connecting pipe 62, the hot air drying unit 30 for collecting and drying the moisture contained in the dry matter 70 through hot air, and discharging hot hot air; and, the hot air drying unit When exchanging hot air discharged through 30 with external air Heat exchanger 40 for discharging to low temperature air; And a hot air supply pipe (50) for supplying the hot air heat exchanged through the heat exchanger (40) to the inside of the hot air drying unit (30) in a hot air state, wherein the hot air drying unit (30) includes: And a second cyclone 31 formed with a second discharge pipe 311 for directing hot air to the heat exchanger, wherein the second cyclone 31 is inserted into a central portion of the airflow drying cylinder 10. .

The second invention relates to a multistage-integrated drying apparatus using a swirling airflow, for this purpose, the airflow drying cylinder (10) for first drying the dry matter 70 at room temperature through a high-speed swirling airflow at room temperature to be discharged to the upper portion; And, the dried product 70 flowing from the airflow drying cylinder 10 is supplied through the first connecting pipe 60, and dried at room temperature secondary discharged to the lower, the wet air containing moisture is connected to the center A first cyclone 20 discharged to the outside through the first discharge pipe 21; and a dry matter 70 flowing from the first cyclone 20 through the second connection pipe 62 and through hot air; Hot air drying unit 30 to collect the moisture contained in the dry matter 70 by evaporation to dry, and discharge the high temperature hot wind; and heat exchange the hot air discharged through the hot air drying unit 30 with external air A heat exchanger 40 for discharging air; And a hot air supply pipe (50) for supplying the hot air heat exchanged through the heat exchanger (40) to the inside of the hot air drying unit (30) in a hot air state, wherein the hot air drying unit (30) includes: Hot air drying cylinder which is inserted into the central portion of the airflow drying cylinder 10 and first evaporated to dry the moisture 70 with hot air supplied through the hot air supply pipe 50 to the dry matter 70 supplied through the first cyclone 20. (32) and the hot air drying cylinder 32 and the third connecting pipe (63) are connected to collect the dry matter 70 by evaporation to dry secondary hot air can be induced to the heat exchanger (40). It characterized in that it is composed of a second cyclone 31 is formed so that the second discharge pipe (311).

The third invention is, in the first or second invention, the air flow drying cylinder 10 is an injection pipe 11 for supplying a dry object 70 to the lower portion, and the high speed inside the air flow drying cylinder 10 It is preferable to further include an air supply pipe 12 to which the blower fan P is connected to form a swirling airflow.

The fourth invention, in the third invention, the inlet pipe 11 is a screw feeder that is built in the inside to supply the dry matter 70 while preventing the air at room temperature supplied through the air supply pipe 12 to enter Further comprising (S), the air supply pipe 12 is to form a rising swirling air flow on the lower circumferential surface of the airflow drying cylinder 10 to form a rising swirling air flow inside the airflow drying cylinder (10) It is preferable to be inclined upward so that it can be.

In the fifth invention, in the first invention, the second cyclone 31 preferably further includes a heat insulation layer 33 provided on the inner wall surface to prevent heat loss.

In the sixth invention, in the second invention, the hot air drying cylinder 32 and the second cyclone 31 preferably further include a heat insulating material layer 33 provided on the inner wall surface to prevent heat loss.

Seventh invention in the first or second invention, it is possible to smoothly supply the dry matter 70 while preventing the hot air supplied through the hot air supply pipe 50 is introduced into the second connection pipe (62). It is preferable to further include a screw feeder (S) arranged in the interior so that.

Eighth invention in the first or second invention, the hot air supply pipe 50 further comprises a blower fan (P), the hot air supply pipe 50 is the upper or hot air drying cylinder of the second cyclone (31) It is preferably connected to the lower part of 32).

The ninth invention, in the second invention, the bottom surface of the hot air drying cylinder 32 is formed in a plurality of inclined clockwise or counterclockwise circularly so that the hot air supplied through the hot air supply pipe 50 can be raised while turning It is preferable to further include a blade 321.

According to the multistage-integrated drying apparatus using the swirling air stream of the present invention, the surface moisture of the dry matter is dried to a constant moisture content without supplying thermal energy through the swirling air stream at room temperature, and then the moisture contained therein is evaporated through hot air. The dry items are collected, but the heat energy of the exhausted hot air is discarded to supply hot air through a heat exchanger, thereby greatly reducing energy.

In addition, by inserting and integrating a hot air drying cylinder into the airflow drying cylinder, the airflow drying cylinder can minimize the energy loss by using the heat lost to the outside from the internal hot air drying cylinder and narrow the size. It can be installed in one place.

In addition, through the multi-stage room temperature drying, single or multi-stage evaporation drying can increase the drying efficiency and energy saving effect.

1 is an exploded view of a multistage-integrated drying apparatus using a swirling airflow according to a first embodiment of the present invention;
Fig. 2 is a plan view of Fig. 1,
3 is an operation of the multistage-integrated drying apparatus using the swirling airflow according to FIG.
4 is an exploded view of a multistage-integrated drying apparatus using a swirling airflow according to a second embodiment of the present invention;
Fig. 5 is a plan view of Fig. 4,
6 is an operation of the multistage-integrated drying apparatus using the swirling airflow according to FIG.
7 is a configuration diagram showing a conventional drying apparatus.

Hereinafter, with reference to the accompanying drawings with respect to the multi-stage-integrated drying apparatus using a swirling air flow according to the present invention will be described in detail.

1 is an exploded view of a multistage-integrated drying apparatus using a swirling airflow according to a first embodiment of the present invention, Figure 2 is a plan view of FIG.

As shown in Figures 1 and 2, the first embodiment of the present invention is to dry the surface moisture of the dry matter to a constant moisture content without supplying heat energy through the swirling air flow at room temperature to room temperature, and then included therein through hot air To collect dry items by evaporating and drying the dried water, but the heat energy of the exhausted hot air that is discarded is reused in the supplying hot air through a heat exchanger, and the multi-stage-integrated drying device 100 using the swirling airflow of the structure that can greatly save energy. will be.

The multistage-integrated drying apparatus 100 using such swirling air flow is largely composed of five parts, which is an airflow drying cylinder 10, a first cyclone 20, a hot air drying unit 30, and a heat exchanger ( 40 and a hot air supply pipe 50.

The airflow drying cylinder 10 functions to primaryly dry the dry matter 70 at room temperature through a high-speed turning airflow at room temperature that is elevated therein.

The airflow drying cylinder 10 is connected to an inlet pipe 11 for supplying a dry object 70 to a lower portion thereof, and an air supply pipe 12 having a blower fan P to form a high speed airflow therein. It is configured.

Here, the input pipe 11 is a screw feeder that is constructed so as to smoothly supply the to-be-dried product 70 to the inside of the airflow drying cylinder 10 while preventing the inflow of high pressure and high speed air supplied through the air supply pipe 12. It further includes (S).

The air supply pipe 12 is connected to the circumferential surface of the airflow drying cylinder 10 so as to form a swirling airflow inside the airflow drying cylinder 10, and is also inclined upwardly to form an upward airflow. It is a structure. At this time, the swirling air flow is formed while rotating along the outer circumferential surface of the hot air drying unit 30 inserted into the central portion of the airflow drying cylinder 10.

As described above, when the dry matter 70 is supplied through the screw feeder S, the airflow dry cylinder 10 is loaded into the high-speed swirl airflow at room temperature, which is raised, and as a result, the residence time and the distance of stay increase. Thus, the drying efficiency is increased.

The first cyclone 20 receives the dry matter 70 from the airflow drying cylinder 10 through the first connection pipe 60 and is discharged downward by its own weight, and the wet air includes moisture. Discharge to the outside through the first discharge pipe 21 is connected to the center.

At this time, both sides of the first connecting pipe 60 is the air flow drying cylinder to continuously maintain the rotational speed and the direction of rotation of the air flow generated in the interior of the air flow drying cylinder 10, the first cyclone (20) It is a configuration that is coupled to the upper end of the circumferential surface (10) and the upper end of the circumferential surface of the first cyclone (20).

Accordingly, the dry matter 70 is loaded into the swirling airflow and is supplied into the first cyclone 20 through the first connecting pipe 60, and the dry matter 70 to be supplied is the first cyclone (by the swirling airflow). The second room temperature dried while turning inside the secondary 20, the second room temperature dried article 70 is dropped to the lower portion of the first cyclone 20, the moisture-containing wet air is opened in the first discharge pipe (21) It is the composition discharged to outside through).

In addition, the hot air drying unit 30 receives the dry matter 70 flowing from the first cyclone 20 through the second connection pipe 62 to evaporate the water contained in the dry matter 70 through the hot air. It is collected by drying and hot air is discharged.

The hot air drying unit 30 is composed of a second cyclone 31 is formed with a second discharge pipe 311 to guide the hot air supplied into the heat exchanger, the second cyclone 31 is the air flow drying cylinder ( 10) It is inserted and placed in the center portion (hereinafter referred to as a hot cyclone drying unit).

Here, the second cyclone 31 is coupled to the second connecting pipe 62 connected to the lower portion of the first cyclone 20 on the upper circumferential surface to receive the dry matter 70. At this time, the screw feeder S for supplying the dry object 70 is also built in the second connecting pipe 62, and the dry item 70 which is evaporated and dried in the lower part of the second cyclone 31 is collected. Screw feeder (S) is built up so that it can be.

In addition, the second cyclone 31 has a configuration in which a hot air supply pipe 50 for supplying hot air to a lower position of the second connection pipe 62 is connected. At this time, the blower fan P and the heater 51 are connected to the hot air supply pipe 50 so as to supply high temperature hot air into the second cyclone 31.

Therefore, inside the second cyclone 31, the dry matter 70 is loaded with hot air, and the water contained in the dry matter evaporates while turning based on the second discharge pipe 311. At this time, the hot air is discharged through the second discharge pipe 311, and the dry matter 70 dried by evaporation is lowered and collected through the screw feeder S.

On the other hand, the second cyclone 31 may be configured by interposing a heat insulating layer 33 on the inner wall surface in order to minimize the loss of heat energy of the supplied hot air. The heat energy lost to the outside of the second cyclone 31 may be reused as the heat energy inside the airflow drying cylinder 10.

In addition, the hot air discharged through the second discharge pipe 311 is connected to the heat exchanger 40 to guide the heat exchanger 40. At this time, the heat exchanger 40 is connected to the second discharge pipe 311 and the hot air supply pipe 50 into which the outside air flows so as to recover heat of the hot air discharged through the second discharge pipe 311. Structure.

The heat exchanger 40, the exhaust hot air discharged through the second discharge pipe 311 is heat-exchanged with the outside air and discharged as a low-temperature air.

The hot air supply pipe 50 has a structure in which the high temperature external air heat-recovered through the heat exchanger 40 is heated through a heater and supplied into the second cyclone 31 in a hot air state through a blower fan P. to be.

Hereinafter, the operation of the multistage-integrated drying apparatus using the swirling airflow according to the first embodiment of the present invention will be briefly described.

3 is an operation of the multistage-integrated drying apparatus using the swirling airflow according to FIG.

As shown in FIG. 3, when the dry matter 70 having a water content of about 35% is supplied to the airflow drying cylinder 10, the airflow drying cylinder of the lifted air flow at room temperature is supplied from the air supply pipe 12. 10) is dried at room temperature primary inside. At this time, as the surface moisture of the object 70 is dried at room temperature, the total moisture content of the object 70 is reduced to about 15%.

In addition, the internal temperature of the airflow drying cylinder 10 may be increased by about 30 ° C. to 40 ° C. with heat energy lost from the second cyclone 31 disposed therein, thereby improving the room temperature drying effect of the dried object 70. .

When the first dried product 70 dried at room temperature is supplied to the first cyclone 20 through the first connecting pipe 60, the second moisture is dried at room temperature while being turned inside the first cyclone 20, so that the entire moisture is dried. Secondary room temperature is dried to about 10%.

And the wet air separated by the room temperature drying of the dry matter 70 is discharged to the outside through the first discharge pipe 21, the second dry room temperature dry matter 70 is the weight of the first cyclone (20) Discharged to the bottom.

The dry matter 70 discharged to the lower portion of the first cyclone 20 is the inside of the second cyclone 31 through the screw feeder S built in the second connecting pipe 62 and the second connecting pipe 62. Is supplied.

The dry matter 70 supplied into the second cyclone 31 is evaporated and dried by hot air while being pivoted based on the second discharge pipe 311 and collected through the screw feeder S, and the hot air is discharged from the second discharge pipe. Discharged through 311. At this time, the internal temperature of the second cyclone 31 is formed at a temperature of about 90 ° C. to 110 ° C. by the supplied hot air of about 120 ° C., so that the moisture contained in the dry matter 70 evaporates within about 3%. Provide a structure that can be dried.

In addition, the temperature of the hot air discharged through the second discharge pipe 311 is about 70 ℃ ~ 80 ℃, this heat energy is recovered mostly through the heat exchanger 40 is discharged to the atmosphere at low temperature.

In addition, the hot air supplied into the second cyclone 31 is raised to about 50 ° C. to 60 ° C. by the heat energy of the hot air discharged through the heat exchanger 40 for the first time, and then about about 50 ° C. through the heater 51. It is raised about 120 ° C. and is supplied into the second cyclone 31.

As described above, the multistage-integrated drying apparatus using the swirling airflow according to the first embodiment can reduce the size of the scale by inserting the second cyclone into the airflow drying cylinder and integrating the same, and exhausted through the heat exchanger. By recovering thermal energy, energy efficiency can be increased.

In addition, through the multi-stage room temperature drying and a single evaporation drying can increase the drying efficiency and energy saving effect.

4 is an exploded view of a multistage-integrated drying apparatus using the swirling airflow according to the second embodiment of the present invention, and FIG. 5 is a plan view of FIG.

4 and 5, unlike the first embodiment, the hot air drying unit 30 is separated into a hot air drying cylinder 32 and a second cyclone 31.

Here, the hot air drying cylinder 32 is inserted into a central portion of the airflow drying cylinder 10 and evaporated with the hot air supplied through the hot air supply pipe 50 to the dry matter 70 supplied through the first cyclone 20. It functions to dry.

At this time, the second connecting pipe 62 connected to the first cyclone 20 and the hot air supply pipe 50 connected to the heat exchanger 40 are respectively connected on the lower circumferential surface of the hot air drying cylinder 32. Structure.

Further, the bottom surface of the hot air drying cylinder 32 further includes a blade 321 formed to be inclined upwardly in a clockwise or counterclockwise direction so that the hot air supplied through the hot air supply pipe 50 is turned.

In addition, the inner wall surface of the hot air drying cylinder 32 has a structure in which a heat insulation layer 33 is disposed to minimize heat loss of the hot air.

The second cyclone 31 is connected to the hot air drying cylinder 32 through a third connecting pipe 63.

In addition, the hot air drying cylinder 32 and the second cyclone 31 for evaporating and drying moisture of the object 70 further include a heat insulating material layer 33 provided on an inner wall surface to prevent heat loss.

In addition, the configuration other than the second embodiment has been described in the first embodiment and will be omitted.

Hereinafter, the operation of the multistage-integrated drying apparatus using the swirling airflow according to the second embodiment of the present invention will be briefly described.

6 is an operation of the multistage-integrated drying apparatus using the swirling airflow according to FIG.

Prior to describing the operation in the second embodiment, the contents described in the first embodiment will be omitted.

As shown in FIG. 6, the dry matter 70 discharged to the lower portion of the first cyclone 20 includes a screw feeder S formed in the second connecting pipe 62 and the second connecting pipe 62. It is supplied to the lower portion of the hot air drying cylinder 32 through.

The to-be-dried product 70 supplied into the hot air drying cylinder 32 is lifted by the swirling air flow carried by the hot air supplied through the hot air supply pipe 50. At this time, the hot air drying cylinder 32 provides a structure in which the swirling air flow rising through the plurality of blades 321 coupled to the bottom surface can be generated.

The dry matter 70 is supplied to the upper portion of the second cyclone 31 through the third connecting pipe 63 while the water is first evaporated to dryness in the ascending swirling airflow.

At this time, both sides of the third connecting pipe (63) is a hot air drying cylinder to continuously maintain the rotational speed and the direction of rotation of the air flow generated inside the hot air drying cylinder (32) inside the second cyclone (31) The upper end of the circumferential surface of (32) and the upper end of the circumferential surface of the second cyclone (31).

Accordingly, the to-be-dried product 70 is loaded into the swirling airflow and is supplied into the second cyclone 31 through the third connecting pipe 63, and the dried product 70 to be supplied is the second cyclone ( It is secondary evaporated to dry while turning inside the 31.

Secondary evaporated dry matter 70 is collected through a screw feeder (S), hot air is discharged through the second discharge pipe (311).

As described above, the multistage-integrated drying apparatus using the swirling airflow according to the second embodiment may increase drying efficiency and energy saving effect through multistage room temperature drying and multistage evaporation drying.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

10: air flow drying cylinder 11: input pipe 12: air supply pipe
20: first cyclone 21: first discharge pipe
30: hot air drying unit 31: the second cyclone 311: the second discharge pipe
32: hot air drying cylinder 321: blade
33: insulation layer
40: heat exchanger
50: hot air supply pipe 51: heater
60: first connector 62: second connector 63: third connector
70: dry matter
P: Blower fan S: Screw feeder
100: multistage-integrated drying apparatus using swirling airflow

Claims (9)

An airflow drying cylinder 10 configured to first dry the dry matter 70 at room temperature through a high-speed swirling air stream at elevated temperature and discharge the upper portion to the upper portion;
The dry matter 70 flowing from the airflow drying cylinder 10 is supplied through the first connection pipe 60 to be dried at a second room temperature and discharged to the lower portion, and the wet air containing moisture is connected to the first discharge pipe. A first cyclone 20 discharged to the outside through the 21;
The dry matter 70 flowing from the first cyclone 20 is supplied through the second connection pipe 62 to collect and dry moisture contained in the dry matter 70 through hot air, and the high temperature hot air is discharged. Hot air drying unit 30;
A heat exchanger 40 for exchanging hot air discharged through the hot air drying unit 30 with external air to discharge the air into low temperature air; And
Hot air supply pipe 50 for heating the hot air heat exchanged through the heat exchanger 40 to supply the inside of the hot air drying unit 30 in a hot air state;
The hot air drying unit 30 is composed of a second cyclone 31 is formed with a second discharge pipe 311 to guide the hot air to the heat exchanger, the second cyclone 31 is the center of the air flow drying cylinder (10) Multi-stage unitary drying device using a swirling air flow, characterized in that the insertion is arranged in.
An airflow drying cylinder 10 configured to first dry the dry matter 70 at room temperature through a high-speed swirling air stream at elevated temperature and discharge the upper portion to the upper portion;
The dry matter 70 flowing from the airflow drying cylinder 10 is supplied through the first connection pipe 60 to be dried at a second room temperature to be discharged to the lower portion, and the wet air containing moisture is connected to the first discharge pipe. A first cyclone 20 discharged to the outside through the 21;
The dry matter 70 flowing from the first cyclone 20 is supplied through the second connection pipe 62 to collect and dry moisture contained in the dry matter 70 through hot air, and the high temperature hot air is discharged. Hot air drying unit 30;
A heat exchanger 40 for exchanging hot air discharged through the hot air drying unit 30 with external air to discharge the air into low temperature air; And
Hot air supply pipe 50 for heating the hot air heat exchanged through the heat exchanger 40 to supply the inside of the hot air drying unit 30 in a hot air state;
The hot air drying unit 30 is inserted into a central portion of the airflow drying cylinder 10 to supply moisture to the dry matter 70 supplied through the first cyclone 20 through the hot air supply pipe 50. The hot air drying cylinder 32 for primary evaporation drying, and the hot air drying cylinder 32 and the third connecting tube 63 are connected to collect the dried items 70 by evaporation to dryness, and the high temperature hot air is heat exchanged. Multi-stage-integrated drying device using a swirling air flow, characterized in that consisting of a second cyclone 31 is formed with a second discharge pipe (311) to be guided to the group (40).
3. The method according to claim 1 or 2,
The airflow drying cylinder 10 is connected to the input pipe 11 for supplying the object 70 to the lower portion and the blower fan (P) to form a high-speed turning airflow inside the airflow drying cylinder (10) Multi-stage unitary drying device using a swirling air flow, characterized in that it further comprises an air supply pipe (12).
The method of claim 3, wherein
The inlet pipe 11 further includes a screw feeder S built therein so as to supply a dry item 70 while preventing the air at room temperature supplied through the air supply pipe 12 from entering,
The air supply pipe 12 is a multi-stage-integrated drying device using a swirling air flow, characterized in that the inclined upwardly to form an upward swirling air flow on the lower circumferential surface of the airflow drying cylinder (10).
The method of claim 1,
The second cyclone (31) is a multi-stage-integrated drying device using a swirling air flow, characterized in that it further comprises a heat insulating layer (33) provided on the inner wall surface to prevent heat loss.
The method of claim 2,
The hot air drying cylinder (32) and the second cyclone (31) further comprises a heat insulation layer (33) provided on the inner wall surface to prevent heat loss, multi-stage-integrated drying apparatus using a swirl airflow.
3. The method according to claim 1 or 2,
The second connection pipe (62) further includes a screw feeder (S) built in the inside so as to smoothly supply the dry matter 70 while preventing the hot air supplied through the hot air supply pipe 50 from being introduced. Multi-stage unitary drying device using a swirling air flow, characterized in that.
3. The method according to claim 1 or 2,
The hot air supply pipe 50 further includes a blower fan (P), the hot air supply pipe 50 is a swirling air flow, characterized in that connected to the upper portion of the second cyclone 31 or the lower portion of the hot air drying cylinder (32) Multi-stage unitary drying device using.
The method of claim 2,
The bottom surface of the hot air drying cylinder 32 further includes a plurality of blades 321 formed to be inclined in a clockwise or counterclockwise direction in a circular shape so that the hot air supplied through the hot air supply pipe 50 is turned upward. Multistage-integrated drying apparatus using a swirling air flow.

Images