KR101325753B1 - Dual rotary kiln and drying method thereof - Google Patents

Abstract

The present invention relates to a drying apparatus for drying a dry material, and more particularly, it is possible to increase the drying efficiency of the dry material and to shorten the drying time, and the product properties of the dry material in a single drying device. The purpose of the present invention is to provide a dual rotary drying apparatus and a drying method thereof, which can select various drying blowing methods according to the residual moisture content, and can improve the driving efficiency by recycling the discharged air discharged. The present invention for achieving the above object, the device frame; A first drying apparatus installed above the apparatus frame and configured to first dry the material to be dried; A feeding means connected to one end of the first drying device and for introducing a dry material into the first drying device; A second drying device installed in the apparatus frame, receiving the first dried material to be dried in the first drying device, and performing a second drying and discharging the dried product to the outside; Drive means for rotationally driving the first and second drying apparatuses; And a hot air supply / exhaust device for providing and discharging hot air to the first drying device and the second drying device.

Description

Dual rotary dryer and its drying method {DUAL ROTARY KILN AND DRYING METHOD THEREOF}

The present invention relates to a drying apparatus for drying a dry material, and more particularly, it is possible to increase the drying efficiency of the dry material and to shorten the drying time, and the product properties of the dry material in a single drying device. According to the residual moisture content, it is possible to select a dry blowing method in various ways, and it is possible to recycle the discharged air discharged, and the present invention relates to a dual rotary drying apparatus and a drying method thereof which can improve operation efficiency.

Recently, various types of dryers for drying the moisture-containing material to be dried have been proposed.

Typically, in the case of a cylindrical rotary drying machine, the product is dried at the other end of the rotating cylinder while supplying the material to be dried at one end of the rotating cylinder and adjusting the residence time of the material to be dried by the rotational speed and the inclination of the cylinder and the inner conveying blade. Most of the series of single-type drying equipment for discharging gas.

In the drying method according to the blowing method, any one of a cocurrent blowing method which is a blowing method according to the direction in which the dried material flows in drying the to-be-dried material, and a countercurrent blowing method which is a blowing method which flows against a dry material. It is a fixed blow type of dry blow type which cannot work by changing the co-current type or countercurrent type arbitrarily because it adopts the blowing method and is uniformly manufactured. In other words, because it is designed only in a uniform blowing method, there is a problem that the blowing method can not be selected in one drying device according to the product properties and residual moisture content of the material to be dried.

In order to solve the problem of the drying method according to the air blowing method, a rotary drying apparatus as shown in FIGS. 1 and 2 has been proposed. 1 and 2 are side and front configuration diagrams schematically shown to explain the configuration of a conventional rotary kiln (rotary kiln), respectively.

As shown in Figs. 1 and 2, in the conventional general rotary drying apparatus, two tires (2) are attached to a rotating cylinder (1), and a driven gear (3) is provided at the center of the rotating cylinder (1). Is mounted.

Four drum holding rollers 4 are provided on both sides of the rotary cylinder 1, and the tires 2 can be rotated on the drum holding rollers 4, respectively. The drive gear 6 is driven by the output shaft of the reducer 5 located on the lower side of the rotary cylinder 1, and the driven gear 3 attached to the rotary cylinder 1 is thus rotated.

Then, the drying hot air is supplied from the first duct 7 and discharged into the second duct 8 while supplying the dry material to the feeder 9 through the hopper 9. chute). Both ends of the rotating cylinder 1 are rotatably supported by holders 12 and 13.

When the drying hot air is blown out of the first duct 7 and discharged to the second duct 8, this drying method is a cocurrent drying method. On the other hand, when the drying hot air is supplied from the second duct 8 and the exhaust air which has finished drying to the first duct 7 is discharged, this is a countercurrent drying method.

1 and 2, in consideration of the product properties of the material to be dried, etc. in one drying apparatus can choose a co-current and countercurrent drying method, but it is not easy to disassemble and assemble for changing the peripheral components accordingly, It takes a long time, there is a problem affecting the life of the device due to disassembly and assembly.

On the other hand, the drying hot air used in the drying apparatus as described above is cocurrent or countercurrent, but the drying hot air supplied from one end of the rotating cylinder is discharged as a high temperature and high temperature hot air after drying the material to be dried, so that the hot air that has acted once is fully atmospheric. Is discharged.

In order to recover and use the exhaust heat of the exhaust air discharged to the atmosphere as described above, the heat exchanger is installed, and the high temperature and high temperature hot air is discharged, and since the fresh air must use the hot air heated through the heat exchanger, the heat exchange efficiency is low, that is, operation There is a problem of low efficiency.

The present invention has been proposed to solve the above-described problems, and provides a dual rotary drying apparatus and a drying method which can freely select a variety of dry blowing methods in one drying apparatus without disassembly and assembly of peripheral components. Its purpose is to.

In addition, another object of the present invention is to provide a dual rotary drying apparatus and a drying method thereof capable of improving the operating efficiency by allowing the maximum recycling of the used hot air without discarding the total amount of used hot air.

Another object of the present invention is to provide a dual rotary drying apparatus and a drying method thereof capable of increasing the drying efficiency of the material to be dried and shortening the drying time.

According to a first aspect of the present invention for achieving the above objects, an apparatus frame; A first drying apparatus installed above the apparatus frame and configured to first dry the material to be dried; A feeding means connected to one end of the first drying device and for introducing a dry material into the first drying device; A second drying device installed in the apparatus frame, receiving the first dried material to be dried in the first drying device, and performing a second drying and discharging the dried product to the outside; Drive means for rotationally driving the first and second drying apparatuses; And a hot air supply / exhaust device for providing and discharging hot air to the first drying device and the second drying device.

The first drying device comprises a cylindrical drying drum; A plurality of lift plates formed on the inner edge of the cylindrical drying drum and for conveying in the axial direction the dry material to be introduced, which is inclined along the axial direction and has a predetermined interval in the circumferential direction; Hoods provided at both ends of the cylindrical drying drum; And one end side duct and the other end side duct respectively provided in the hood to supply and discharge hot air, and wherein the second drying apparatus comprises: a cylindrical drying drum; A plurality of lift plates formed on an inner edge of the cylindrical drying drum and having a predetermined interval in the circumferential direction and extending obliquely along the axial direction to transfer the dry material provided from the first drying apparatus in the axial direction; Hoods provided at both ends of the cylindrical drying drum; And one end duct and the other end side duct respectively provided at the hood to supply and discharge hot air.

The driving means includes a tire which is installed symmetrically with respect to a central portion on both outer edges of the drying drum of the first drying apparatus and the drying drum of the second drying apparatus; A rotating roller that contacts and supports the tires so as to be rotatably supported; A driven gear provided at the outer edge of the central portion of each drying drum; A drive gear meshing with the driven gear; And a rotation shaft may include a drive motor coupled to the drive gear.

The hot air exhaust device includes a first blower for blowing hot air to one end duct of the first drying device; A second blower for blowing hot air to the other end duct of the second drying device; A third blower for blowing air from one end duct of the second drying device; A first heater installed between the first blower and one end duct; And a second heater installed between the second blower and the other end duct of the second drying apparatus.

The apparatus may further include a blowing method controller for selectively controlling the flow of air from the first drying apparatus to the second drying apparatus or from the second drying apparatus to the first drying apparatus.

The air blowing control device may include a first connection duct branched from the first heater to connect one end duct and the other end duct of the first drying device; First switching means for selectively providing the air flow provided from the first connection duct to one end duct or the other end duct of the first drying apparatus; A second connection duct branched from the second heater to connect one end duct and the other end duct of the second drying apparatus; Second switching means for selectively providing the air flow provided from the second connection duct to one end duct or the other end duct of the second drying apparatus; And it may include a control means for controlling the operation of the first and second switching means.

It may further include a third connection duct branched from the second connection duct to be switched by the second switching means to provide an air flow to the first blower.

The first switching means includes a plurality of opening and closing members for selectively providing air flow to one end duct or the other end duct of the first drying apparatus, and the second switching means is one end of the second drying apparatus. It may include a plurality of opening and closing member for selectively providing air flow to the duct, the other end duct or the first blower.

A heat exchanger for heat-exchanging air discharged from the first drying apparatus; And a connection pipe for supplying air heat-exchanged in the heat exchanger to the second drying apparatus.

According to a second aspect of the present invention, there is provided a drying method for providing a dry product by providing the dry material first dried in the first drying apparatus to a second drying apparatus, wherein the first drying apparatus is a second drying apparatus. Or it provides a drying method of the dual rotary drying apparatus for selectively controlling the flow of air from the second drying apparatus to the first drying apparatus.

According to the dual rotary drying apparatus and the drying method thereof according to the present invention, it is possible to freely select a variety of dry blowing method in one drying apparatus, and to increase the drying efficiency of the material to be dried and shorten the drying time. It has an effect.

In addition, according to the present invention, it is possible to recycle as much as possible without discarding the total amount of hot air used for drying the material to be dried, thereby improving the driving efficiency.

Figure 1 is a side configuration diagram schematically showing in order to explain the configuration of a conventional rotary kiln (rotary kiln).
Figure 2 is a front configuration diagram schematically showing in order to explain the configuration of a conventional rotary kiln (rotary kiln).
Figure 3 is a side configuration diagram showing the configuration of a preferred embodiment of a dual rotary drying apparatus according to the present invention.
4 is a view showing that hot air is provided in a co-current drying method by a blowing method control device.
5 is a view showing that hot air is provided in a countercurrent drying method by a blowing method control device.

Further objects, features and advantages of the present invention will become more apparent from the following detailed description and the accompanying drawings.

Prior to the description, the invention should not be construed as limited to the embodiments described below, but may be embodied in many different forms. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Also, unless stated otherwise, all terms including technical and scientific terms have the same meaning as would be understood by one of ordinary skill in the art having ordinary skill in the art.

These terms, such as those defined in conventional dictionaries, shall be construed to have meanings consistent with their meanings in the context of the related art and the description of the present invention, and are to be interpreted as being ideally or externally grossly intuitive It will not be interpreted.

An embodiment of the invention is described with reference to schematic illustrations of an ideal embodiment of the invention. Accordingly, changes or changes from the shapes of the illustrations, for example changes in shape or tolerances, are to be expected. Accordingly, embodiments of the invention are not intended to be limited to the particular shapes of the areas described as illustrations, but include deviations in the shapes, the areas described in the figures being entirely schematic and their shapes It is not intended to describe the precise shape of the region nor is it intended to limit the scope of the invention.

Dual rotary drying apparatus according to the invention is large, the device frame of a predetermined shape; A first drying apparatus installed above the apparatus frame and configured to first dry the material to be dried; A feeding means connected to one end of the first drying device and for introducing a dry material into the first drying device; A second drying device installed in the apparatus frame, receiving the first dried material to be dried in the first drying device, and performing a second drying and discharging the dried product to the outside; Drive means for rotationally driving the first and second drying apparatuses; And a hot air supply / exhaust device for providing and discharging hot air to the first drying device and the second drying device.

Here, the dual rotary drying apparatus of the present invention includes a blowing method control device for selectively controlling the flow of hot air provided by the hot air supply and exhaust device.

Hereinafter, a preferred embodiment of the dual rotary drying apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a side configuration diagram showing the configuration of a preferred embodiment of a dual rotary drying apparatus according to the present invention.

As shown in Figure 3, the dual rotary drying apparatus according to the present invention basically comprises a device frame (A) of a predetermined shape; A first drying device (100) installed above the device frame (A) and rotatably drying the material to be dried first; An injection means (200) provided at one end of the first drying apparatus (100), for introducing a material to be dried into the first drying apparatus; The second drying is installed in the device frame (A), receiving the first dry material to be dried in the first drying device 100, the second drying and discharged the dried product to the outside, rotatably installed second drying Device 300; Rotation driving means (400) for rotationally driving the first and second drying apparatuses (100, 300); And a hot air supply / exhaust device for providing and discharging hot air to the first drying device 100 and the second drying device 300.

Although the apparatus frame A is shown to be formed in a frame having a rectangular support frame, the second drying apparatus from the first drying apparatus 100 is supported while supporting the first drying apparatus 100 and the second drying apparatus 300. If it is a configuration that can be installed to support the material to be dried to 300 to be provided is not particularly limited.

In the drawing, the device frame A has a first drying device 100 installed thereon, and the dried material first dried from the first drying device 100 through a chute (described later) by its own weight. The embodiment provided to the drying apparatus 300 is shown.

The first drying device 100 is a cylindrical drying drum (110); A plurality of lift plates (not shown) formed at the inner edge of the cylindrical drying drum 110 to transfer the dry material to be introduced, which is inclined along the axial direction and has a predetermined interval in the circumferential direction; Hoods 120 and 121 provided at both ends of the cylindrical drying drum 110, respectively; And one end duct 130 and the other end duct 131 provided at the hoods 120 and 121, respectively, to which hot air is supplied and discharged.

The input means 200 is not particularly limited as long as it is a configuration that can be transported through the hopper 210 into the first drying apparatus 100. The feeding means 200 shown in the figure shows an example of a transfer screw transfer method. As another example, the input means 200 may be configured by a conveyor belt transfer method.

The second drying apparatus 300 has a cylindrical drying drum 310 similar or the same as the first drying apparatus 100; A plurality of lift plates are formed on the inner edge of the cylindrical drying drum 310, have a predetermined interval in the circumferential direction and extend inclined along the axial direction to transfer the dry material provided from the first drying apparatus 100 in the axial direction. (Not shown); Hoods 320 and 321 respectively provided at both ends of the cylindrical drying drum 310; And one end duct 330 and the other end duct 331 provided at the hoods 320 and 321, respectively, to which hot air is supplied and discharged. The lower side of the one end side duct 330 is provided with a discharge chute 350 for discharging the product dried in the second drying apparatus 300 to the bottom.

Here, as shown in the drawing, the dry material to be primarily dried in the first drying apparatus 100 is supplied to the other end side of the second drying apparatus 300 through a moving chute (150).

Looking at the drive means 400 that is configured to rotatably support and rotate the first drying apparatus 100 and the second drying apparatus 300, the drying drum 110 of the first drying apparatus 100 and Tires 410 which are respectively installed symmetrically with respect to the central part on both outer edges of the drying drum 310 of the second drying apparatus 300; A rotating roller 420 in contact with each tire 410 to be rotatably supported; A driven gear 430 provided at the outer edge of the central portion of each of the drying drums 110 and 310; A driving gear 440 engaged with the driven gear 430; And a drive motor 450 whose rotation shaft is coupled to the drive gear 440.

The driving means 400 is not limited to the above-described embodiment, and may be configured in various ways as long as it can rotate the drying apparatuses 100 and 300. As another example, the driving means 200 may be configured in such a way that a driven sprocket is installed at one end and a driving sprocket interlocked with the driven sprocket is rotated by a driving motor.

Next, the hot air supply / exhaust device constituting the dual rotary drying apparatus of the present invention will be described with reference to FIGS. 4 and 5. 4 and 5 is a view showing the configuration of the hot air exhaust and exhaust air control device and the air blowing control device constituting the dual rotary drying apparatus according to the present invention, Figure 4 is a hot air is provided in a co-current drying method by the air blowing control device It is a figure which shows that FIG. 5 is a figure which shows that a hot air is provided by a counterflow type drying method by a ventilation system control device.

The hot air supply / exhaust device for supplying and discharging hot air to the first drying apparatus 100 and the second drying apparatus 300 is hot air (hot air) to one end duct 130 of the first drying apparatus 100. A first blower 510 for blowing air; A second blower 520 for blowing hot air (hot air) to the other end duct 331 of the second drying device 300; A third blower (530) for blowing air from one end duct (330) of the second drying apparatus (300); A first heater 540 installed between the first blower 510 and one end duct 120; And a second heater 550 installed between the second blower 520 and the other end duct 331 of the second drying apparatus 300.

In addition, the hot air supply and exhaust device of the present invention selectively flows the air from the first drying apparatus 100 to the second drying apparatus 300 or from the second drying apparatus 300 to the first drying apparatus 100. It further includes a blowing method control device for controlling.

The air blowing control device is branched from the first heater 540 and the first connection duct 610 connecting the one end side duct 130 and the other end side duct 131 of the first drying apparatus 100. ); First switching means for selectively providing the air flow provided from the first connection duct 610 to one end duct 130 or the other end duct 131 of the first drying apparatus 100; A second connection duct 620 branched from the second heater 550 to connect one end duct 330 and the other end duct 331 of the second drying apparatus 300 to each other; Second switching means for selectively providing the air flow provided from the second connection duct 620 to one end duct 130 or the other end duct 131 of the second drying apparatus 300; And control means for controlling the operation of the first and second switching means.

The apparatus further includes a third connection duct 630 branched from the second connection duct 620 to be switched by the second switching means to provide an air flow to the first blower 510.

The first switching means is a plurality of opening and closing member (710, 720, 730, 740) for selectively providing air flow to one end duct 130 or the other end duct 131 of the first drying device 100 The second switching means includes a plurality of opening and closing members for selectively providing an air flow to one end duct 330, the other end duct or the first blower 510 of the second drying apparatus 300 ( 810, 820, 830, 840. At this time, the 'opening and closing member' will include various types of opening and closing control member such as 'opening and closing damper (Damper)' or 'opening and closing valve (Valve)'.

In addition, the present invention may further include a lift device for adjusting the inclination of the first and second drying apparatus (100.300).

Dual rotary drying apparatus of the present invention configured as described above is composed of the first drying device 100 and the second drying device 300 is operated independently of the heat source and the driving method.

The first drying device 100 is responsible for the period drying period of the most evaporation of moisture, and the second drying device 300 is responsible for the drying period.

The first drying apparatus 100 evaporates most of the moisture contained in the material to be dried so that the air (hot air) discharged from the other end duct 131 of the first drying apparatus 100 discharges all the amount or passes through a heat exchanger. Humid air may be completely discharged and only fresh hot air that has been indirectly exchanged may be supplied to the heater of the second drying apparatus 300.

On the other hand, the drying hot air in the second drying apparatus 300 is used in the rate-sensitive drying to further reduce the moisture of the low moisture content of the material to be dried, so that the generation of moisture is extremely low.

Therefore, the exhaust air from the second drying apparatus 300 guides the entire amount to the heater 540 of the first drying apparatus 100 to heat the heater, thereby maximally saving the amount of heat consumed.

The first drying apparatus 100 and the second drying apparatus 300 may have independent driving and drying processes, and may be arbitrarily operated according to the rotational speed and the inclination of the drying apparatus. It is possible to operate by selecting the moisture content freely.

Hereinafter, the drying method according to the blowing method in the dual rotary drying apparatus according to the present invention.

4 and 5 illustrate the operation of the switching means in the co-current drying method and the countercurrent drying method, it is possible to control the blowing method by arbitrarily selecting whether to open or close each opening member by the control means.

First, the drying method according to the co-current blowing method will be described.

The opening and closing members 710 and 720 installed in the duct line of the first drying apparatus 100 are completely opened through the first switching means, and the opening and closing members 730 and 740 are completely closed.

The entire amount of discharged air from the second drying apparatus 300 is sucked into the intake port of the blower 510 of the first drying apparatus 100 and heated by the heater 540 to pass through the opening and closing member 710 so as to pass the first drying apparatus. Blowing through the hood 120 to which the input means 200 of the 100 is attached, the hot air is supplied to the dry material to be dried and the drying operation is completed. It is guided to the blower 530 through the entire amount is discharged to the outside. The discharged exhaust may be induced to be recycled in the second drying apparatus 300 via the heat exchanger as described above.

At this time, the internal drying action of the first drying apparatus 100, the flow direction of the dry material and the flow direction of the drying hot air is the same. Therefore, this drying method is a cocurrent drying method.

Subsequently, the opening and closing members 810 and 820 are completely opened in the duct line of the second drying apparatus 300, and the air sucked into the blower 520 in the state in which the opening and closing members 830 and 840 are completely sealed is heated ( When heated and blown with 550, the drying hot air enters the other end duct 331 of the second drying apparatus 300 through the opening and closing member 810, and the first drying (constant drying) is performed in the first drying apparatus 100. The dried material containing the relatively low moisture is supplied while being supplied as a free drop, and the drying material is passed through the second drying device 300 to go in the same direction as the dry material.

After being discharged to the other end of the second drying apparatus 300 and passing through the hood 320, the whole amount is sucked into the blower 510 of the first drying apparatus 100 through the opening and closing member 820. That is, the direction of the drying hot air is the same direction as the flow direction of the material to be dried, thereby achieving a cocurrent drying method.

Hereinafter, the countercurrent drying method will be described.

The opening and closing members 710 and 720 and the opening and closing members 810 and 820 set in the co-current drying method are completely closed through the first and second switching means, and the opening and closing members 730 and 740 and the opening and closing member 830, 840 is fully open.

When the first drying apparatus 100 and the second drying apparatus 300 are operated as described above, the exhaust air discharged from the second drying apparatus 300 is guided to the inlet of the blower 510 to be sucked and the heater 540. The heated hot air is heated from the place where the dry material is discharged from the first drying apparatus 100 through the opening / closing member 730 to face the direction in which the dry material is introduced. After that, the material is sucked into the blower 530 through the opening and closing member 740 through the raw material input side hood 120 of the first drying apparatus 100 and then discharged to the outside. In other words, the material to be dried and the hot air act in opposite directions to each other, and the drying method is a countercurrent drying method.

In the second drying apparatus 300, the fresh air sucked into the blower 520 is heated through the heater 550, and then one end duct through which the dry material is dried is discharged through the opening and closing member 830. 330 flows through the hood 320 and through the opening and closing member 840 to be sucked into the blower 510 of the first drying apparatus 100.

At this time, it can be seen that the working direction of the dry material and the hot air flows to face each other. That is, it can be seen that drying is in progress by the countercurrent drying method.

As can be seen above, since each opening and closing member used in the first and second drying apparatuses 100 and 300 can be used freely, the first drying apparatus 100 is co-current only by setting the operation of the opening and closing members. The drying method, and also the second drying apparatus 300 may be selected by a countercurrent drying method to perform the drying operation or to select the opposite operation.

In other words, since four types of drying methods can be freely selected, the residual moisture content of the dried material can be selected and operated under the highest efficiency conditions.

As described above, the dual rotary drying apparatus according to the present invention can freely select a variety of dry blowing methods in one drying apparatus, and can increase the drying efficiency of the material to be dried and shorten the drying time. Operation efficiency can be improved by allowing maximum recycling of the hot air used for drying the material without discarding it.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes within the scope not departing from the technical spirit of the present invention are possible in the art. It will be evident to those who have knowledge of.

100: first drying device
200: input means
300: second drying apparatus
410 tire
420: roller
430: driven gear
440: drive gear
450: drive motor
510, 520, 530: blower
610, 620, 630: piping
710-740: opening and closing member
810-840: opening and closing member

Claims (10)

Device frames;
A first drying apparatus installed above the apparatus frame and configured to first dry the material to be dried;
A feeding means connected to one end of the first drying device and for introducing a dry material into the first drying device;
A second drying device installed in the apparatus frame, receiving the first dried material to be dried in the first drying device, and performing a second drying and discharging the dried product to the outside;
Drive means for rotationally driving the first and second drying apparatuses; And
A hot air supply / exhaust device for providing and discharging hot air to the first drying device and the second drying device,
The first drying device comprises a cylindrical drying drum; A plurality of lift plates formed on the inner edge of the cylindrical drying drum and for conveying in the axial direction the dry material to be introduced, which is inclined along the axial direction and has a predetermined interval in the circumferential direction; Hoods provided at both ends of the cylindrical drying drum; And one end duct and the other end duct provided in the hood, respectively, to which hot air is supplied and discharged.
The second drying device comprises a cylindrical drying drum; A plurality of lift plates formed on an inner edge of the cylindrical drying drum and having a predetermined interval in the circumferential direction and extending obliquely along the axial direction to transfer the dry material provided from the first drying apparatus in the axial direction; Hoods provided at both ends of the cylindrical drying drum; And one end duct and the other end duct provided in the hood, respectively, to which hot air is supplied and discharged.
The dry material to be primarily dried in the first drying device is supplied to the other end side of the second drying device through a moving chute,
And a blowing method control device for selectively controlling the flow of air from the first drying apparatus to the second drying apparatus or from the second drying apparatus to the first drying apparatus.
delete The method of claim 1,
The driving means
Tires are installed symmetrically around a central portion on both outer edges of the drying drum of the first drying device and the drying drum of the second drying device;
A rotating roller that contacts and supports the tires so as to be rotatably supported;
A driven gear provided at the outer edge of the central portion of each drying drum;
A drive gear meshing with the driven gear; And
Dual rotary drying apparatus comprising a drive motor that the rotary shaft is coupled to the drive gear.
The method of claim 1,
The hot air supply and exhaust device
A first blower for blowing hot air to one end duct of the first drying device;
A second blower for blowing hot air to the other end duct of the second drying device;
A third blower for blowing air from one end duct of the second drying device;
A first heater installed between the first blower and one end duct; And
And a second heater installed between the second blower and the other end duct of the second drying device.
delete The method of claim 1,
The blowing method control device
A first connection duct branched from the first heater to connect one end duct and the other end duct of the first drying apparatus;
First switching means for selectively providing the air flow provided from the first connection duct to one end duct or the other end duct of the first drying apparatus;
A second connection duct branched from the second heater to connect one end duct and the other end duct of the second drying apparatus;
Second switching means for selectively providing the air flow provided from the second connection duct to one end duct or the other end duct of the second drying apparatus; And
Dual rotary drying device comprising a control means for controlling the operation of the first and second switching means.
The method according to claim 6,
And a third connection duct branched from the second connection duct and diverted by the second switching means to provide an air flow to the first blower.
The method of claim 7, wherein
The first switching means includes a plurality of opening and closing member for selectively providing air flow to one end duct or the other end duct of the first drying device,
The second switching means comprises a plurality of opening and closing member for selectively providing air flow to one end duct, the other end duct or the first blower of the second drying device.
9. The method of claim 8,
A heat exchanger for heat-exchanging air discharged from the first drying apparatus; And
And a connection pipe for supplying air heat-exchanged in the heat exchanger to the second drying apparatus.
delete

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