KR20130047939A - Rotary type dry apparatus and dry method thereof - Google Patents

Abstract

PURPOSE: A rotary type drying device and a method for drying a non-drying material are provided to obtain suitable drying time to various types of non-drying material with high moisture content and improve the drying efficiency. CONSTITUTION: A rotary type drying device comprises a bottom frame, a dryer assembly, a driving member, a grinding unit, an input unit, air supply and inhalation pipes, and an inducement pipe. The grinding unit is installed on one side of the bottom frame and grinds a non-drying material into a fine particle. The air supply and the inhalation pipes are individually installed on both ends of the dryer assembly for supplying and inhaling the hot air inside the dryer assembly. The inducement pipe is formed to be communicated to one end of the air supply pipe.

Description

ROTARY TYPE DRY APPARATUS AND DRY METHOD THEREOF

The present invention relates to a rotary type drying apparatus and a method for drying a dried material, and more particularly, to dry a dried material such as silica having a high moisture content without using a multistage drying apparatus, and using a dryer having a compact structure and a continuous single unit. The present invention relates to a nanoporous silica drying apparatus and a drying method capable of drying a dry material such as silica having an optimal water content as a result of securing an appropriate drying time through a process.

Recently, various types of drying apparatuses for drying the moisture-containing material to be dried have been proposed. Usually, in the case of the cylindrical rotary drying device, the drying material is supplied from one end of a rotating cylinder to blow dry hot air from one end into the cylinder until the discharge from the other end, and the drying operation is finished. One-stage drying apparatus for discharging is known. Such a single stage drying apparatus is required to improve drying efficiency and drying time in a primitive form.

A radial drying apparatus has been proposed to solve this problem. The radial rotary drying apparatus uses two inner cylinders and an outer cylinder, and partitions between the inner cylinder and the outer cylinder so that the material to be dried is axially partitioned according to the rotation of the cylinder. After alternately traveling in and out of one room, the dried product is discharged from one end of the inner cylinder in which the dry material is finally added.

On the other hand, silica is used in various fields throughout the industry. Silica has a higher moisture content compared to other physical properties, so that the silica is dried to have an appropriate water content according to the field used.

In particular, nanoporous silica is very sensitive to the size of the pore volume depending on the hot air temperature and the hydrothermal time at the beginning of drying. Therefore, in order to increase the pore volume, it is necessary to maximize the drying rate by initially contacting the silica powder of fine particles at a high temperature.

In addition, as mentioned above, silica has a high moisture content, so the drying time should be longer than other physical properties.

However, in the case of using the existing drying apparatus to dry the high moisture content dry material such as silica, the drying time has to be lengthened in order to have a low moisture content, so the structure of the entire drying apparatus becomes complicated and the installation area becomes large. there was.

The background art of the present invention is disclosed in Korean Patent Laid-Open Publication No. 10-2010-0029961, but the above-described problems still exist.

In order to solve the above-mentioned problems of the present invention, a dry dye such as silica having a high moisture content is used without a multi-stage drying apparatus by using a pulverizer and a compact dryer and a single continuous process. By drying, the object of the present invention is to provide a rotary type drying apparatus and a method for drying a dried material, which can secure proper drying time and improve drying efficiency through a simple and compact configuration.

In addition, it is an object of the present invention to provide a rotary type drying apparatus and a method for drying the dried material that can ensure a proper drying time and improve the drying efficiency for various kinds of dry materials having a high moisture content.

According to a first aspect of the present invention for achieving the above objects, a bottom frame; A dryer assembly rotatably installed on the bottom frame; Drive means for rotationally driving the dryer assembly; Crushing means installed on one side of the bottom frame and pulverizing the material to be dried into fine particles; Feeding means provided to feed the fine particles of the dry material pulverized by the grinding means into the dryer assembly; An air supply and an intake pipe respectively installed at both ends of the dryer assembly for supplying air and intake of hot air into the dryer assembly; And an induction pipe which is formed in communication with one end of the air supply pipe and is provided to flow in the axial direction after inducing hot air to the distal end of the feeding means.

The dryer assembly includes a cylindrical main drying drum partitioned into an inlet chamber and an outlet chamber by a closed partition member; And a plurality of sub-drying drums disposed radially on an outer circumference of the main drying drum, wherein one of the sub-drying drums of the plurality of sub-drying drums is partitioned into an inflow chamber and an outflow chamber by a partition member, and the main drying The dry material supplied to the input chamber of the drum is provided to the inlet chamber of the one sub drying drum, and sequentially from the one sub drying drum to the other sub drying drums as the main drying drum and the sub drying drum are rotated. And then provided to the outlet chamber of the one sub drying drum, and then to the outlet chamber of the main drying drum from the outlet chamber of the one sub drying drum.

In addition, the dryer assembly, as another example, the main drying drum which is open on both sides; A plurality of sub-drying drums fixed radially along the circumferential direction at the outer edge of the main drying drum; And a front cover portion and a rear cover member coupled to the main drying drum to open and close both ends of the sub-drying drum. The main drying drum is provided with an enclosed partition plate for partitioning into two spaces from an inner central part, and includes a plurality of lift plates that are spaced in the circumferential direction and extend inclined along the axial direction. The sub-drying drum is provided with a drying drum having a front opening and a rear opening having a predetermined size, and the sub-drying drum has a plurality of lift plates which are spaced in the circumferential direction and extend inclined along the axial direction. One sub-drying drum corresponding to a position at which front and rear openings of the main drying drum are formed is provided with a partition plate at an inner center thereof, and front and rear openings communicating with the front and rear openings of the main drying drum with respect to the partition plate are provided. And a plurality of sub-drying drums that are adjacent to each other. And a communication port communicating with another sub-drying drum, wherein particulates of the dry material entering through the front opening of the one sub-drying drum are one side of each sub-drying drum by the lift plate as the dryer assembly rotates. In the other side, it may include a communication port formed having a communication relationship to be alternately transmitted from the other side to one side.

The plurality of sub-drying drums are composed of N sub-drying drums (where N is a natural number of 2 or more), and the communication port formed between neighboring sub-drying drums may be alternately formed at one end and the other end.

N is 6, and the communication port communicates with each other at one end of the first sub-drying drum and the second sub-drying drum adjacent thereto and is sealed to the outside. The second communication port is formed in communication with each other at the other end of the third drying drum to be sealed to the outside, the third sub-drying drum and one end formed in the communication with each other at one end of the neighboring fourth drying drum 3 communication port, the fourth communication port formed in communication with each other at the other end of the fourth drying drum and the neighboring fifth drying drum and sealed to the outside, one end of the fifth drying drum and the sixth drying drum adjacent thereto And a fifth communication port communicating with each other and being sealed to the outside, and a sixth communication port communicating with each other at the other end of the sixth drying drum and the first drying drum adjacent thereto.

Each sub-drying drum may form a flange portion extending radially outward from the outer edge, and the edges of the front and rear cover members may be fixedly coupled to the flange portion.

One of the front and rear cover members is preferably provided with a detachable or openable access door at a position corresponding to the openings at both ends of the sub-drying drum.

The drive means may include a drive motor, a tire fixed around the outer periphery of both ends of the sub-drying drum, a roller bracket having a roller rotatably supporting the tire, and one end of the drive motor and the dryer assembly. One end of the main drying drum may include driving and driven sprocket wheels respectively installed on the outer edge.

The apparatus may further include a rotary drum having open at both ends fixed around the outer side of the sub-drying drum, and both ends of the rotary drum may be provided with flange portions extending radially outwardly, and the front and rear cover members may be formed in the flange portion. Is fixed, the drive means may include a roller motor having a drive motor, a reduction gear box connected to the drive shaft of the drive motor, and a roller in contact with the rotating drum.

According to a second aspect of the present invention, there is provided a drying method for drying a dry material, comprising: grinding the dry material; Entering a dryer assembly for drying the fine particles of the pulverized material to be dried; Providing hot air to the dryer assembly, followed by induction of hot air blowing to the fine particles of the dry material to be introduced into the dryer assembly to perform primary heat exchange and then to dry in the axial direction of the dryer assembly for secondary drying; Exhausting the hot air heat exchanged from the dryer assembly to the outside; It provides a dry material drying method comprising discharging the particles of the dry material dried in the dryer assembly to the outside.

In order to perform the secondary drying, the dryer assembly includes a cylindrical main drying drum and a plurality of sub drying drums radially fixed and closed at both ends of the main drying drum, the secondary in the dryer assembly. Drying is carried out from the main drying drum to one sub-drying drum, where the particles of the dry material are moved, and another sub-drying drum to which the fine particles of the dry material provided from one sub-drying drum is adjacent as the dryer assembly rotates. They may be sequentially dried from one side to the other side and the other side to be alternately transported and dropped to return to the main drying drum.

Further, as another example, the main drying drum is provided as a cylindrical drying drum partitioned into the input chamber and the discharge chamber by a sealed partition member for carrying out the secondary drying, and one of the plurality of sub drying drums is provided. The sub drying drum is partitioned into an inflow chamber and an outflow chamber by a partition member, and particulates of the dry material supplied to the input chamber of the main drying drum are provided to the inflow chamber of the one sub drying drum, In turn from one subdrying drum to another subdrying drum sequentially and then back to the outlet chamber of the one subdrying drum, and then discharge of the main dry drum from the outlet chamber of the one subdrying drum Particles of the material to be dried are transferred through a communication port formed to have a communication relationship to the chamber. Can be adjusted.

In addition, the main drying drum is provided with a sealed partition plate for dividing the interior into two spaces for carrying out the secondary drying, and there are a plurality of lift plates which are spaced in the circumferential direction and inclined along the axial direction. And a drying drum having a front opening and a rear opening having a predetermined size formed in front and rear with respect to the partition plate, wherein the sub-drying drum has a plurality of lifts which are spaced in the circumferential direction and inclined along the axial direction. The sub-drying drum is provided with a plate, and the sub-drying drum corresponding to the position at which the front and rear openings of the main drying drum are formed is provided with a partition plate at an inner central part, and the front and rear of the main drying drum with respect to the partition plate. Provided as a drying drum in which front and rear openings are formed in communication with the openings; The plurality of sub-drying drums have a communication port communicating with another neighboring sub-drying drum, wherein the fine particles of the dry material coming in through the front opening of the one sub-drying drum are moved by the lift plate as the dryer assembly rotates. In each sub-drying drum, the fine particles of the dry material may be moved and dried through a communication port having a communication relationship to be alternately transferred from one side to the other side and the other side to the one side.

Rotary type drying apparatus and dried material drying method according to the present invention can be dried to have an optimum moisture content through a single process and a device of a compact structure for a variety of dry materials including a high moisture-containing silica, etc. It works.

In addition, the present invention has the effect that it is possible to select a dry blowing method to efficiently dry the dried material such as product properties and high residual moisture content suitable for the field to be applied in a single device.

In addition, according to the present invention, it is possible to implement a compact dryer, it is easy to clean after the completion of the drying operation is excellent in maintenance.

1 is a configuration diagram schematically showing the overall configuration of a rotary type drying apparatus according to a preferred embodiment of the present invention.
Figure 2 is a side view and a front view schematically showing the configuration of the multi-chamber combination dryer assembly constituting the rotary type drying apparatus according to the present invention.
3 is a front view illustrating a state in which the multi-chambered dryer assembly is rotated 180 ° in the front view of FIG. 2.
4 is an exploded view illustrating the communication relationship between the sub-drying drum constituting the multi-chamber combination dryer assembly constituting the rotary type drying apparatus according to the present invention.
5 is a side view illustrating the communication relationship between the sub drying drum constituting the multi-chamber combination dryer assembly constituting the rotary type drying apparatus according to the present invention.
6 is a view showing a form in which the particles of the dry material flows in the sub drying drum of the dryer assembly of the rotary type drying apparatus according to the present invention.
FIG. 7 is a cross-sectional view illustrating one sub-drying drum corresponding to a position at which front and rear openings of the main drying drum are formed, and a partition plate and a lift plate formed in the main drying drum.
8 is a cross-sectional view illustrating a configuration of a lift plate formed inside the remaining sub-drying drums except for one sub-drying drum corresponding to a position at which front and rear openings of the main dry drum are formed.

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 from the shapes of the illustrations, for example changes in tolerances, are those that can 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.

Rotary type drying apparatus according to the present invention, the bottom frame; A dryer assembly rotatably installed on the bottom frame; Drive means installed at one side of the bottom frame to drive the dryer assembly; Crushing means provided on the other side of the bottom frame, for pulverizing the material to be dried into fine particles; Injecting means provided at at least one end of the dryer assembly to inject the fine particles of the dry material pulverized by the grinding means into the dryer assembly; An air supply and an intake pipe respectively installed at both ends of the dryer assembly to provide hot air into the dryer assembly; And an induction pipe which is formed in communication with one end of the air supply pipe and is formed to flow in the axial direction after inducing hot air to the distal end of the feeding means.

The induction pipe is characterized in that it is installed detachably to one end of the air supply pipe.

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

1 is a configuration diagram schematically showing the overall configuration of a rotary type drying apparatus according to a preferred embodiment of the present invention.

Rotary type drying apparatus according to the present invention, as shown in Figure 1, the bottom frame (1); A dryer assembly (10) rotatably installed on the bottom frame (1); A driving means (20) installed at one side of the bottom frame (1) to rotationally drive the dryer assembly (10); Crushing means (30) installed on the other side of the bottom frame (1) to crush the dry material into fine particles; An input means (40) provided at at least one end of the dryer assembly (10) to inject the fine particles of the dry material pulverized by the grinding means (30) into the dryer assembly (10); Air supply and intake pipes (51, 52) respectively installed at both ends of the dryer assembly (10) to supply and intake hot air into the dryer assembly (10); And an induction pipe 60 formed to communicate with one end of the air supply pipe 51 and provided to flow in the axial direction after inducing hot air to the distal end of the feeding means 40.

A dryer assembly 10 rotatably installed on the bottom frame 1 will be described with reference to FIGS. 2 to 5.

2 is a side view and a front view schematically showing the configuration of the multi-chambered dryer assembly constituting the rotary type drying apparatus according to the present invention, Figure 3 is a state in which the multi-chambered dryer assembly 180 ° rotated in the front view of FIG. It is a front view which shows.

As shown in Figure 2 to 5, the dryer assembly 10, the main drying drum 100 is open at both ends; A plurality of sub-drying drums 210 to 260 fixed radially along the circumferential direction at the outer circumference of the main drying drum 100; And front and rear cover members 310 and 320 coupled to close the open ends of the sub-drying drums 210 to 260 and having openings at positions corresponding to both ends of the main drying drum 100.

The main drying drum 100 is formed of a cylinder having a predetermined diameter, the inner partition portion is a sealed partition plate 110 for partitioning the main drying drum 100 into a front space and a rear space (inlet chamber and outlet chamber) It prevents the wind to pass between the front space and the rear space of the main drying drum 100 to be isolated.

In addition, a plurality of lift plates 120 (representing six lift plates in the drawing) may be disposed in the partition plate 110 at predetermined intervals in the circumferential direction and inclined along the axial direction inside the main drying drum 100. It is provided in the front space and the rear space of the main drying drum 100 partitioned by each.

In addition, the main drying drum 100 is formed with a front opening 131 and a rear opening 132 of a predetermined size in the front and rear around the partition plate 110. As will be described in detail below, the material to be dried is moved through the front opening 131 to one sub-drying drum connected to the main drying drum 100, and then sequentially to other neighboring sub-drying drums. And is flowed back from the one sub drying drum to the main drying drum 100 (outflow chamber side) through the rear opening 132.

The sub-drying drums 210 to 260 are formed in a cylinder having a predetermined diameter, and have a plurality of lift plates 270 (six lift plates in the drawing) having a predetermined interval therein and extending in an inclined direction along the axial direction. Are shown). The lift plate 270

In addition, one of the sub-drying drums 210 to 260 corresponding to the positions where the front and rear openings 131 and 132 of the main drying drum 100 are formed is divided into a partition plate ( 211 is provided, and front and rear openings 212 and 213 are formed to communicate with the front and rear openings 131 and 132 of the main drying drum 100 around the sealed partition plate 110. The partition plate 211 is isolated to prevent the wind from passing between the front space and the rear space of the sub-drying drum (210).

At this time, the main drying drum 100 inside the one of the sub-drying drum 210 corresponding to the position where the front and rear openings 131 and 132 of the main drying drum 100 are formed among the sub-drying drums 210 to 260. As shown in FIG. 2, a plurality of lift plates 270 (see FIG. 2; six lift plates in the drawing) are provided in the front space and the rear space of the sub-drying drum 210 partitioned by the partition plate 211. Each is provided. Since the partition plate 211 is not formed in the other sub-drying drums 220-260, the lift plate 270 extends inclined from one side to the other side or the other side to one side to conform to the moving direction of the material to be dried. .

FIG. 7 illustrates one sub-drying drum (first sub-drying drum 210 to be described later) corresponding to a position at which front and rear openings 131 and 132 of the main drying drum 100 are formed among the sub-drying drums 210 to 260. And cross-sectional views of the partition plates 110 and 211 and the lift plates 110 and 211 formed in the main drying drum 100, and FIG. 8 is provided with front and rear openings 131 and 132 of the main drying drum 100. A cross-sectional view showing a configuration of the lift plate 270 formed in the remaining sub-drying drums (second to sixth sub-drying drums 220-260 described later) except for the one sub-drying drum 210 corresponding to the position.

Next, a communication relationship between neighboring sub-drying drums 210 to 260 will be described with reference to FIGS. 4 and 5. 4 is an exploded view illustrating the communication relationship of the sub drying drum constituting the multi-chamber combination dryer assembly constituting the nano-porous silica drying apparatus according to the present invention, Figure 5 is a nano-porous silica drying according to the present invention It is a side view which shows in order to demonstrate the communication relationship of the sub drying drum which comprises the multi-chamber combination dryer assembly which comprises an apparatus. In the description, the first to sixth sub-drying drums will be described to distinguish each sub-drying drum.

The communication relationship between the sub-drying drums of the dryer assembly of the rotary type drying apparatus according to the present invention includes a communication port communicating with other servo-drying drums adjacent to each other, and the material to be dried through the front opening of one sub-drying drum. Is provided with a communication port formed to have a communication relationship to be transferred alternately from one side to the other side, the other side to one side of each sub-drying drum in accordance with the rotation of the main and sub-drying drum. In other words, the plurality of sub-drying drums are composed of N sub-drying drums (wherein N is a natural number of 2 or more) (6 in the drawing), and the communication port is formed between neighboring sub-drying drums. The communication port is alternately formed at one end and the other end.

Specifically, as an embodiment, when composed of six sub-drying drums, the communication port by the communication relationship formed at this time will be described.

One end of the first sub-drying drum 210 and the second sub-drying drum 220 adjacent thereto having front and rear openings 212 and 213 communicating with the front and rear openings 131 and 132 of the main drying drum 100. A first communication port 410 communicating with each other is formed (left end in the drawing). A second communication port 420 communicating with each other is formed at the other end (right end in the drawing) of the second sub-drying drum 220 and the third sub-drying drum 230 adjacent thereto. In addition, a third communication port 430 communicating with each other is formed at one end of the third sub-drying drum 230 and the fourth sub-drying drum 240 adjacent thereto. A fourth communication port 440 communicating with each other is formed at the other end of the fourth sub-drying drum 240 and the fifth sub-drying drum 250 adjacent thereto. A fifth communication port 450 communicating with each other is formed at one end of the fifth sub-drying drum 250 and the sixth sub-drying drum 260 adjacent thereto. A sixth communication port 460 communicating with each other is formed at the other end of the sixth sub-drying drum 260 and the first sub-drying drum 210 adjacent thereto.

That is, the dry material introduced into the front space of the main drying drum 100 may include the front opening 131 of the main drying drum, the front opening 212 of the first sub drying drum, and the first sub drying drum 210. Front space, the first communication port 410, the second sub-drying drum 220, the second communication port 420, the third sub-drying drum 230, the third communication port 430, the fourth sub-drying drum 240, a fourth communication port 440, a fifth sub-drying drum 250, a fifth communication port 450, a sixth sub-drying drum 260, a sixth communication port 460, and a first sub-drying The rear space of the drum 210, the rear opening 213 of the first sub-drying drum, the rear opening 132 of the main drying drum, and the rear space of the main giant drum 100 are sequentially moved (as shown in FIG. 4). Arrow).

It is apparent that the openings between the openings and the communication ports may be formed through a communication path that is closely bonded or sealed to the outside so that the dry material to be moved may not leak.

An operation of transferring the material to be dried through each communication port 410-260 formed in each of the sub-drying drums 210-260 will be described later.

Next, the front and rear cover members 310 and 320 are formed in a circular plate. The front and rear cover members 310 and 320 are formed with flange portions 111 extending radially outwardly from the outer edges of the respective sub-drying drums 210 to 260, and the front and rear cover members 310 are formed. , 320 may be configured to be fixed to the flange portion 111.

In addition, any one of the front and rear cover members (310, 320) is an access door (not shown) detachably or openable in a position corresponding to the opening of the sub-drying drum (210-260) It may be provided.

Through such access doors, the drying process can be observed during use, and after completion of use, the maintenance of the sub-drying drum is facilitated after the access door is detached or opened.

Next, the driving means 20 for rotating the dryer assembly 10 is a tire 21 fixed around the outer edges of both ends of the sub-drying drums 210-260 of the dryer assembly 10. A roller bracket 23 on which a roller 22 rotatably supporting the tire 21 is installed, a drive motor 24 for providing a driving force, one end of the drive motor 24 and the dryer assembly ( 10) drive and driven sprocket wheels 25 and 26 respectively installed at one end of the main drying drum 100.

The driving means 20 is not limited to the above-described embodiment, and may be configured in various ways as long as it can rotate the dryer assembly 10. As another example, the drive means 20 may be configured such that the drive shaft of the drive motor directly drives the roller of the roller bracket through the reduction gear box.

In addition, in the present invention, the sub-drying drums 210 to 260 may be fixed to rotating drums (not shown) which are open on both sides of the outer drum, and at both ends of the rotating drums, flanges extending radially outward are formed. The front and rear cover members 310 and 320 may be fixed to the flange portion.

Here, the drive means 20 may include a contact roller in direct contact with the rotating drum, the rotational force of the drive shaft of the drive motor is transmitted to the contact roller through the reduction gear box can be configured to rotate the rotating drum. .

Next, the grinding means 30 for grinding the dry material into fine particles is not particularly limited as long as it is a means or an apparatus capable of grinding the dry material such as silica into fine particles.

The fine particles of the dry material pulverized by the crushing means 30 are provided to the feeding means 40 through a chute 31. One end of the dosing means 40 is preferably provided with a hopper 41.

The feeding means 40 is not particularly limited as long as it is a configuration capable of transferring the dried material pulverized into the dryer assembly 10. The feeding means 40 shown in the figure shows an example of a conveying screw conveying method. As another example, the input means 40 may be configured by a conveyor belt transfer method.

Although the input means 40 shows the example provided in one side end (left end) in the figure, it may be provided in the other end (right end). In other words, when the dosing means 40 is provided at one end, the hot air blowing direction and the dosing direction of the fine particles of the dry material are dried by the same co-current drying method, and the dosing means 40 is provided at the other end. In this case, it can be dried by a countercurrent drying method in which the direction of hot air blowing and the direction in which the fine particles to be dried are opposed. Preferably, in the present invention, it is preferable to apply a co-current drying method in order to perform a high temperature drying hot air and a rapid heat exchange at the initial stage of adding the dry material.

Next, the air supply pipe 51 connected to the external hot air supply device is provided on the side where the input means 40 is located, and the air intake pipe 52 connected to the external air intake device faces the air supply pipe. It is provided at the end of the main drying drum of the dryer assembly on the side.

Subsequently, the induction pipe 60 communicates with one end of the air supply pipe 51, induces hot air to the distal end of the inlet means 40, and is provided to flow in the axial direction. Since the fine particles of the pulverized dry material introduced into the dryer assembly 10 by the 40) have a high water content, they are provided at the distal end of the feeding means 40 so as to perform heat exchange in a short time by hot hot air at the beginning of the feeding. .

It is preferable that the induction pipe 60 is formed integrally with the distal end of the air supply pipe 51 and is configured such that the distal end of the feeding means 40 is located therein.

The operation of the rotary type drying apparatus according to the present invention configured as described above will be described. At this time, it is obvious that the material to be dried may include various materials such as silica. Hereinafter, the nanoporous silica having a high moisture content will be described as a material to be dried for more detailed description.

Silica is thrown into the grinding means 30 and pulverized, and the pulverized silica fine particles fall along the chute 31 and are provided to one end of the feeding means 40 through the hopper 41.

The silica fine particles provided to the dosing means 40 are transferred by the dosing means 40 and flow into the main drying drum 100 of the dryer assembly 10.

At this time, the hot air supplied by the external hot air supply device is guided to the induction pipe 60 via the intake pipe 51. The high temperature hot air guided to the induction pipe 60 is subjected to high temperature heat exchange with the initial silica particles introduced into the main drying drum 100 of the dryer assembly 10 at the distal end of the charging means 40, and thus silica. The water content of the microparticles is greatly lowered primarily.

As such, the silica fine particles heat-exchanged with the hot air at the initial stage of introduction are introduced into the main drying drum 100 of the dryer assembly 10. The following describes the drying operation performed by the dryer assembly 10. FIG. 6 is a view illustrating a form in which silica fine particles flow in a sub drying drum of a dryer assembly of a rotary type drying apparatus according to the present invention.

The silica fine particles introduced into the main drying drum 110 are located in the front space partitioned by the partition plate 110. In this state, as the main drying drum 110 and the sub drying drums 210 to 260 are rotated by the driving means 20, at one end of the front space of the main drying drum 110 (the left end in the drawing). The positioned silica fine particles are moved to the right side by the lift plate 120 extending obliquely along the axial direction, and the silica fine particles reaching the other end of the front space communicate with the front opening 131 of the main drying drum 110. The falling through the front opening 212 to the sub-drying drum (210).

The silica fine particles moved to the sub-drying drum 210 are located at the other end (right end) of the front space of the sub-drying drum 210 partitioned by the partition plate 211.

Subsequently, as the sub-drying drums 210 to 260 rotate, silica fine particles located at the other end of the front space of the sub-drying drum 210 are transferred to the left side by the lift plate 270 and moved to the left end thereof. The transported silica fine particles fall down to the second sub-drying drum 220 through the first communication port 410 of the first and second sub-drying drums 210 and 220.

Afterwards, the silica fine particles dropped and moved to the second sub drying drum 220 are moved to the right again by the rotation of the drying drum, and the silica fine particles transferred to the right end thereof are separated from the second and third sub drying drums 220 and 230. Falling to the third sub-drying drum 230 through the second communication port 420.

Subsequent rotations cause the silica fine particles to alternately transfer to the right and left, left and right sides of the third to sixth sub-drying drums 230 to 260 and drop movement through each communication port 430 to 460. The sub-drying drum flows back into the neighboring first sub-drying drum 210. The silica fine particles introduced into the first sub-drying drum 210 are located in the rear space of the first sub-drying drum 210, and the silica fine particles located in the rear space are left end of the rear space by the rotation of the drying drum. It is transferred to the final through the rear opening 213 and the rear opening 132 of the main drying drum 110 formed therein into the rear space (outflow chamber) of the main drying drum 110.

The finally introduced silica fine particles are sequentially transferred left and right alternately and ensure sufficient drying time in the process of dropping to neighboring sub-drying drums.

The dried material introduced into the rear space of the main drying drum 110 is transferred to the right end of the rear space by the lift plate 120 and is discharged according to rotation.

As described above, the description of the operation of the rotary type drying apparatus according to the present invention is directed to the direction in which the silica particles move and the blowing direction of the drying hot air are in the same direction (left to right in the drawing), that is, the material moving direction It is a cocurrent drying method with the same hot wind recovery direction.

Optionally, when the dryer assembly of the rotary type drying apparatus of the present invention is rotated counterclockwise, the silica fine particles are injected from the right side and the hot air blowing is provided from the left side, the silica fine particles are discharged from the left end, so that the silica fine particles A countercurrent drying method may be implemented in which the moving direction and the drying hot air are opposite to the blowing direction.

Therefore, the rotary type drying apparatus of the present invention can selectively implement a cocurrent drying method and a countercurrent drying method according to the characteristics of the material to be dried and the desired moisture residual content even with a single dryer.

When explaining the dry material drying method according to the present invention, as a drying method for drying the dry material such as nano-porous silica, the dry material is pulverized; Entering a dryer assembly for drying the fine particles of the pulverized material to be dried; Providing hot air to the dryer assembly, followed by induction of hot air blowing to the fine particles of the dry material to be introduced into the dryer assembly for primary heat exchange, followed by secondary drying by flowing in the axial direction of the dryer assembly; Exhausting the hot air heat exchanged from the dryer assembly to the outside; And discharging particulates of the dried material dried in the dryer assembly to the outside.

In order to perform the secondary drying, the dryer assembly includes a cylindrical main drying drum and a plurality of sub drying drums radially fixed and closed at both ends of the main drying drum, the secondary in the dryer assembly. Drying is carried out from the main drying drum to one sub-drying drum, where the particles of the dry material are moved, and another sub-drying drum to which the fine particles of the dry material provided from one sub-drying drum is adjacent as the dryer assembly rotates. They are sequentially transported and dropped in one side to the other side, and the other side to one side, and dried to return to the final main drying drum.

In other words, the main drying drum is provided as a cylindrical drying drum partitioned into an inlet chamber and an outlet chamber by a sealed partition member, and one of the plurality of subdrying drums is connected to the inlet chamber by the partition member. Particles of the dry material supplied to the input chamber of the main drying drum are partitioned into an outlet chamber and provided to the inlet chamber of the one sub drying drum, and the other one of the sub drying drums is rotated according to the rotation of the dryer assembly. A communication port provided sequentially to the sub-drying drums and then again provided to the outflow chamber of the one sub-drying drum, and having a communication relationship provided from the outflow chamber of the one sub-drying drum to the discharge chamber of the main dry drum. Particles of the material to be dried are moved through and dried.

Specifically, the main drying drum is provided with a sealed partition plate for dividing the interior into two spaces, the interior of the main drying drum is provided with a plurality of lift plates that are spaced in the circumferential direction and inclined along the axial direction, the center of the partition plate And a drying drum having a front opening and a rear opening having a predetermined size in front and rear, and the sub drying drum is provided with a plurality of lift plates that are spaced in the circumferential direction and inclined along the axial direction. One sub-drying drum corresponding to the position in which the front and rear openings of the main drying drum are formed in the drum has a partition plate at an inner center thereof, and the front and rear communicating with the front and rear openings of the main drying drum about the partition plate. It is provided as a drying drum, the opening is formed, the plurality of sub-drying drum And a communication port communicating with another sub-drying drum, wherein particulates of the dry material entering through the front opening of the one sub-drying drum are lifted from one side of each sub-drying drum by a lift plate as the dryer assembly rotates. On the other side, the fine particles of the material to be dried are moved and dried through a communication port having a communication relationship to be alternately transmitted from the other side to one side.

The dry material drying method having the above structure has an effect of efficiently drying the dry material even when nanoporous silica or the like having a high moisture content is used as the dry material.

Rotary type drying apparatus and dry material drying method according to the present invention is preliminarily pulverized silica having a relatively high moisture content, the fine particles of the pulverized dry material is subjected to high temperature hot air and heat exchange at the beginning of the injection, It can be dried sequentially and alternately through the sub-drying drum, so that the drying efficiency of the material to be dried can be increased and the drying time can be shortened. It can be reduced to implement a compact drying apparatus and drying method.

In addition, the present invention can select the dry blowing method according to the product properties and the residual moisture content of the material to be dried in a single drying device can be expanded the product applicability.

And according to the invention, it is easy to clean after the completion of the drying operation is excellent in maintenance.

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.

1: Floor frame
10: dryer assembly
20: drive means
30: grinding means
40: input means
51, 52: piping
60: induction piping
100: main drying drum
110, 211: partition plate
111: flange
131, 132: opening
120, 270: lift plate
210-260: Sub Dry Drum
212, 213: opening
310, 320: cover member
410-460: communication port

Claims (13)

Floor frame;
A dryer assembly rotatably installed on the bottom frame;
Drive means for rotationally driving the dryer assembly;
Crushing means installed on one side of the bottom frame and pulverizing the material to be dried into fine particles;
Feeding means provided to feed the fine particles of the dry material pulverized by the grinding means into the dryer assembly;
An air supply and an intake pipe respectively installed at both ends of the dryer assembly for supplying air and intake of hot air into the dryer assembly; And
Rotary type drying apparatus is formed in communication with one end of the air supply pipe, the induction pipe is provided to flow in the axial direction after inducing hot air to the distal end of the input means. The method of claim 1,
The dryer assembly includes a cylindrical main drying drum partitioned into an inlet chamber and an outlet chamber by a closed partition member; And a plurality of sub-drying drums disposed radially on an outer circumference of the main drying drum.
One sub-drying drum of the plurality of sub-drying drums is partitioned into the inlet chamber and the outflow chamber by the partition member, and the dry material supplied to the inlet chamber of the main dry drum is the inlet chamber of the one sub-drying drum. Provided, sequentially provided from the one sub drying drum to the other sub drying drums according to the rotation of the main drying drum and the sub drying drum, and then again provided to the outflow chamber of the one sub drying drum, and then the one sub Rotary type drying apparatus to be provided from the discharge chamber of the drying drum to the discharge chamber of the main drying drum. The method of claim 1,
The dryer assembly includes a main drying drum open at both sides; A plurality of sub-drying drums fixed radially along the circumferential direction at the outer edge of the main drying drum; And a front cover portion and a rear cover member coupled to the main drying drum to open and close both ends of the sub-drying drum.
The main drying drum is provided with an enclosed partition plate for partitioning into two spaces from an inner central part, and includes a plurality of lift plates that are spaced in the circumferential direction and extend inclined along the axial direction. The sub-drying drum is provided with a drying drum having a front opening and a rear opening having a predetermined size, and the sub-drying drum has a plurality of lift plates which are spaced in the circumferential direction and extend inclined along the axial direction. One sub-drying drum corresponding to a position at which front and rear openings of the main drying drum are formed is provided with a partition plate at an inner center thereof, and front and rear openings communicating with the front and rear openings of the main drying drum with respect to the partition plate are provided. And a plurality of sub-drying drums that are adjacent to each other. And a communication port communicating with another sub-drying drum, wherein particulates of the dry material entering through the front opening of the one sub-drying drum are one side of each sub-drying drum by the lift plate as the dryer assembly rotates. Rotary type drying apparatus comprising a communication port formed in a communication relationship to be alternately transferred from one side to the other side, from the other side. The method according to claim 2 or 3,
The plurality of sub-drying drums are composed of N sub-drying drums (where N is a natural number of 2 or more),
The communication port is formed between the neighboring sub-drying drum is a rotary type drying device is formed alternately on one end and the other end. 5. The method of claim 4,
N is 6,
The communication port,
A first communication port formed in communication with each other at one end of the first sub-drying drum and the second sub-drying drum adjacent thereto and closed to the outside;
A second communication port formed in communication with each other at the other end of the second sub-drying drum and the third drying drum adjacent thereto and closed with the outside;
A third communication port formed in communication with each other at one end of the third sub-drying drum and the neighboring fourth drying drum and being sealed to the outside;
A fourth communication port formed in communication with each other at the other end of the fourth drying drum and the fifth drying drum adjacent thereto and closed with the outside;
A fifth communication port formed in communication with each other at one end of the fifth drying drum and the sixth drying drum adjacent thereto and closed with the outside; and
And a sixth communication port communicating with each other at the other end of the sixth drying drum and the first drying drum adjacent thereto. The method of claim 3,
Each of the sub-drying drum forms a flange portion extending radially outward from the outer edge,
Edges of the front and rear cover member is fixed to the flange type rotary device. The method according to claim 3 or 6,
Any one of the front and rear cover member is provided with a removable or open access door in a position corresponding to the opening of both ends of the sub-drying drum. The method of claim 3,
The drive means
Drive motor,
Tires fixed around outer edges of both ends of the sub-drying drum,
A roller bracket having a roller rotatably supporting the tire, and
Rotary type drying apparatus comprising a drive and driven sprocket wheel is installed on one end of the drive motor and one end of the main drying drum of the dryer assembly. The method of claim 3,
And a rotary drum having open at both ends fixed around the outer side of the sub-drying drum, and at both edges of the rotary drum, a flange portion extending radially outward is formed, and the front and rear cover members are fixed to the flange portion. Become,
And the drive means comprises a drive motor, a reduction gear box connected to a drive shaft of the drive motor, and a roller bracket having a roller in contact with the rotating drum. As a drying method for drying the dry material,
Grinding the dry material;
Entering a dryer assembly for drying the fine particles of the pulverized material to be dried;
Providing hot air to the dryer assembly, followed by induction of hot air blowing to the fine particles of the dry material to be introduced into the dryer assembly to perform primary heat exchange and then to dry in the axial direction of the dryer assembly for secondary drying;
Exhausting the hot air heat exchanged from the dryer assembly to the outside;
Drying material drying method comprising discharging the fine particles of the dry material dried in the dryer assembly to the outside. The method of claim 10,
In order to perform the secondary drying, the dryer assembly includes a cylindrical main drying drum and a plurality of sub drying drums radially fixed and closed at both ends of the main drying drum,
Secondary drying in the dryer assembly is the fine particles of the dry material to be transferred from the main drying drum to one sub-drying drum, and provided from one sub-drying drum as the dryer assembly rotates. The method for drying the dried material to dry the neighboring sub-drying drums are sequentially transferred from one side to the other side and the other side to one side to be returned to the main drying drum. The method of claim 10,
In order to perform the secondary drying, the main drying drum is provided as a cylindrical drying drum partitioned into an input chamber and an discharge chamber by a closed partition member, and one sub drying drum of the plurality of sub drying drums is a partition member. And the dry matter particulates supplied to the input chamber of the main drying drum are provided to the inlet chamber of the one sub drying drum by the rotation of the dryer assembly. A communication relationship is provided sequentially from the drying drum to the other sub-drying drums and then back to the outflow chamber of the one sub-drying drum, and then provided to the discharge chamber of the main drying drum from the outflow chamber of the one sub-drying drum. Drying material to be dried by moving the fine particles of the dry material through a communication hole formed to have Way. The method of claim 10,
In order to perform the secondary drying, the main drying drum is provided with a closed partition plate for dividing the interior into two spaces, and has a plurality of lift plates therein spaced in the circumferential direction and inclined along the axial direction. It is provided as a drying drum in which a front opening and a rear opening of a predetermined size are formed in the front and rear around the partition plate, and the sub drying drum has a plurality of lift plates that are spaced in the circumferential direction and inclined along the axial direction. One sub-drying drum corresponding to a position at which front and rear openings of the main drying drum are formed among the sub-drying drums includes a partition plate at an inner center thereof, and a front and rear openings of the main drying drum with respect to the partition plate. It is provided as a drying drum which is formed in communication with the front and rear openings, the plurality The sub-drying drum has a communication port communicating with another neighboring sub-drying drum, wherein the particles of the dry material coming in through the front opening of the one sub-drying drum are moved by the lift plate according to the rotation of the dryer assembly. The dry material drying method in which the fine particles of the dry material are moved and dried through a communication port having a communication relationship that is alternately transferred from one side to the other side and the other side to the one side in the sub-drying drum.

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