KR102030961B1 - Fine material supply device - Google Patents

Abstract

The present invention relates to pulverized raw material supply equipment and, more specifically, to pulverized raw material supply equipment including: a storage unit which stores fine power raw materials; a mixing unit which mixes the pulverized raw materials of the storage unit and store the mixture; a ring blower which is to generate vacuum; a raw material transferring unit which generates a cyclone phenomenon inside when the vacuum is generated by the ring blower, temporarily stores the pulverized raw materials of the storage unit, and supplies the pulverized raw materials to the mixing unit; a raw material collecting unit which collects pulverized raw materials from air passing through the raw material transferring unit to supply the collected pulverized raw materials to the mixing unit; and a control unit which controls the ring blower, the raw material transferring unit and the raw material collecting unit. The present invention is able to prevent and minimize environmental pollution in surrounding areas by filtering dust and fine dust generated from pulverized raw materials while easily transferring a large amount of stored pulverized raw materials to the mixing unit.

Description

Fine material supply device

The present invention relates to a supply apparatus, and more particularly, it is possible to easily transfer the fine powder to the mixing unit provided at a high position by using the air suction input to improve the transfer efficiency, dust and fine dust generated during the transfer The present invention relates to a fine raw material supply device capable of treating and minimizing contamination.

In general, the hopper loader is mainly used to transport materials having small particles, and is widely used as a means for supplying raw materials in an injection factory, a grain warehouse, a pharmaceutical factory, and the like.

In one embodiment, when used in the injection factory, the suction of the synthetic resin contained in the reservoir as the suction force of the suction fan with the suction air, and the suction air and the synthetic resin raw material is separated by a filter installed on the suction path therein, the suction air Is discharged to the outside and synthetic resin raw materials have been installed and used to feed the hopper installed in the injection machine.

Conventionally, the hopper rodder sucks and separates the suction air and the synthetic resin raw material, as disclosed in Korean Patent Publication No. 10-2005-0063256, and supplies the separated synthetic resin raw material to the hopper for the injection machine.

However, as the conventional hopper rod is directly caught on the filter, there is a problem that the work efficiency decreases by repeatedly using the filter after the filter is maintained after the filter is blocked.

Accordingly, there is an urgent need for the development of a technology capable of easily transporting raw materials, as well as increasing maintenance work intervals and improving work efficiency according to raw material transport.

Accordingly, the present invention has been made to solve the above problems, a storage unit for storing the fine powder, a mixing unit for mixing and storing the fine powder of the storage unit, a ring blower for generating a vacuum, the ring blower When the vacuum is generated, a cyclone phenomenon is generated inside the raw material transfer unit for temporarily storing the fine powder of the storage unit to supply to the mixing unit, recovering the fine powder from the air passing through the raw material transfer unit to supply to the mixing unit A raw material recovery unit, and a ring blower, a raw material transfer unit, a control unit for controlling the raw material recovery unit, to easily transfer a large amount of stored fine raw materials to the mixing unit, and to filter the dust and fine dust generated from the fine raw materials It is an object of the present invention to provide a fine raw material feeder that can prevent and minimize contamination.

The present invention for achieving the above object is, a storage unit for storing the fine raw material, a mixing unit for mixing and storing the fine powder of the storage unit, a ring blower for generating a vacuum, when the vacuum is generated by the ring blower, A raw material conveying unit for temporarily storing the fine powder of the storage unit and supplying it to the mixing unit, a raw material recovering unit for recovering the fine powder from the air passing through the raw material conveying unit, and supplying it to the mixing unit, and the ring And a control unit for controlling the blower, the raw material conveying unit, and the raw material recovering unit.

Preferably, the raw material conveying portion, a transfer tank having a transfer space therein, has a flexibility, one end is located in the storage portion, the other end is a transfer suction pipe is located in the transfer tank,

It has flexibility and is controlled by a transfer connecting tube for connecting the air and the fine raw material passed through the transfer screen to the raw material recovery unit, and the control unit, opening and closing the transfer space part to supply the temporarily stored fine raw material to the mixing unit And a transfer valve, wherein the other end of the transfer suction pipe is positioned to face the inner side of the transfer space so that the sucked fine raw material is rotated along the inner side of the transfer space to form a cyclone.

And one end of the transfer pipe is connected to the upper end of the transfer tank, the transfer screen is formed at the end of the transfer connection pipe.

The raw material transfer unit may further include a transfer filter unit provided in the transfer tank to temporarily filter some of the finely divided raw materials transported together with the air sucked into the raw material recovery unit, to temporarily store in the transfer space.

The transfer filter unit may include a transfer filter frame provided in the transfer tank through a central portion thereof so that one end of the transfer connection pipe may be positioned therein, and provided at the transfer filter frame to cover one end of the transfer connection pipe. Feed filter net, having a plurality of feed filter blades on the outside of the upper end, the feed filter blades are provided to be rotatable in the feed filter frame, a plurality of feed filter blades are provided at regular intervals along the outer peripheral surface of the lower end of the feed filter blades A feed filter roller for rotatable along a feed filter frame, a plurality of feed filter rollers are provided between the feed filter frame and the feed filter blades, and are formed to protrude on the feed filter blocks to be moved up and down by the feed filter rollers. Transfer filter hammer rod for hitting the transfer filter network, and the transfer filter roller And a conveying pressurizing portion for pressurizing the conveying filter block and the conveying filter striking rod which are moved upward by the lower side. When the air is sucked by the ring blower, the conveying filter blades are rotated to convey the plurality of conveying parts. As the filter roller is rotated along the transfer filter frame, the plurality of transfer filter blocks and the transfer filter strike rods are sequentially moved upward, and the transfer filter strike rods moved upwards are moved downward by the elastic force of the transfer pressurization unit. The fine powder is dropped by striking the transfer filter net.

In addition, the raw material recovery unit, a recovery tank formed therein for recovering the fine raw material introduced with the air through the transfer connecting pipe, the recovery tank is provided in the recovery tank and transported with the air sucked into the ring blower A bag filter unit for filtering the fine raw material is controlled, the control unit, a bellows pulse unit for separating the filtered fine powder by generating a pulse inside the bag filter unit, has a flexibility, one end is in the recovery tank And a recovery valve connected to the other end connected to the ring blower, controlled by the controller, a recovery valve for supplying the recovered raw material to the mixing unit by opening and closing the recovery space part, wherein the bellows water part When separating the filtered raw material filtered by the bag filter by generating a pulse in the state that the ring blower is stopped operation The.

The bag filter part is positioned at an upper center portion of the recovery tank so as to be spaced apart from an inner surface of the recovery space part, and one end of the recovery discharge pipe is provided to be located inside the bag filter part.

In addition, the ring blower, a blower body having a rotating space portion therein, a blower wing portion having a plurality of wings along the edge, rotatably provided in the rotating space portion, a blower driving motor for rotating the blower wings, And a discharge tube for discharging air to the outside of the rotary space part, and after the air flows into the rotary space part through the recovery discharge tube by a blower wing part rotated by the blower driving motor, the discharge tube. As it is discharged to, the fine raw material of the storage unit is transferred to the mixing unit.

And a blower filter unit for filtering the air discharged through the ring blower.

In addition, the blower filter unit separates the foreign matter contained in the air discharged provided in the discharge pipe.

The blower filter unit includes a HEPA filter for primary filtering the air discharged through the discharge pipe, and an activated carbon filter for secondary filtering the air filtered primarily through the HEPA filter.

As described above, according to the fine powder feed device according to the present invention, it is easy to transfer a large amount of stored fine raw material to the mixing unit, to filter the dust and fine dust generated in the fine powder to prevent and minimize the environmental pollution It is a very useful and effective invention.

1 is a view showing a fine raw material supply apparatus according to the present invention,
2 is a view showing a raw material conveying unit according to the present invention,
3 is a view showing a transfer filter unit according to the present invention,
4 is a view showing a raw material conveying unit according to the present invention,
5 is a view showing a ring blower according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The detailed description, which will be given below with reference to the accompanying drawings, is intended to explain exemplary embodiments of the present invention and is not intended to represent the only embodiments in which the present invention may be practiced. The following detailed description includes specific details in order to provide a thorough understanding of the present invention. However, one of ordinary skill in the art appreciates that the present invention may be practiced without these specific details.

In some instances, well-known structures and devices may be omitted or shown in block diagram form centering on the core functions of the structures and devices in order to avoid obscuring the concepts of the present invention.

Throughout the specification, when a part is said to "comprising" (or including) a component, this means that it may further include other components, except to exclude other components unless otherwise stated. do. In addition, the term "... part" described in the specification means a unit for processing at least one function or operation. Also, "a or an", "one", "the", and the like are used differently in the context of describing the present invention (particularly in the context of the following claims). Unless otherwise indicated or clearly contradicted by context, it may be used in the sense including both the singular and the plural.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, terms to be described below are terms defined in consideration of functions in the embodiments of the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the contents throughout the specification.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view showing a fine raw material supply apparatus according to the present invention, Figure 2 is a view showing a raw material transfer unit according to the present invention, Figure 3 is a view showing a transfer filter unit according to the present invention, Figure 4 is 5 is a view illustrating a raw material conveying unit according to the present invention, and FIG. 5 is a view showing a ring blower according to the present invention.

As shown in the figure, the fine raw material supply device 10 is a storage unit 100 and mixing unit 200, ring blower 300, raw material conveying unit 400, raw material recovery unit 500 and the control unit 600 It includes.

The storage unit 100 is provided to store the fine raw material to be supplied to the mixing unit 200.

And the mixing unit 200 is for mixing and storing the fine raw material of the storage unit 100, is located above the storage unit 100.

In other words, the storage unit 100 is provided on the floor or basement so as to easily store the purchased fine raw material, the mixing unit 200 is provided so that the lower end is spaced a certain height above the ground.

The ring blower 300 is provided to generate a vacuum.

In addition, the raw material transfer part 400 is provided to supply the mixing unit 200 by temporarily storing the fine powder of the storage unit 100 is generated by the cyclone phenomenon is generated when the vacuum is generated by the ring blower (300).

The raw material recovery unit 500 is provided to recover the fine powder from the air passing through the raw material transfer unit 400 to supply to the mixing unit 200.

And the control unit 600 is provided to control the ring blower 300, the raw material conveying unit 400, the raw material recovery unit 500.

According to such a fine raw material supply device 10, the fine raw material of the storage unit 100 is easily transferred to the mixing unit 200 provided at a high position, and removes the generated dust, as well as effectively processing ultrafine dust can do.

Thus, ultrafine dust may be removed from the air discharged from the ring blower 300, thereby preventing and minimizing contamination of the surroundings of the mixing unit 200.

To this end, the raw material conveying unit 400, as shown in Figure 2, includes a transfer tank 410 and the transfer suction pipe 420, the transfer connection pipe 440 and the transfer valve 450.

The transfer tank 410 has a transfer space 412 formed therein.

And the transfer suction pipe 420 has a flexibility, one end is located in the storage unit 100, the other end is located in the transfer tank 410.

The transfer connection pipe 440 has flexibility and is provided to connect the air of the transfer space 412 and the fine powder to the raw material recovery unit 500.

In addition, the transfer valve 450 is controlled by the control unit 600, the opening and closing the transfer space 412 is provided for supplying the temporarily stored fine raw material to the mixing unit 200.

Here, the other end of the transfer suction pipe 420 is positioned to face the inner side of the transfer space 412, the sucked fine raw material is rotated along the inner side of the transfer space 412 to form a cyclone.

Thus, the sucked air and the fine raw material forms a vortex in the transfer space 412 so that a part of the fine raw material falls during the movement and is accumulated in the transfer space 412.

The remaining fine raw material is sucked into the transfer connection pipe 440 together with the air and is transferred to the raw material recovery unit 500.

Here, the transfer connection pipe 440 is connected to the upper center portion of the transfer tank 410, the transfer filter unit 430 is formed at the end of the transfer connection pipe 440.

Thus, as the fine raw materials conveyed together with the air collide with each other, the amount stored in the transfer space 412 is increased.

And the raw material feeder 400 further includes a feed filter 430.

The transfer filter unit 430 is provided in the transfer tank 410 to temporarily store some of the finely divided raw material that is transferred together with the air sucked into the raw material recovery unit 500 in the transfer space 412.

The transfer filter unit 430 is introduced into the transfer space 412 into a transfer filter network having a predetermined size of pores, and transfers the finely divided raw materials transferred to the raw material recovery unit 500 to drop the transfer space 412. Save it to

In addition, as shown in Figure 3, the feed filter unit 430 of another embodiment is a feed filter frame 431, a feed filter network 432, a feed filter blade 433, a feed filter roller 434, a feed filter Block 435, the feed filter hammer rod 436 and the feed pressing unit 437.

The transfer filter frame 431 is provided in the transfer tank 410 through the central portion so that one end of the transfer connection pipe 440 is movably positioned therein.

The feed filter net 432 is provided in the feed filter frame 431 to cover one end of the feed connecting pipe 440.

The feed filter blade part 433 has a plurality of feed filter blades 433a to the outside of the upper end and is provided to be rotatable in the feed filter frame 431.

In addition, a plurality of feed filter rollers 434 are provided along the outer circumferential surface of the lower end of the feed filter blade 433 at a predetermined interval so that the feed filter blade 433 may be rotatable along the feed filter frame 431. .

A plurality of feed filter blocks 435 are provided between the feed filter frame 431 and the feed filter blades 433a and are moved up and down by the feed filter roller 434.

The feed filter hammer rod 436 is formed to protrude on each feed filter block 435 to strike the feed filter net 432.

The transfer pressurizing unit 437 is provided to press the transfer filter block 435 and the transfer filter strike bar 436 moved upward by the transfer filter roller 434 downward.

Looking at the operation state of the transfer filter 430, when the air is sucked by the ring blower 300, the feed filter blade portion 433 is rotated so that the plurality of feed filter rollers 434 transfer filter frame 431 Is rotated along

Accordingly, each of the feed filter rollers 434 sequentially moves the plurality of feed filter blocks 435 and the feed filter hammer rod 436 upwardly, and passes the feed filter block 434 past the feed filter rollers 434. The transfer filter hammer rod 436 moves downward by the elastic force of the transfer presser 437 to strike the transfer filter net 432 to drop the finely divided raw material.

In other words, when the feed filter block 435 and the feed filter hammer rod 436 are moved upward by the feed filter roller 434, the feed pressing unit 437 compresses the feed filter roller 434. In this case, the transfer filter block 435 and the transfer filter striking rod 436 are moved downward by the elastic force of the transfer presser 437 to strike the transfer filter net 432.

Accordingly, as the plurality of transfer filter hammer rods 436 sequentially strikes the transfer filter net 432 at the corresponding position to separate the filtered fine material, the transfer filter net 432 is cleaned to improve the transfer efficiency. Can be.

The transfer filter unit 430 operates together with the feed filter unit 430 or operates the feed filter unit 430 in a state in which the transfer operation is stopped. Of course, it is controlled by the control unit 600 to be operated through a separate suction line (not shown).

On the other hand, the transfer filter unit 430 may be operated by the gas boost pump 438.

In other words, the feed filter blade portion 433 and the feed filter roller 434 are rotated by the air that is charged by the gas boost pump 438 instead of the suction air of the ring blower 300, and the supercharged air is transferred to the feed connection. It is moved to the tube 440.

Thus, the gas boost pump 438 is controlled to operate simultaneously with the ring blower 300 does not interfere with the transfer of the fine raw material.

4, the raw material recovery part 500 includes a recovery tank 510, a bag filter part 520, a bellows pulse part 530, a recovery discharge pipe 540, and a recovery valve 550. .

The recovery tank 510 has a recovery space 512 formed therein for recovering the fine raw material introduced with the air through the transfer connection pipe 440.

In addition, the bag filter unit 520 is provided in the recovery tank 510 is provided for filtering the fine raw material conveyed with the air sucked into the ring blower (300).

The bellows pulse unit 530 is controlled by the controller 600 and is provided to separate the filtered fine raw material by generating a pulse inside the bag filter unit 520.

And the recovery discharge pipe 540 has flexibility, one end is connected to the recovery tank 510, the other end is connected to the ring blower (300).

The recovery valve 550 is controlled by the control unit 600, and is provided to supply the fine powder recovered by opening and closing the recovery space 512 to the mixing unit 200.

Here, the bag filter unit 520 is positioned at the upper center of the recovery tank 510 so as to be spaced apart from the inner surface of the recovery space unit 512, and one end of the recovery discharge pipe 540 is located inside the bag filter unit 520. It is provided to be positioned.

The bellows pulse unit 530 generates a pulse in a state in which the operation of the ring blower 300 is stopped to separate the filtered fine material from the bag filter unit 520.

Thus, the finely divided raw material filtered by the bag filter unit 520 is dropped into the recovery space 512, and the recovery space 512 is opened by the recovery valve 550 to mix the finely divided raw material 200. Can be transferred.

The ring blower 300 includes a blower body 310, a blower wing 320, a blower driving motor 330, and a discharge pipe 340, as shown in FIG. 5.

Blower body 310 has a rotating space 312 is formed therein.

In addition, the blower wing 320 has a plurality of wings 322 along the edge, it is provided rotatably in the rotating space 312.

The blower driving motor 330 is provided to rotate the blower wing unit 320.

In addition, the discharge tube 340 is provided for discharging the air of the rotating space 312 to the outside.

Looking at the operating state of the ring blower 300, after the air flows into the rotary space portion 312 through the recovery discharge pipe 540 by the blower wing portion 320 rotated by the blower driving motor 330, As the discharge tube 340 is discharged, the fine raw material of the storage unit 100 is transferred to the mixing unit 200.

The ring blower 300 further includes a blower filter 350.

The blower filter unit 350 is provided to filter the air discharged through the ring blower 300.

The blower filter unit 350 is provided in the discharge pipe 340 to separate the foreign matter contained in the discharged air.

The blower filter unit 350 includes a HEPA filter 352 and an activated carbon filter 354.

The HEPA filter 352 is provided for primary filtering the air discharged through the discharge pipe 340, and the activated carbon filter 354 is provided for secondary filtering the primary filtered air through the HEPA filter 352. do.

Accordingly, the air discharged to the outside may be filtered to prevent and minimize contamination of the surroundings.

10: fine powder supply device 100: storage unit
200: mixing section 300: ring blower
310: blower body 320: blower wings
330: blower drive motor 340: discharge tube
350: blower filter 400: raw material transfer unit
410: transfer tank 420: transfer suction pipe
430: transfer filter unit 440: transfer connector
450: transfer valve 500: raw material recovery unit
510: recovery tank 520: bag filter
530: bellows pulse unit 540: recovery discharge pipe
550: recovery valve 600: control unit

Claims (10)

A storage unit for storing fine raw materials;
Mixing unit for mixing and storing the fine raw material of the storage unit;
A ring blower for generating a vacuum;
When the vacuum is generated by the ring blower, a cyclone phenomenon is generated inside the raw material transfer unit for temporarily storing the fine powder of the storage unit to supply to the mixing unit;
A raw material recovering unit for recovering fine powder from the air passing through the raw material conveying unit and supplying it to the mixing unit; And
And a control unit for controlling the ring blower, a raw material conveying unit, and a raw material recovering unit.
The raw material transfer unit,
A transfer tank having a transfer space therein;
A transfer suction pipe having flexibility, one end of which is located in the storage unit, and the other end of which is located in the transfer tank;
A transfer filter unit provided in the transfer tank to temporarily filter some of the finely divided raw materials transported together with the air sucked into the raw material recovery unit, to temporarily store in the transfer space;
A transfer connecting tube having flexibility and connecting the air and the fine powder to the raw material recovery unit; And
And a transfer valve controlled by the controller and configured to supply the finely divided raw material to the mixing unit by temporarily opening and closing the transfer space.
The other end of the transfer suction pipe is positioned to face the inner side of the transfer space, and the sucked fine raw material is rotated along the inner side of the transfer space to form a cyclone,
The transfer connector is connected to one end of the upper end of the transfer tank,
The transfer filter unit is formed at the end of the transfer connection pipe,
The transfer filter unit,
A transfer filter frame provided at the transfer tank through a central portion so that one end of the transfer connection pipe is movably positioned therein;
A transfer filter net provided in the transfer filter frame to cover one end of the transfer connection pipe;
A feed filter blade having a plurality of feed filter blades outside the upper end and provided to be rotatable in the feed filter frame;
A feed filter roller provided with a plurality of feed filter blades at a predetermined interval along the outer circumferential surface of the lower end of the feed filter blade to enable the feed filter blade to be rotatable along the feed filter frame;
A plurality of feed filter blocks provided between the feed filter frame and the feed filter blade to be moved up and down by the feed filter roller;
A feed filter strike rod protruding from each transfer filter block to strike the transfer filter network; And
And a conveying pressurizing portion configured to pressurize the conveying filter block and the conveying filter hammer rod which are moved upward by the conveying filter roller to the lower side.
When the air is sucked by the ring blower, the feed filter blade is rotated so that the plurality of feed filter rollers are rotated along the feed filter frame to sequentially move the plurality of feed filter blocks and the feed filter hammer rods upward. Let's
The feed filter striking rod moved to the upper side is moved to the lower side by the elastic force of the conveying pressurization unit, characterized in that to drop the fine powder caught by hitting the feed filter network. delete delete delete The method of claim 1, wherein the raw material recovery unit,
A recovery tank having a recovery space formed therein for recovering the fine raw material introduced with air through the transfer connection pipe;
A bag filter unit provided in the recovery tank to filter the finely divided raw material transported together with the air sucked into the ring blower;
A bellows pulse unit controlled by the controller, for generating a pulse inside the bag filter unit to separate the filtered fine powder;
A recovery discharge pipe having flexibility and having one end connected to the recovery tank and the other end connected to the ring blower; And
And a recovery valve controlled by the controller and configured to supply the fine powder recovered by opening and closing the recovery space to the mixing unit.
The bellows pulse unit generates a pulse in a state in which the operation of the ring blower stops to separate the fine raw material filtered by the bag filter unit. The method of claim 5,
The bag filter unit is located in the upper center portion of the recovery tank so as to be spaced apart from the inner surface of the recovery space,
One end of the recovery discharge pipe,
Fine powder supply device characterized in that it is provided to be located inside the bag filter. The method of claim 5, wherein the ring blower,
A blower body having a rotating space therein;
Blower wings having a plurality of wings along the edge, rotatably provided in the rotating space portion;
A blower driving motor for rotating the blower wings; And
And a discharge tube for discharging air to the outside of the rotating space part.
After the air flows into the rotating space part through the recovery discharge pipe by the blower blade rotated by the blower driving motor, and is discharged to the discharge pipe, the fine raw material of the storage unit is transferred to the mixing unit. Fine powder feeder. The method of claim 7, wherein
And a blower filter unit for filtering the air discharged through the ring blower. The method of claim 8, wherein the blower filter unit,
Fine powder supply device characterized in that for separating the foreign matter contained in the discharged air provided in the discharge pipe. The method of claim 9, wherein the blower filter unit,
A hepa filter for firstly filtering the air discharged through the discharge tube; And
And an activated carbon filter for secondly filtering the first filtered air through the hepa filter.

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