KR102458072B1 - Filter apparatus for fluid bed processor using static electricity and fluid bed processor comprising thereof - Google Patents

Abstract

A filter device for a fluidized bed processing machine using static electricity according to an embodiment disclosed in this document is a DC power supply unit including a first pole terminal and a second pole terminal, and is located inside the filter housing so as to cross the inside of the columnar filter housing. A metal grill installed, electrically connected to the first pole terminal of the DC power supply, and configured to be charged while the dried particles pass from the bottom to the top by the flow of air from the bottom to the top of the filter housing, and the inside of the filter housing A first electrode installed on the inside of the filter housing to cross, spaced upward from the metal grill, electrically connected to the first pole terminal of the DC power supply, and configured to communicate with air, the filter to cross the inside of the filter housing A dielectric installed in the housing, disposed adjacent to the first electrode on the first electrode, and configured to communicate with air, and installed in the filter housing to cross the inside of the filter housing, the dielectric and the dielectric on the upper part of the filter housing It may include a second electrode disposed to be adjacent, electrically connected to the second pole terminal of the DC power supply, and configured to communicate with air.

Description

A filter device for a fluidized bed processing machine using static electricity and a fluidized bed processing machine including the same

Embodiments disclosed herein relate to a filter device for a fluidized bed processor and a fluidized bed processor comprising the filter device.

The fluidized bed processing machine is a facility for performing processes such as drying, granulating, or coating particles by injecting hot air in a closed space and inducing a flow of air, and may include a fluidized bed dryer and a fluidized bed granulator. A fluidized bed processing machine may be essential for the production of pharmaceuticals, cosmetics and functional foods. 1, a typical fluidized bed processing machine 100 includes a heat exchanger 110 for supplying hot air, a container 120 for loading particles containing moisture, a filter housing 130 connected to the container 120, It may include a filter 140 that blocks the outflow of particles due to the flow of air, and a blower 150 that generates a flow of air from the inside of the fluidized bed processing machine 100 to the outside. The dried particles may be continuously adsorbed to the filter 140 included in the fluidized bed processor 100 as the process progresses.

When the dried particles are adsorbed to the filter 140 of the fluidized bed processor 100 , the flow of air through the filter 140 may be slowed. Therefore, in order to remove the particles adsorbed to the filter 140 from the filter 140, a shaking process of shaking the filter 140 in the vertical direction should be performed. Since the flow of air should not occur during the shaking process, a process (eg, a drying process, a granulation process, a coating process, etc.) performed by the fluidized bed processor 100 should be stopped and the flow of air should be blocked. Therefore, in order to perform the shaking process, the process time may inevitably increase. Typically, when the fluidized bed processor 100 is operated, a filter shaking process of about 10 seconds per 60 seconds may be performed. Also, if the dried particles are continuously adsorbed to the filter 140 , the filter 140 may be damaged, and the dried particles may pass through the damaged filter 140 and be lost to the outside. Accordingly, a filter system for a fluidized bed processor capable of omitting the shaking process and reducing filter damage may be required.

SUMMARY Embodiments of the present invention are to provide a filter system for a fluidized bed processing machine capable of minimizing damage due to use without requiring a shaking process to remove adsorbed particles, and a fluidized bed processing machine including the filter system.

A filter device for a fluidized bed processing machine using static electricity according to an embodiment disclosed in this document is a DC power supply unit including a first pole terminal and a second pole terminal, and is located inside the filter housing so as to cross the inside of the columnar filter housing. A metal grill installed, electrically connected to the first pole terminal of the DC power supply, and configured to be charged while the dried particles pass from the bottom to the top by the flow of air from the bottom to the top of the filter housing, and the inside of the filter housing A first electrode installed on the inside of the filter housing to cross, spaced upward from the metal grill, electrically connected to the first pole terminal of the DC power supply, and configured to communicate with air, the filter to cross the inside of the filter housing A dielectric installed in the housing, disposed adjacent to the first electrode on the first electrode, and configured to communicate with air, and installed in the filter housing to cross the inside of the filter housing, the dielectric and the dielectric on the upper part of the filter housing It may include a second electrode disposed to be adjacent, electrically connected to the second pole terminal of the DC power supply, and configured to communicate with air.

According to an embodiment, the metal grill has a side surface attached to the inner surface of the filter housing, a ring-shaped frame, and arranged parallel to each other on the inner surface of the frame, both ends are attached to the inner surface of the frame, and has a band shape It may include a plurality of charging plates made of.

According to an embodiment, the first electrode and the second electrode may have a plate shape and may include one or more openings.

According to an embodiment, the dielectric material may have a plate shape and may include one or more openings.

According to an embodiment, the opening formed in the dielectric may be smaller than the opening formed in the first electrode.

According to one embodiment, the first electrode is to be charged to the first pole by the DC power supply unit so that when the particles charged to the first pole are adjacent while passing through the metal grill from the bottom to the top, the particles move downward by the electrical repulsive force. can

According to an embodiment, the first electrode, the dielectric material, and the second electrode are connected to each other and connected to at least one of the first electrode, the dielectric material, and the second electrode, and the first electrode, the dielectric material, and the second electrode are moved in the vertical direction It may further include a cylinder configured to act.

According to an embodiment, the metal grill, the first electrode, and the second electrode may be made of aluminum or stainless steel, and the dielectric may be made of polytetrafluoroethylene or silicon.

According to an embodiment, the filter device may further include a control circuit configured to control the output voltage of the DC power supply unit based on the dust sensor installed above the second electrode, and the concentration of dust detected by the dust sensor.

A fluidized bed process machine including a filter device using static electricity according to an embodiment disclosed in this document receives particles containing moisture, a container in communication with a heat exchanger, is connected to the upper portion of the container, and is columnar Consists of a filter housing communicating with the blower at the upper end, a DC power supply including a first pole terminal and a second pole terminal, and a filter disposed inside the filter housing, the filter comprising the inside of the filter housing A flow of air from the bottom to the top of the filter housing generated by the blower installed inside the filter housing to cross, electrically connected to the first pole terminal of the DC power supply, and dried by the heat exchanger in the container A metal grill configured to be charged while passing from the bottom to the top by the , a first electrode configured to communicate with air, a dielectric that is installed in the filter housing to cross the inside of the filter housing, is disposed adjacent to the first electrode on the first electrode, and is configured to communicate with air, and the filter housing It may include a second electrode installed inside the filter housing to cross the inside of the filter housing, disposed adjacent to the dielectric on the upper part of the dielectric, electrically connected to the second pole terminal of the DC power supply, and configured to communicate with air. .

According to the embodiments disclosed in this document, by employing a metal grill for charging particles and an electrode for filtering the charged particles using an electrical repulsive force, adsorption of particles to the filter is prevented and the shaking process of the filter , it is possible to shorten the processing time by the fluidized bed processing machine.

In addition, by employing a grill-shaped metal member in a path through which the particles pass, the particles can be easily charged.

In addition, by forming openings in the electrodes and dielectrics included in the filter to facilitate the flow of air, it is possible to reduce the required capacity of the blower and reduce the energy consumption of the fluidized bed processing machine.

In addition, by making the size of the opening of the dielectric disposed between the two electrodes smaller than the size of the opening of the electrode, it is possible to reduce the amount of particles that are not filtered by the electrical repulsive force flowing to the outside.

In addition, by adjusting the supply voltage based on the concentration of the dust detected by the dust sensor, it is possible to supply a voltage suitable for the process state and reduce the power consumption of the filter.

In addition, various effects directly or indirectly identified through this document may be provided.

1 shows the configuration of a conventional fluidized bed processing machine according to the prior art.
2 illustrates a configuration of a fluidized bed processing machine according to an embodiment.
3 illustrates movement of particles by the operation of a fluidized bed processing machine according to an exemplary embodiment.
4 illustrates a structure of a metal grill included in a fluidized bed processing machine according to an exemplary embodiment.
5 illustrates a structure of an electrode included in a fluidized bed processing machine according to an exemplary embodiment.
6 illustrates a structure of a dielectric included in a fluidized bed processing machine according to an exemplary embodiment.
7 is an exemplary view for explaining a voltage control operation according to the dust concentration in the fluidized bed processing machine according to an embodiment.
In connection with the description of the drawings, the same or similar reference numerals may be used for the same or similar components.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. However, this is not intended to limit the present invention to specific embodiments, and it should be understood that various modifications, equivalents or substitutes of the embodiments of the present invention are included. In adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in the description of the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

2 illustrates a structure of a fluidized bed processing machine according to an embodiment.

Referring to FIG. 2 , the fluidized bed process machine 200 according to an embodiment includes a heat exchanger 210 , a container 220 , a filter housing 230 , a metal grill 240 , and a first electrode 251 . ), a dielectric 252 , a second electrode 253 , a direct current (DC) power supply 260 , and a blower 270 . The fluidized bed processing machine 200 may be, for example, a device such as a fluidized bed dryer or a fluidized bed granulator.

The heat exchanger 210 may supply heat to the outside. The heat exchanger 210 may supply, for example, high-temperature steam or air to the outside.

The container 220 may contain particles containing moisture. The container 220 may have a container shape with an open top. The particles may be, for example, components such as pharmaceuticals, cosmetics, and/or food, and may be loaded into the container 220 in a mixed state with moisture. The container 220 containing the particles containing moisture may be connected to the heat exchanger 210 and the filter housing 230 . The container 220 may communicate with the heat exchanger 210 through a pipe. The particles accommodated in the container 220 may receive high-temperature water vapor or air from the heat exchanger 210 .

The filter housing 230 may be formed in a column shape. The filter housing 230 may have an open lower end and a closed upper end. The filter housing 230 may be connected to an upper portion of the container 220 . Particles dried in the container 220 may be introduced into the filter housing 230 . The filter housing 230 may communicate with the blower 270 at the upper end through a pipe.

The DC power supply unit 260 may supply DC power to the outside. The DC power supply unit 260 may include a first pole (eg, negative) terminal and a second pole (eg, positive) terminal. The output voltage of the DC power supply unit 260 may be controlled.

A filter system (the filter system may be referred to as a filter in this document) may be disposed inside the filter housing 230 . The filter system may include a metal grill 240 , a first electrode 251 , a dielectric 252 , and a second electrode 253 .

The metal grill 240 may be installed inside the filter housing 230 to cross the inside of the filter housing 230 . When the filter housing 230 is cylindrical, the metal grill 240 may have a circular shape corresponding to the shape of the filter housing 230 , and the outer peripheral surface of the metal grill 240 is attached to the inner surface of the filter housing 230 . can be The metal grill 240 may be made of, for example, a material such as aluminum or stainless steel.

The metal grill 240 may include a frame forming an outer circumferential surface and a charging plate arranged inside the frame. The structure of the metal grill 240 will be described in detail with reference to FIG. 4 . In the metal grill 240, the particles dried by the heat exchanger 210 can pass from the bottom to the top by the flow of air from the bottom to the top of the filter housing 230 generated by the blower 270. can be configured to The metal grill 240 may be electrically connected to the first pole terminal of the DC power supply unit 260 . The metal grill 240 may be charged to the first pole by the DC power supply 260 . Since the metal grill 240 is charged with the first pole, particles passing through the metal grill 240 may be charged with the first pole.

The first electrode 251 may be installed inside the filter housing 230 to cross the inside of the filter housing 230 . The first electrode 251 may be spaced upwardly from the metal grill 240 . When the filter housing 230 is cylindrical, the first electrode 251 may have a circular shape corresponding to the shape of the filter housing 230 , and the outer peripheral surface of the first electrode 251 is the inner surface of the filter housing 230 . can be attached to The first electrode 251 may be made of, for example, a material such as aluminum or stainless steel.

The first electrode 251 may include one or more openings through which air may communicate. The particles may approach the first electrode 251 by a flow of air from the bottom to the top through the opening. The first electrode 251 may be electrically connected to the first electrode terminal of the DC power supply unit 260 . The first electrode 251 may be charged to the first electrode by the DC power supply unit 260 . Since the first electrode 251 is charged with the first pole, when the particles charged with the first pole are adjacent to the first electrode 251 while passing through the metal grill 240 from the bottom to the top, the particles are electrically repulsive. can be moved downwards.

The dielectric 252 may be installed inside the filter housing 230 to cross the inside of the filter housing 230 . The dielectric 252 may be disposed on the first electrode 251 to be adjacent to the first electrode 251 . When the filter housing 230 is cylindrical, the dielectric 252 may have a circular shape corresponding to the shape of the filter housing 230 , and the outer peripheral surface of the dielectric 252 may be attached to the inner surface of the filter housing 230 . have. Dielectric 252 may include one or more openings to allow air to communicate. Dielectric 252 may be made of, for example, polytetrafluoroethylene or silicon.

The second electrode 253 may be installed inside the filter housing 230 to cross the inside of the filter housing 230 . The second electrode 253 may be disposed on the dielectric 252 and adjacent to the dielectric 252 . The second electrode 253 may have a shape similar to that of the first electrode 251 . When the filter housing 230 is cylindrical, the second electrode 253 may have a circular shape corresponding to the shape of the filter housing 230 , and the outer peripheral surface of the second electrode 253 is the inner surface of the filter housing 230 . can be attached to The second electrode 253 may include one or more openings through which air may communicate. The second electrode 253 may be made of, for example, a material such as aluminum or stainless steel. The second electrode 253 may be electrically connected to the second electrode terminal of the DC power supply unit 260 . The second electrode 253 may be charged to the second electrode by the DC power supply unit 260 .

The blower 270 may generate a flow of air. The blower 270 may generate a flow of air from the container 220 to the outside of the blower 270 through the filter housing 230 . The blower 270 may include a fan for generating a flow of air and a case for guiding the flow of air.

The fluidized bed processor 200 according to an embodiment may further include a cylinder (not shown). The first electrode 251 , the dielectric 252 , and the second electrode 253 may be connected to each other. The cylinder may be connected to at least one of the first electrode 251 , the dielectric 252 , and the second electrode 253 . The cylinder may be configured to vertically move the first electrode 251 , the dielectric 252 , and the second electrode 253 . When particles are attached to the first electrode 251 , the dielectric 252 , and the second electrode 253 using a cylinder, they may be removed.

3 illustrates movement of particles by the operation of a fluidized bed processing machine according to an exemplary embodiment.

Referring to FIG. 3 , the fluidized bed processing machine 200 according to an embodiment may perform a process such as drying, granulating, or coating particles containing moisture contained in the container 220 .

The particles containing moisture contained in the container 220 may be dried by high-temperature steam or air supplied from the heat exchanger 210 . The dried particles may float in the container 220 . A flow of air passing through the heat exchanger 210 , the container 220 , the filter housing 230 and the blower 270 may be generated by the blower 270 and the heat exchanger 210 . Particles suspended in the container 220 may move upward toward the filter housing 230 by the flow of air.

Particles moved to the filter housing 230 may pass through the metal grill 240 . The metal grill 240 may be negatively charged by the DC power supply 260 . Due to the negatively charged metal grill 240 , particles passing through the metal grill 240 may be negatively charged. The negatively charged particles may move upward toward the first electrode 251 by the flow of air.

The charged particles may approach the first electrode 251 . The first electrode 251 may be negatively charged to the DC power supply unit 260 . The charged first electrode 251 may generate an electric field. An electrical repulsive force may be generated between the negatively charged first electrode 251 and negatively charged particles. Particles charged by the electrical repulsive force may move in a direction away from the first electrode 251 without passing through the first electrode 251 . Accordingly, the dried particles do not flow out through the blower 270 but are filtered by the filter and stay inside the filter housing 230 and the container 220 .

4 illustrates a structure of a metal grill included in a fluidized bed processing machine according to an exemplary embodiment.

Referring to FIG. 4 , the metal grill 240 according to an embodiment may include a frame 241 and a plurality of charging plates 242 .

The frame 241 may have a ring shape. The frame 241 may be formed, for example, in a belt shape having a relatively thin thickness and a relatively high height. The side surface of the frame 241 may be attached to the inner surface of the filter housing 230 . The frame 241 may be made of metal.

The charging plate 242 may have a straight band shape. Both ends of the charging plate 242 may be attached to the inner surface of the frame 241 , respectively. The charging plate 242 may be disposed so that the wide side faces the inner side of the frame 241 . The charging plates 242 may be arranged parallel to each other in the frame 241 .

Due to the structure of the frame 241 and the charging plate 242 constituting the metal grill 240 , particles passing through the metal grill 240 may be adjacent to the charged metal grill on a wider surface, and thus more easily charged can be

5 illustrates a structure of an electrode included in a fluidized bed processing machine according to an exemplary embodiment.

Referring to FIG. 5 , the first electrode 251 according to an embodiment may be formed in a plate shape. One or more openings 251a may be formed in the first electrode 251 . Although not shown in FIG. 5 , the second electrode 253 may have the same shape as the first electrode 251 .

The plurality of openings 251a formed in the first electrode 251 may be formed for air communication. In the fluidized bed processor 200 , a flow of air from the bottom to the top may be generated inside the container 220 and the filter housing 230 by the blower 270 . Air may flow upward through the opening 251a of the first electrode 251 .

Most of the particles moving from the lower part to the upper part according to the flow of air may move to the lower part again by the electric repulsive force generated by the first electrode 251 . However, some of the particles may move upwards through the opening 251a along with air in some cases.

6 illustrates a structure of a dielectric included in a fluidized bed processing machine according to an exemplary embodiment.

Referring to FIG. 6 , the dielectric 252 according to an embodiment may be formed in a plate shape. One or more openings 252a may be formed in the dielectric 252 .

A plurality of openings 252a formed in the dielectric 252 may be formed for communication of air. In the fluidized bed processor 200 , a flow of air from the bottom to the top may be generated inside the container 220 and the filter housing 230 by the blower 270 . Air may flow upward through opening 252a in dielectric 252 .

According to an embodiment, the opening 252a formed in the dielectric 252 may be smaller than the opening 251a formed in the first electrode 251 . The particles are mainly filtered by the electric field generated by the first electrode 251, but when some of the particles move through the first electrode 251 together with air, the opening 252a formed in the dielectric 252 is Since it is smaller than the opening 251a formed in the first electrode 251 , particles may be secondary filtered.

7 is an exemplary view for explaining a voltage control operation according to the dust concentration in the fluidized bed processing machine according to an embodiment.

Referring to FIG. 7 , a fluidized bed processing machine 700 according to an embodiment includes a heat exchanger 710 , a container 720 , a filter housing 730 , a metal grill 740 , a first electrode 751 , and a dielectric ( 752 ), a second electrode 753 , a DC power supply unit 760 , a blower 770 , a dust sensor 780 , and a control circuit 790 may be included. For convenience of description, duplicate descriptions of the same components as those already described will be omitted.

The dust sensor 780 may be installed above the second electrode 753 . For example, the dust sensor 780 may be installed on the inner surface of the filter housing 730 above the second electrode 753 . The dust sensor 780 may measure the concentration of dust. As the amount of particles passing through the first electrode 751 , the dielectric 752 , and the second electrode 753 increases, the concentration of dust measured by the dust sensor 780 may increase.

The control circuit 790 may be electrically connected to the dust sensor 780 and the DC power supply 760 . In FIG. 7 , the control circuit 790 is illustrated as an independent configuration, but the present invention is not limited thereto, and the control circuit 790 may be configured to be integrated with the dust sensor 780 or the DC power supply unit 760 . The control circuit 790 may control the output voltage of the DC power supply unit 760 based on the concentration of the dust detected by the dust sensor 780 . For example, the control circuit 790 may increase the output voltage of the DC power supply unit 760 as the concentration of dust increases. Since the high concentration of dust requires stronger filtering, by increasing the output voltage of the DC power supply unit 760, the magnitude of the electrical repulsive force generated between the first electrode 751 and the particles may be increased.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Claims (5)

In the filter device for a fluidized bed processing machine using static electricity,
DC power supply including a first pole terminal and a second pole terminal;
It is installed inside the filter housing so as to cross the inside of the columnar filter housing, is electrically connected to the first pole terminal of the DC power supply, and the dried particles are air flowing from the lower part of the filter housing to the upper part. a metal grill configured to be charged while passing from the bottom to the top by the flow;
A first installed inside the filter housing so as to cross the inside of the filter housing, spaced upward from the metal grill, electrically connected to the first pole terminal of the DC power supply, and configured to communicate with the air electrode;
a dielectric installed inside the filter housing to cross the inside of the filter housing, disposed on the first electrode to be adjacent to the first electrode, and configured to communicate with the air;
It is installed in the filter housing so as to cross the inside of the filter housing, is disposed on the upper part of the dielectric and adjacent to the dielectric, is electrically connected to the second pole terminal of the DC power supply, and the air is communicated. a second electrode configured;
a cylinder connected to at least one of the first electrode, the dielectric material and the second electrode and configured to move the first electrode, the dielectric material, and the second electrode in a vertical direction;
a dust sensor installed above the second electrode; and
a control circuit configured to control the output voltage of the DC power supply unit based on the concentration of the dust sensed by the dust sensor;
wherein the control circuit is configured to increase the output voltage of the DC power supply as the concentration of the dust increases. The method of claim 1,
The metal grill is
a frame having a side surface attached to the inner surface of the filter housing and having a ring shape, and
and a plurality of charging plates arranged parallel to each other on the inner surface of the frame, both ends attached to the inner surface of the frame, and formed in a band shape. The method of claim 1,
The device of claim 1, wherein the first electrode and the second electrode are plate-shaped and include one or more openings. The method of claim 1,
The device of claim 1, wherein the dielectric is plate-shaped and includes one or more openings. In a fluidized bed processing machine comprising a filter device using static electricity,
a container for receiving particles comprising moisture and communicating with a heat exchanger;
a filter housing connected to the upper portion of the container, formed in a columnar shape, and communicating with a blower at the upper end;
DC power supply including a first pole terminal and a second pole terminal; and
a filter disposed inside the filter housing;
The filter is
It is installed inside the filter housing so as to cross the inside of the filter housing, is electrically connected to the first pole terminal of the DC power supply, and the particles dried by the heat exchanger in the container are generated by the blower a metal grill configured to be charged while passing from the bottom to the top by the flow of air from the bottom to the top of the filter housing;
A first installed inside the filter housing so as to cross the inside of the filter housing, spaced upward from the metal grill, electrically connected to the first pole terminal of the DC power supply, and configured to communicate with the air electrode;
a dielectric installed inside the filter housing to cross the inside of the filter housing, disposed on the first electrode to be adjacent to the first electrode, and configured to communicate with the air;
It is installed in the filter housing so as to cross the inside of the filter housing, is disposed to be adjacent to the dielectric on the upper part of the dielectric, is electrically connected to the second pole terminal of the DC power supply, and the air is communicated a second electrode configured;
a cylinder connected to at least one of the first electrode, the dielectric material and the second electrode and configured to move the first electrode, the dielectric material, and the second electrode in a vertical direction;
a dust sensor installed above the second electrode; and
a control circuit configured to control the output voltage of the DC power supply unit based on the concentration of the dust sensed by the dust sensor;
wherein the control circuit is configured to increase the output voltage of the DC power supply as the concentration of the dust increases.

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