KR20240028222A - Magnetic vibrator for particulate material transferring plant - Google Patents

Abstract

The present invention includes a housing mounted on one side of a facility through which powder (particle material) is transported; And a vibration unit, which is built into the housing and operates by the induced electromotive force of an electromagnet operated by receiving power from the outside, and includes a vibrator that imparts vibration or shock to one side of the above-mentioned equipment, This relates to a magnetic vibrator for powder transfer equipment that is installed in the equipment being transported to prevent clogging and agglomeration of powders in the equipment due to mechanical vibration or impact force caused by electromagnetism.

Description

Magnetic vibrator for powder transport equipment {MAGNETIC VIBRATOR FOR PARTICULATE MATERIAL TRANSFERRING PLANT}

The present invention relates to a magnetic vibrator for powder transport equipment, and more specifically, to a magnetic vibrator for powder transport equipment, which can be installed in equipment where powder is transported to prevent clogging and agglomeration of powder in the equipment due to electromagnetic mechanical vibration or impact force. This relates to magnetic vibrators for transfer equipment.

A chute, hopper, or transfer piping facility is a facility that transports powder or particle material, which is generally used in petrochemical plant transfer facilities, to temporarily store or supply.

Conventional equipment that continuously inputs and stores a large amount of various substances in the form of powder and supplies them through transfer facilities causes the injected powder to clump together and form lumps due to its own physical properties such as moisture or static electricity, which reduces fluidity and causes blockages. occurred.

In other words, a device that allows the powder to be smoothly supplied to the transfer line by crushing and dispersing the powder being transferred inside the transfer piping equipment is absolutely necessary.

Registered Patent No. 10-2042696

The present invention was invented to improve the above problems, and is a powder transport equipment installed in equipment where powder is transported to prevent clogging and agglomeration of powder in the equipment due to electromagnetic mechanical vibration or impact force. The purpose is to provide a magnetic vibrator for use.

In order to achieve the above object, the present invention includes a housing mounted on one side of a facility through which powder (particle material) is transported; and a vibration unit, which is operated by the induced electromotive force of an electromagnet built into the housing and operated by receiving power from the outside, and includes a vibrator that imparts vibration or shock to one side of the equipment. We will be able to provide magnetic vibrators for equipment.

Here, the housing further includes a main body portion having a space in which the vibration unit is built, and a fixing flange extending from an edge of one end of the main body portion and detachably coupled to one side of the facility.

At this time, the housing further includes a fastening hole radially penetrating along the fixing flange, and a fastener that passes through the fastening hole and is coupled to one side of the facility.

In addition, the housing further includes a main body portion that has a space in which the vibration unit is built and is detachably coupled to one side of the facility, and a cover that closes the other open end surface of the main body portion.

In addition, the vibration unit further includes a stator including a bobbin built in the housing, a plurality of extension pieces protruding along an inner peripheral surface of the bobbin and disposed radially, and a coil wound around the extension pieces a plurality of times. , The vibrator is characterized in that it is coupled to a rotating shaft rotatably supported at the center of the stator.

In addition, the vibration unit has an outer peripheral surface facing the distal end surface of each of the plurality of extension pieces and is mounted on the rotation shaft to which the vibrator is coupled, and an outer peripheral surface of the rotation shaft to generate an induced electromotive force together with the coil to rotate the rotation shaft. It is characterized in that it further includes a rotor including a permanent magnet for rotating.

In addition, the vibrator is characterized in that it is formed in a fan shape with the center coupled to the distal end of the rotor.

In addition, a plurality of vibrators are mounted along the rotation axis, and when one end of one of the plurality of vibrators is coupled through the rotation shaft, the other end of another one of the plurality of vibrators is throughly coupled to the rotation shaft. The pattern is repeated along the rotation axis, and each vibrator is eccentrically coupled to the rotation axis and rotates eccentrically within the housing.

And, it further includes a reducer coupled to the end of the rotation shaft and built into the housing,

The plurality of vibrators are characterized in that they are coupled to the drive transmission shaft of the reducer.

In addition, it is characterized in that it further includes a first bearing supported by the rotation shaft and built into the housing, and a second bearing supported by the drive transmission shaft and built into the housing.

In addition, the vibrator is connected to the equipment and directly vibrates the equipment, and the equipment is a transport connection pipe mounted on a powder transport pipe through which the powder is transported.

According to the present invention with the above configuration, it has the advantage of being installed in a facility where powder is transported to prevent clogging and agglomeration of the powder in the facility due to electromagnetic mechanical vibration or impact force.

Figure 1 is a conceptual diagram showing the periphery of a facility where a magnetic vibrator for powder transport facility is installed according to an embodiment of the present invention.
Figure 2 shows part ii of Figure 1, and is an internal side cross-sectional conceptual diagram showing the overall structure of a magnetic vibrator for powder transport equipment according to an embodiment of the present invention.
Figure 3 shows part iii of Figure 2, and is an internal side cross-sectional conceptual diagram showing the overall structure of a magnetic vibrator for powder transport equipment according to another embodiment of the present invention.

The advantages and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms.

The examples herein are provided to make the disclosure of the present invention complete and to fully inform those skilled in the art of the scope of the invention.

And the present invention is only defined by the scope of the claims.

Accordingly, in some embodiments, well-known components, well-known operations and well-known techniques are not specifically described in order to avoid ambiguous interpretation of the present invention.

In addition, the same reference numerals refer to the same components throughout the specification, and the terms used (mentioned) in the specification are for explaining embodiments and are not intended to limit the present invention.

In this specification, the singular also includes the plural unless specifically stated in the phrase, and elements and operations referred to as 'including (or, including)' do not exclude the presence or addition of one or more other elements and operations. .

Unless otherwise defined, all terms (including technical and scientific terms) used in this specification may be used with meanings that can be commonly understood by those skilled in the art to which the present invention pertains.

Additionally, terms defined in commonly used dictionaries are not interpreted ideally or excessively unless they are defined.

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

First, Figure 1 is a conceptual diagram showing the periphery of a facility where a magnetic vibrator for powder transport facility is installed according to an embodiment of the present invention.

In addition, Figure 2 shows part ii of Figure 1, and is an internal side cross-sectional conceptual diagram showing the overall structure of a magnetic vibrator for powder transport equipment according to an embodiment of the present invention.

In addition, Figure 3 shows part iii of Figure 2, and is an internal side cross-sectional conceptual diagram showing the overall structure of a magnetic vibrator for powder transport equipment according to another embodiment of the present invention.

As shown in FIG. 1, the present invention includes a housing 100 mounted on one side of a facility 300 through which powder (particle material) is transported, and an electromagnet built into the housing 100 and operated by receiving power from the outside. An embodiment that includes a vibration unit 200 that operates by induced electromotive force and includes a vibrator 210 that applies vibration or shock to one side of the facility 300 may be applied.

The present invention can be applied to the above-mentioned embodiments, and of course, it is also possible to apply the following various embodiments.

First, the housing 100 has a main body 110 having a space in which the vibration unit 200 is built, as shown in FIG. 2, and extends from the edge of one end of the main body 110 to be attached and detached to one side of the equipment 300. A fixed flange 120 coupled thereto may be further provided.

In addition, the housing 100 has a fastening hole 121 (see FIG. 2 below) radially penetrating along the fixing flange 120, and a fastening hole 121 that penetrates the fastening hole 121 and is coupled to one side of the equipment 300. An additional sphere 130 may be provided.

In addition, of course, the housing 100 may be further provided with a cover 140 that closes the open other end surface of the main body 110 along with the above-described main body 110.

Here, the cover 140 is provided to be openable and closed with respect to the main body 110 for the convenience of work such as installation and inspection, replacement, and repair of each part of the vibration unit 200, which will be described later.

Meanwhile, the vibration unit 200 includes a bobbin 221 built into the housing 100, a plurality of extension pieces 222 that protrude along the inner peripheral surface of the bobbin 221 and are radially arranged, and an extension piece 222. A stator 220 including a coil 223 wound multiple times may be further provided.

Here, it can be seen that the vibrator 210 is coupled to the rotation shaft 231 rotatably supported at the center of the stator 220.

At this time, the vibration unit 200 may further include a rotor 230 including a rotation shaft 231.

The rotation axis 231 has an outer peripheral surface facing the end surface of each of the plurality of extension pieces 222 and is coupled to the vibrator 210.

The permanent magnet 232 is mounted on the outer peripheral surface of the rotating shaft 231 and generates induced electromotive force together with the coil 223 to rotate the rotating shaft 231.

Here, the vibrator 210, although not specifically shown, may be formed in a fan shape with the center coupled to the distal end of the rotor 230.

At this time, the shape of the vibrator 210 is not limited to the fan-shaped shape described above, and of course, any application and modification design is possible as long as it has a structure and shape that can generate vibration due to centrifugal force due to rotation of the vibrator 210.

These vibrators 210 are mounted in plural numbers along the rotation axis 231, and when one end of one of the plurality of vibrators 210 is coupled through the rotation shaft 231, the other of the plurality of vibrators 210 is connected to the other vibrator 210. A pattern in which the other end of one vibrator 210 is coupled through the rotation axis 231 may be repeated along the rotation axis 231 .

Here, each vibrator 210 is eccentrically coupled to the rotation axis 231 and rotates eccentrically within the housing 100, thereby generating mechanical vibration and impact force on the equipment 300.

Meanwhile, a reducer 240 is coupled to the end of the rotation shaft 231 and built into the housing 100, and a plurality of vibrators 210 may be coupled to the drive transmission shaft 241 of the reducer 240.

Here, the rotation shaft 231 is rotationally supported by the first bearing 251 built into the housing 100, and the drive transmission shaft 241 is rotationally supported by the second bearing 252 built into the housing 100. It can be.

Meanwhile, the vibrator 210 is connected to the equipment 300 as shown in FIG. 3 and can directly shake the equipment 300, and the above-described equipment 300 is mounted on the powder transport pipe 400 through which the powder is transported. It may be a transfer connection pipe 310.

That is, the transfer connection pipe 310 is placed on the conduit through which the powder is transferred and the transfer connection pipe 310 itself is oscillated to eliminate agglomeration and agglomeration of the powder.

In Figure 3, the transfer connection pipe 310 is shown in the form of a straight pipe, but the transfer connection pipe 310 corresponds to a section on the powder transfer path where the transfer speed of the powder is slow or a lot of stacking occurs, for example, a curved section. By manufacturing it in the shape of a curved pipe and installing it in the corresponding curved section, it will be possible to eliminate the clumping and agglomeration phenomenon of powder.

Here, the vibration unit 200 is coupled to both ends of the transport connection pipe 310 and connects the corrugated pipe 311 between one pipe 410 and the other pipe 420 of the powder transport pipe 400, and the transport connection. Extension flanges 312 extending from both end edges of the pipe 310 may be further provided.

At this time, the vibrator 210 is rotatably supported on one side of the extension flange 312, and the first vibration axis 211 is parallel to one side pipe 410, the other pipe 420, and the transfer connection pipe 310. ) may include.

The vibrator 210 may include a first shaft support bearing 212 that is mounted on one side of the extension flange 312 and supports rotation of the first vibration shaft 211.

The vibrator 210 may include a first eccentric rotation piece 213 that is eccentrically coupled to an end of the first vibration shaft 211 and rotates integrally with the first vibration shaft 211 .

Here, it may further include a housing 100 that surrounds the outer peripheral surface of one side pipe 410 and the other side pipe 420 and in which the corrugated pipe 311 and the transfer connection pipe 310 are built.

The vibrator 210 may include a drive transmission motor 214 that is provided on one side of the housing 100 and transmits driving force to the first vibration shaft 211.

The vibrator 210 is provided on the drive transmission motor 214 and rotates by receiving driving force from the drive transmission motor 214, and may include a second vibration axis 215 parallel to the first vibration axis 211. there is.

The vibrator 210 is eccentrically coupled to the end of the second vibration shaft 215 and rotates integrally with the second vibration shaft 215, and includes a second eccentric rotation piece 216 parallel to the first eccentric rotation piece 213. ) may include.

The vibrator 210 has a first end 217a rotatably supported at the distal end of the first eccentric rotary piece 213, and a second end rotatably supported at the distal end of the second eccentric rotary piece 216 ( 217b) and may include a vibration connection axis 217 parallel to the first vibration axis 211 and the second vibration axis 215.

Therefore, the drive transmission motors 214 are installed on both sides of the housing 100, and operate some or all of the drive transmission motors 214 on both sides of the housing 100 to symmetrically or It will be possible to prevent or improve clogging or agglomeration of powder that may accumulate inside the transport connection pipe 310 due to mechanical vibration caused by asymmetric eccentric rotation.

As described above, the present invention provides a magnetic vibrator for powder transport equipment that can be installed in equipment where powder is transported to prevent clogging and agglomeration of powder in the equipment due to electromagnetic mechanical vibration or impact force. You can see that it is being done with thought.

And, of course, many other modifications and applications are possible for those skilled in the art within the scope of the basic technical idea of the present invention.

100...Housing
110...main body
120...fixed flange
121... Fastening hole
130...fastener
140...cover
200...vibration unit
210...oscillator
211...First vibration axis
212...First shaft support bearing
213...First eccentric rotation piece
214...Drive transmission motor
215...second vibration axis
216...2nd eccentric rotation piece
217...Vibration connecting shaft
217a...first end
217b...second end
220...Stator
221...bobbin
222...extended edition
223...coil
230...Rotor
231...rotation axis
232...Permanent magnet
240...Reducer
241...Drive transmission shaft
251...First bearing
252...2nd bearing
300...equipment
310...Transfer connection pipe
311...corrugated pipe
312...extension flange
400...Powder transfer pipe
410...one side pipe
420...other side pipe

Claims (11)

A housing mounted on one side of the equipment through which particle material is transported; and
A powder transport facility comprising a vibration unit that is operated by induced electromotive force of an electromagnet built into the housing and operated by receiving power from the outside, and includes a vibrator that imparts vibration or shock to one side of the facility. For magnetic vibrator.
In claim 1,
The housing is,
A main body portion having a space in which the vibration unit is built,
A magnetic vibrator for powder transport equipment, characterized in that it further includes a fixed flange extending from an edge of one end of the main body and detachably coupled to one side of the equipment.
In claim 2,
The housing is,
A fastening hole radially penetrating along the fixing flange,
A magnetic vibrator for powder transport equipment, further comprising a fastener that passes through the fastening hole and is coupled to one side of the equipment.
In claim 1,
The housing is,
A main body portion that has a space in which the vibration unit is built and is detachably coupled to one side of the facility,
A magnetic vibrator for powder transport equipment, further comprising a cover closing the other open end surface of the main body.
In claim 1,
The vibration unit is,
It further includes a stator including a bobbin built into the housing, a plurality of extension pieces protruding along an inner peripheral surface of the bobbin and disposed radially, and a coil wound around the extension pieces a plurality of times,
A magnetic vibrator for powder transport equipment, wherein the vibrator is coupled to a rotating shaft rotatably supported at the center of the stator.
In claim 5,
The vibration unit is,
The rotating shaft has an outer peripheral surface facing the end surface of each of the plurality of extension pieces and is coupled to the vibrator, and a permanent magnet mounted on the outer peripheral surface of the rotating shaft to generate an induced electromotive force with the coil to rotate the rotating shaft. A magnetic vibrator for powder transport equipment, further comprising a rotor.
In claim 6,
A magnetic vibrator for powder transport equipment, wherein the vibrator is formed in a fan-shaped shape with a center coupled to the distal end of the rotor.
In claim 6,
The vibrators are mounted in plural numbers along the rotation axis,
When one end of one of the plurality of vibrators is coupled to the rotating shaft,
A pattern in which the other end of one of the plurality of vibrators is coupled through the rotation axis is repeated along the rotation axis,
A magnetic vibrator for powder transport equipment, wherein each vibrator is eccentrically coupled to the rotation axis and rotates eccentrically within the housing.
In claim 8,
It further includes a reducer coupled to the end of the rotation shaft and built into the housing,
A magnetic vibrator for powder transport equipment, characterized in that the plurality of vibrators are coupled to the drive transmission shaft of the reducer.
In claim 9,
a first bearing that supports the rotating shaft and is built into the housing;
A magnetic vibrator for powder transport equipment, further comprising a second bearing supporting the drive transmission shaft and built into the housing.
In claim 1,
The vibrator is,
It is connected to the equipment and directly shakes the equipment,
A magnetic vibrator for powder transport equipment, characterized in that the equipment is a transport connection pipe mounted on the powder transport pipe through which the powder is transported.