KR101036648B1 - Iron powder removal device - Google Patents

Abstract

The present invention provides an iron collection device that effectively collects and transports the iron suspended in the flow path, is easy to install in the flow path, does not disturb the flow of water, and enables the optimum channel efficiency and discharge according to the flow rate and the amount of suspended iron. The iron collecting device is arranged between the upper and lower parts of the frame at predetermined intervals, and is disposed between the upper and lower parts of the frame and moved between the upper and lower parts of the frame as external force is transmitted, and the iron contained in the flow path is collected or collected iron. A plurality of sliding members for separating the; and a plurality of guide members for connecting the upper and lower parts of the frame to guide the movement of the plurality of sliding members, the plurality of sliding members are variable in response to the state of being coupled and separated from each other The iron is collected or separated according to the strength of the magnetic force.

Euro, Iron, Collection, Collection, Magnet

Description

Iron collecting device {IRON POWDER REMOVAL DEVICE}

The present invention relates to an iron collecting device, and more particularly to an iron collecting device for collecting and collecting iron suspended in the flow path of the water passage.

In general, a precipitation method of collecting iron precipitated using a multi-stage collection tank is used to recover iron contained in the fluid in a place forming a flow path, such as a water channel. In addition, a method of collecting the iron contained in the fluid in the process of passing through the narrowly formed flow path using a permanent magnet, such as a drum-type magnet sorter.

However, in the case of recovering the iron in the above manner it is not possible to collect the floating fine particles in accordance with the transport of the fluid and to give a sufficient time for the fine particles to precipitate due to the continuous flow path configuration. Therefore, a large amount of fine particles are suspended in the flow path, there is a problem that damage occurs due to precipitation in unspecified place or wear of equipment.

In addition, the drum-type magnet sorter has a problem in effectively collecting the iron collected during continuous operation due to the configuration limit of the flow path in contact with the magnet.

Provided is an iron collection device for effectively collecting and transporting iron suspended in the flow path.

In addition, it provides an iron collection device that is easy to install in the flow path, does not interfere with the flow of water, and enables the optimum channel efficiency and discharge according to the flow rate and the amount of suspended iron.

The iron collecting device is arranged between the upper and lower parts of the frame at predetermined intervals, and is disposed between the upper and lower parts of the frame and moved between the upper and lower parts of the frame as external force is transmitted, and the iron contained in the flow path is collected or collected iron. A plurality of sliding members for separating the; and a plurality of guide members for connecting the upper and lower parts of the frame to guide the movement of the plurality of sliding members, the plurality of sliding members are variable in response to the state of being coupled and separated from each other The iron is collected or separated according to the strength of the magnetic force.

The plurality of sliding members have a plurality of thin plate-shaped magnet plates extending along the longitudinal direction of the guide member, and each of the magnet plates is mounted under the magnet member and a magnet member having a plurality of magnetic bodies, and a plurality of magnet plates are inserted therein. It may include a collecting member having a plurality of collecting plates.

The plurality of magnetic bodies are arranged over the entire surface of the magnet plate, and the plurality of magnetic bodies may vary the strength of the magnetic force according to the arrangement position.

Magnetic materials coupled to the upper side of the magnet plate may be arranged to have a greater intensity of magnetic force than magnetic bodies coupled to the lower side of the magnet plate.

The collecting member is made of at least the outer surface of the collecting plate is made of non-magnetic material, the iron attached to the outer surface of the collecting plate in the state that the magnet plate and the collecting plate is combined, and the iron plate attached to the outer surface of the collecting plate as the magnet plate is separated from the collecting plate. Can make it fall.

The plurality of sliding members are mounted below the collecting member, and further include a slag rack member having a plurality of holes to which the plurality of collecting plates are respectively coupled, and the plurality of sliding members are arranged and engaged in a sequentially adjacent or spaced apart relationship. Can be.

The slag rack member further includes an iron removing member coupled to each hole, and the iron removing member may remove iron remaining on the outer surface of the collecting plate as the slag rack member moves in contact with the outer surface of the collecting plate. . Iron removing member may be made in the form of a brush.

It is disposed on one side of the frame, may further comprise a collecting member for moving to the lower portion of the slag rack member to collect the iron falling freely from the collecting plate.

The plurality of guide members may be disposed at four in the front and at the rear in the rear of the frame, and the plurality of conveying members may be disposed at the front and two at the rear.

It further comprises a plurality of transfer members connecting the upper and lower parts of the frame, and provided separately from the guide member to transfer the driving force to the sliding member, wherein the plurality of transfer members are associated with the transfer of the magnet member, the first transfer member, slag rack And a second transfer member that is related to the transfer of the member, wherein the plurality of transfer members may be in a coupling relationship between the transfer screw and the transfer nut coupled to the respective members.

The first conveying member and the second conveying member are arranged one by one so as to correspond to each other in a diagonal direction of the front and the rear with respect to the plane of the frame, and the two conveying members are composed of a pair, and the power transmission between each conveying member is performed by a belt or It can be made of chains.

A driving part driven according to an input of a driving control signal supplied from the outside to provide a driving force to the conveying member, wherein the driving part includes a first drive part related to the magnet member side drive, and a second part related to the slag rack member side drive; The driving unit may include a first driving unit and a second driving unit, respectively.

An iron detection sensor for detecting iron content contained in the flow path, and a control unit for supplying a drive control signal corresponding to the control program set according to the iron content input from the iron detection sensor to the drive unit.

It is possible to effectively collect the iron contained in the channel, and to treat the flow of water within a state that has little influence on the flow of the flow path, and to prevent the damage of secondary equipment through the excellent effect on the recovery of fine iron particles. Can be.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the specification and drawings, the same reference numerals denote the same elements.

Embodiments of the present invention relate to an iron collection device for collecting suspended iron (including fine iron) without sedimentation in the water containing iron, it is possible to install in a narrow space and the flow of fluid on the water channel It does not affect the high iron collection rate.

Iron generated from some processes of the steel industry is mixed with water such as high pressure water, and some of the precipitate is precipitated, and extremely fine particles float and move along the flow path. Fine particles settle in a certain place and block the flow path or cause abrasion of the pump impeller and should be effectively collected.

Embodiment of the present invention is an iron collector for collecting and separating the iron particles suspended in the fluid in the flow path through the magnetic force.

1 is a view schematically showing an iron collecting device according to an embodiment of the present invention, Figure 2 is a view showing a state in which the iron collecting device according to an embodiment of the present invention installed in the waterway (80).

1 and 2, the iron collection device according to an embodiment of the present invention, the frame 10, the sliding member 20, the guide member 30, the transfer member 40, the drive unit 50, the iron detection The sensor 70 includes a control unit 60.

The frame 10 is disposed at an upper portion 10a and a lower portion 10b at predetermined intervals.

A plurality of sliding members 20 are disposed between the upper portion 10a and the lower portion 10b of the frame 10 and moved between the upper portion 10a and the lower portion 10b of the frame 10 as the external force is transmitted to the flow path. Collect and collect the contained iron.

The plurality of sliding members 20 includes a magnet member 200, a collecting member 210, and a slag rack member 220, each of which is disposed between the upper portion 10a and the lower portion 10b of the frame 10. It is disposed in a vertical direction, and arranged so as to be coupled in a sequentially adjacent or spaced apart relationship from the upper portion 10a to the lower portion 10b of the frame 10. The plurality of sliding members 20 may collect or separate iron powder according to a varying strength of magnetic force corresponding to a state in which the plurality of sliding members 20 are close to or spaced apart from each other. That is, the iron powder may be collected or separated according to the strength of the magnetic force transmitted to the corresponding member among the plurality of sliding members 20.

The magnet member 200 includes a plurality of thin plate-shaped magnet plates 202 extending along the longitudinal direction of the guide member 30, and each of the magnet plates 202 is provided with a plurality of magnetic bodies 204. The plurality of magnet plates 202 may be arranged by arranging several sheets at predetermined intervals, and each magnet plate 202 is connected to the magnet member 200, respectively. The magnetic body 204 is composed of a permanent magnet of circular or polygonal thickness.

Meanwhile, the plurality of magnetic bodies 204 may be uniformly arranged or irregularly arranged over the entire surface of the magnet plate 202. In addition, the plurality of magnetic bodies 204 may vary the strength of the magnetic force according to the arrangement position. For example, the magnetic bodies 204 coupled to the upper side of the magnet plate 202 may have a greater intensity of magnetic force than the magnetic bodies 204 coupled to the lower side of the magnet plate 202. That is, the upper side of the front of the magnet plate 202 can close the arrangement of the magnetic body 204, and the lower side can be made small. If the magnet plate 202 is inserted into the same flow path as the water 82 of the water flow path 80, it is possible to maximize the trapping effect of iron through the flow inhibition of the fluid in the flow path.

The collecting member 210 is mounted below the magnet member 200 and has a collecting plate 212 into which a plurality of magnet plates 202 are inserted. Each collecting plate 212 is formed to surround the respective magnet plate 202, the magnet plate 202 is free to move up and down in the collecting plate (212). The quantity of the magnet plate 202 and the collection plate 212 may increase or decrease according to the iron collection demand. The collecting member 210 has at least an outer surface of the collecting plate 212 made of a nonmagnetic material, and the magnet plate 202 having the magnetic material 204 is coupled to the collecting plate after the magnet member 200 and the collecting member 210 are coupled to each other. As it is separated from the 212, the iron 84, which was attached to the outer surface of the collecting plate 212, falls freely. That is, the iron powder 84 is formed on the outer surface of the collecting plate 212 by the magnetic force generated by the plurality of magnetic bodies 204 coupled to the magnet plate 202 while the magnet plate 202 and the collecting plate 212 are coupled to each other. It sticks. As the magnet plate 202 is separated from the collecting plate 212, the magnetic force applied to the collecting plate 212 gradually disappears, and the iron 84 attached to the outer surface of the collecting plate 212 falls.

The slag rack member 220 is mounted below the collecting member 210 and has a hole 222 to which the plurality of collecting plates 212 are coupled. The holes 222 of the slag rack member 220 are adjacent to the outer surface of the collecting plate 212 and may be coupled at least in a loose fit.

Meanwhile, the slag rack member 220 may further include an iron removing member 224 coupled to each hole 222. The iron removing member 224 removes iron 84 remaining on the outer surface of the collecting plate 212 as the slag rack member 220 moves in contact with the outer surface of the collecting plate 212. Iron removing member 224 may be made in the form of a brush.

Embodiment of the present invention is disposed on one side of the frame 10, and further comprises a collecting member for moving the lower portion of the slag rack member 220 to collect the iron (84). The collecting member may include a chute 90, a scraper 92, a rack and a pinion, a conveyor belt for conveyance, and the like.

Guide member 30 is composed of a plurality of connecting the upper (10a) and lower (10b) of the frame 10 to guide the movement of the plurality of sliding members (20).

The transfer member 40 connects the upper portion 10a and the lower portion 10b of the frame 10, and is provided in plural from the guide member 30 to transmit the driving force to the sliding member 20.

The plurality of guide members 30 and the conveying member 40 may be changed in design depending on the quantity and arrangement of the driving unit 50. In addition, the quantity of the driving unit 50 may be designed differently depending on the quantity of the plurality of sliding members 20.

For example, when two driving units 50 are installed, two transfer units may be connected to each driving unit 50 in a power transmission relationship. In this case, the plurality of guide members 30 and the transfer member 40 may be installed only in one side direction (front or rear) of the upper frame 10a. When installed only in front of the upper frame 10a, the plurality of guide members 30 may be disposed two by one on each side. In addition, the plurality of transfer members 40 may be arranged in a structure in which two transfer units are connected to each driving unit 50.

On the contrary, when four driving units are installed, the plurality of guide members may be disposed two and two at the front of the upper frame 10a, and the plurality of transfer members may be four at the front and four at the rear.

In addition, as shown in the embodiment of the present invention, two driving units 50 are installed, and the plurality of guide members 30 and the transfer member 40 are front and rear with respect to the plane on the upper portion 10a of the frame 10. Can be placed on both. In this case, as shown in FIG. 1, the plurality of guide members 30 may be disposed in two at the front and two at the rear, and the plurality of transfer members 40 may be disposed at four at the front and four at the rear. The plurality of transfer members 40 may include a first transfer member related to the transfer of the magnet member 200 and a second transfer member related to the transfer of the slag rack member 220. The first conveying member and the second conveying member may be arranged one by one so as to correspond to each other in a diagonal direction of the front and the rear with respect to the plane in the upper portion 10a of the frame 10, and two conveying members may be formed as a pair. The transfer member 40 is formed by a coupling relationship between a transfer screw connected to the driving unit 50 and a transfer nut coupled to the respective members. Each of the first transfer member and the second transfer member spaced apart from each other is powered by a belt or chain.

The driving unit 50 is driven according to an input of a driving control signal supplied from the outside to provide a driving force to the transfer member 40. As described above, the quantity of the driving unit 50 may be provided to correspond to the quantity of the plurality of sliding members 20. Alternatively, the quantity of the driving unit 50 is different from the quantity of the plurality of sliding members 20. Design changes may also be made. For example, as in the embodiment of the present invention, the driving unit 50 includes the first driving unit 52 related to the driving of the magnet member 200 side and the second driving unit 54 related to the driving of the slag rack member 220 side. ) May be included. In this case, the driving unit for driving the collecting member 210 may be omitted, and may have a structure that is linked to the movement of the magnet member 200. In detail, the collecting member 210 may be supported by an elastic spring and interlocked according to a pressure that is pressed when the magnet member 200 descends. If the pressing force transmitted to the collecting member 210 when the magnet member 200 descends while the collecting member 210 is supported by the elastic spring is greater than the elastic force of the elastic spring, the collecting member 210 is the magnet member 200. It is linked with and descends. When the pressing force of the magnet member 200 is released, the magnet member 200 may be restored to its position by the restoring force of the elastic spring. The driving unit 50 may be made of a motor. In addition, the driving unit 50 may be formed of a hydraulic cylinder or a pneumatic cylinder.

The iron detection sensor 70 is a sensor for detecting iron content contained in the flow path.

The controller 60 supplies a driving control signal to the driver 50. The controller 60 supplies a control signal corresponding to the control program set according to the iron content input from the iron detection sensor 70 to the driver 50.

3a to 3h is a view showing the operation sequence of the iron collection device according to an embodiment of the present invention.

An iron collection operation of the iron collection device according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3H.

First, the iron collection device may be operated by selecting and inputting an automatic or manual method into the control unit 60. Here, the selection of the automatic method or the manual method can be divided into the presence or absence of repetition of the iron collection operation, the operation method of the iron collection device can be the same as the automatic method and the manual method.

FIG. 3A illustrates a state in which the iron is collected and the initial state in which both the first driver 52 and the second driver 54 are stopped. When the first driving unit 52 is driven in this state, as shown in FIG. 3B, the upper magnet member 200 descends along the guide member 30 mounted on the frame 10. And each magnet plate 202 coupled to the magnet member 200 is inserted into each collection plate 212 coupled to the collecting member 210.

With each magnet plate 202 coupled to the corresponding collecting plate 212, the magnet member 200 and the collecting member 210 continue along the guide member 30 to the position of the slag rack member 220. Descend. When the magnet member 200 and the collecting member 210 reach the predetermined position, the magnet member 200 and the collecting member 210 are lowered together with the slag rack member 220 as shown in FIG. 3C according to the driving of the second driving unit 54.

Referring to FIG. 3C, the magnet plate 202 is inserted into the collecting plate 212, and the collecting plate 212 is integrated into the hole 222 of the slag rack member 220 to be integrated into the water flow path 80. ) Is submerged in water 82. That is, the magnet plate 202, the collecting plate 212, and the slag rack member 220 constituting the sliding member 20 are coupled to each other in a state in which they are inserted into each other in a vertically arranged state and are integrated to each other. It is submerged in water 82. Since the magnet plate 202 and the collecting plate 212 is in a coupled state, the iron 84 contained in the water 82 of the water passage 80 is attached to the outer surface of the collecting plate 212.

In this case, the controller 60 may control the collection time according to the concentration of iron input from the iron detection sensor 70.

Thereafter, the sliding members 20 (the magnet member 200, the collecting member 210, and the slag rack member 220) are raised in an integrated state according to the control operation of the controller 60. At this time, the first driver 52 and the second driver 54 are driven simultaneously.

Subsequently, as shown in FIG. 3D, when the chute 90 reaches a position capable of being inserted into the lower portion of the sliding member 20 while the sliding member 20 is raised to collect iron collected in the sliding member 20. A separate motor that drives the rack and pinion attached to 90 is driven. Then, the chute 90 moves in the downward direction of the sliding member 20, and is in a state as shown in FIG. 3E.

In the state of FIG. 3E, the second driver 54 is stopped and only the first driver 52 is driven so that the magnet member 200 continues to rise. Then, the magnet plate 202 inserted into the collecting plate 212 is separated from the collecting plate 212. As the magnet plate 202 having the magnetic body 204 is separated from the collecting plate 212, the iron 84 attached to the outer surface of the non-magnetic collecting plate 212 falls freely and falls on the chute 90.

In this case, some iron 84 may remain on the outer surface of the collecting plate 212. In order to remove the iron powder 84 remaining on the outer surface of the collecting plate 212, the second driving unit 54 is rotated in reverse to allow the slag rack member 220 to descend so that the outer surface of the collecting plate 212 and the slag rack member ( 220 is performed.

3F and 3G, the slag rack member 220 descends while the outer surface of the collecting plate 212 is fitted into the hole 222 of the slag rack member 220 and coupled thereto. As the slag rack member 220 is separated from the collecting plate 212, iron 84 remaining on the outer surface of the collecting plate 212 may be removed and shaken off on the chute 90. At this time, the brush-type iron removing member 224 coupled to the hole 222 of the slag rack member 220 can reliably remove the iron 84 remaining on the outer surface of the collecting plate 212. Since the iron removing member 224 may maintain a state in direct contact with the outer surface of the collecting plate 212, the iron removing member 224 may be in close contact with the outer surface of the collecting plate 212 according to the movement of the slag rack member 220. By providing the iron removing member 224, the effect of cleaning the outer surface of the collecting plate 212 with a brush can be obtained.

Then, when the chute 90 is reversed, the iron 84 on the chute 90 is dropped to the secondary conveying belt by the scraper 92 fixed to the upper part and is transferred to a predetermined place.

As described above, once the collection and collection of iron 84 is completed through a series of processes, the above process may be repeated from the beginning.

1 is a view schematically showing an iron collection device according to an embodiment of the present invention.

2 is a view showing a state in which the iron collecting device according to an embodiment of the present invention is installed in the water passage.

3A to 3H are diagrams sequentially showing operations of the iron collecting device according to the embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

10; Frame 20; Sliding member

30; Guide member 40; Conveying member

50; Drive unit 52; First driving part

54; Second driving unit 60; Control

70; Iron detection sensor 80; irrigation channel

90; Chute 200; Magnet member

202; Magnet plate 204; Magnetic material

210; Collecting member 212; Capture plate

220; Slag rack member 224; Iron removal member

Claims (15)

A frame disposed at an upper portion and a lower portion at predetermined intervals; A plurality of sliding members disposed between the upper and lower parts of the frame and moved between the upper and lower parts of the frame as external force is transmitted, and collecting iron or separating the collected iron from the flow path; A plurality of guide members connecting upper and lower portions of the frame to guide movement of the plurality of sliding members; A plurality of transfer members connecting upper and lower portions of the frame and separately provided from the plurality of guide members to transfer driving force to the plurality of sliding members; An iron detection sensor for detecting iron content contained in the flow path; A control unit for generating a driving control signal corresponding to a control program set according to the iron content input from the iron detection sensor; A driving unit driven according to an input of a driving control signal supplied from the control unit to provide a driving force to the plurality of transfer members; Including; The plurality of sliding members are iron collection device for collecting or separating the iron in accordance with the intensity of the magnetic force is variable corresponding to the state in which they are adjacent to or spaced apart from each other. The method of claim 1, The plurality of sliding members A magnet member having a plurality of thin plate-shaped magnet plates extending along the length direction of the guide member, each magnet plate having a plurality of magnetic bodies; and A collecting member mounted below the magnet member and having a plurality of collecting plates into which the plurality of magnet plates are inserted; Iron collection device comprising a. The method of claim 2, And the plurality of magnetic bodies are arranged over the entire surface of the magnet plate, and the plurality of magnetic bodies vary in intensity of magnetic force according to an arrangement position. The method of claim 3, Magnetic body coupled to the upper side of the magnet plate is the iron collection device arranged to have a greater intensity of magnetic force than the magnetic body coupled to the lower side of the magnet plate. The method of claim 4, wherein And said collecting member is at least an outer surface of said collecting plate made of nonmagnetic material. The method of claim 5, Iron is attached to the outer surface of the collecting plate in the state in which the magnet plate and the collecting plate, and the iron attached to the outer surface of the collecting plate is falling as the magnet plate is separated from the collecting plate. The method of claim 6, A slag rack member mounted below the collecting member and having a plurality of holes to which the plurality of collecting plates are coupled; The plurality of sliding members Iron collection device is coupled sequentially or spaced apart sequentially. The method of claim 7, wherein The slag rack member is iron removal member coupled to each hole More, And the iron removing member removes iron remaining on the outer surface of the collecting plate as the slag rack member moves in contact with the outer surface of the collecting plate. The method of claim 8, The iron removing member is iron collection device made of a brush form. 10. The method of claim 9, It is disposed on one side of the frame, the iron collecting device further comprises a collecting member for moving to the lower portion of the slag rack member to collect the iron falling freely from the collecting plate. The method of claim 10, The plurality of guide members Two in front and two in the rear with respect to the plane of the frame, The plurality of transfer members Iron collection device is arranged in the front and the rear four with respect to the plane of the frame. The method of claim 11, The plurality of transfer members A first transfer member related to the transfer of the magnet member; A second conveying member related to conveying of the slag rack member Including; The plurality of conveying members are iron collection device made of a coupling relationship between the conveying screw and the conveying nut. The method of claim 12, The first conveying member and the second conveying member are disposed one by one so as to correspond to each other in a diagonal direction of the front and the rear with respect to the plane of the frame, and the two conveying members are formed in a pair, and each conveyed apart from each other. The member is an iron collector that is powered by a belt or chain. The method of claim 13, The driving unit A first drive unit related to the magnet member side drive, and Second drive part related to the said slag rack member side drive Including, And the first driving unit and the second driving unit are each made of a motor. delete

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