KR101544614B1 - Magnetic separation apparatus - Google Patents

Abstract

The magnetic flux contained in the raw water can be removed with high performance by solving the problems of the adsorption separation efficiency and the recovery efficiency of the magnetic flux possessed by the conventional magnetic separator.

A plurality of magnetic disks 36 are disposed in the raw water of the separation tank 32 so as to be semi-molten so as to separate the raw water from the water supply port 44 formed at the lower end of the separation tank 32 The raw water supplied from the water supply port 44 is divided into the left and right direction and the thickness direction of the surface of the magnetic disk 36, A pair of troughs 45 for removing the magnetic flux F from the raw water by the magnetic disk 36 are provided on both side surfaces of the separating tank 32 parallel to the rotation axis of the separating tank 32, (Trough) 40 is provided.

Magnetic separator, magnetic disk, magnetic floc, magnetic powder.

Description

MAGNETIC SEPARATION APPARATUS

The present invention relates to a magnetic separator, and more particularly, to a technique for separating and removing magnetic flocs in raw water by adsorbing the magnetic flocs in raw water.

There is a magnetic separator as an apparatus for removing pollutants present in raw water such as sewage or factory drainage. This magnetic separator is formed of a magnetic floc having magnetism by adding a coagulant and a magnetic powder in raw water, and the magnetic flux F is adsorbed to a magnetic disk on which magnets are disposed to separate And is called a magnetic seed method.

Patent Document 1 discloses a solid-liquid separating device in which a magnetic separating device is assembled. As shown in Patent Document 1, the magnetic separation apparatus is a system in which a plurality of (plural number of) magnetic disks in which magnets are attached in a separation tank (separation tank) are arranged And is removed and recovered in raw water.

Patent Document 1: JP-A-10-244424

However, it can not be said that the conventional magnetic separator still has sufficient performance in removing magnetic flux from raw water in the following points.

(1) It is important for the raw water supplied into the separation tank to evenly contact a plurality of magnetic disks to effectively remove the magnetic flux in the raw water. However, the conventional magnetic separation apparatus is prone to water flow in the separating tank.

(2) In the case where the magnetic flux is semi-water-immersed in the raw water in the separating tank, the magnetic flux adsorbed on the magnetic disk is easily peeled off from the raw water, It is hard to be peeled off because it is fixed on the surface of the magnetic disk. It can not be said that the conventional magnetic separator has a countermeasure for the problem of peeling off the magnetic flux once adsorbed to the magnetic disk in the raw water and a countermeasure for efficiently recovering the adsorbed magnetic flux in the atmosphere.

SUMMARY OF THE INVENTION The present invention has been made in view of such circumstances, and it is an object of the present invention to provide a magnetic separation device capable of eliminating the problems of adsorption separation efficiency and recovery efficiency of a magnetic flux possessed by a conventional magnetic separation device, The purpose is to provide.

According to a first aspect of the present invention, there is provided a separation tank for separating raw water containing magnetic flocs into a separation tank for introducing a magnetic floc into the separation tank, A plurality of magnetic disks that are juxtaposed at predetermined intervals on the rotation axis of the magnetic disk to attract the magnetic flux by magnetic force and a recovery means for recovering the attracted magnetic flux, Wherein the plurality of magnetic disks are arranged so as to be approximately half molten in the raw water of the separation tank so that the raw water is supplied from the water feed port formed at the lower end of the separation tank as an upward flow into the separation tank, (Splitting) the raw water supplied from the water supply port in the left and right direction of the magnetic disk surface and in the thickness direction of the magnetic disk is disposed right under each of the plurality of magnetic disks Wherein a pair of troughs are provided on both sides of the separation tank in parallel with the rotation axis, the troughs of which the magnetic flux in the raw water is removed by the magnetic disk do.

According to claim 1, the raw water supplied from the water supply port formed at the lower end of the separation tank collides with the separating member and is divided into the radial direction of the magnetic disk and the thickness direction of the magnetic disk. As a result, the raw water supplied from the water supply port collides with the separating member and flows in the left and right direction and the thickness direction of the magnetic disk, so that the flow rate of the raw water flowing between the magnetic disks is decelerated and flows upwardly . The magnetic flux in the raw water can be efficiently adsorbed to the magnetic disk.

In addition, since a pair of troughs in which magnetic fluxes are removed from the raw water by the magnetic disk are provided on both sides of the separation vessel parallel to the rotation axis, Can be quickly discharged out of the separating tank.

Also, by arranging the separating member directly below the magnetic disk, the raw water can be prevented from flowing in the vicinity of the surface of the magnetic disk due to an upward flow with a high flow velocity, so that the magnetic flux once attracted to the surface of the magnetic disk is peeled off and dropped into the raw water There is nothing to drink.

[2] According to claim 2, the separating member is formed in a wedge shape in which the thickness of the top surface is formed to be equal to the thickness of the magnetic disk, and at the same time, the thickness becomes thinner toward the lower end.

By forming the shape of the sorting member as described in claim 2, the raw water supplied from the water supply port can be accurately classified in the radial direction and the thickness direction of the magnetic disk.

According to a third aspect of the present invention, in the first or second aspect of the present invention, the water supply port is formed as a long rectangular tube in the direction of the rotation axis.

As described in claim 3, since the water supply port is formed in the shape of a long rectangular tube in the direction of the rotation axis, it is easy to uniformly supply water into the separation tank, and the removal performance of the magnetic flux can be further improved.

[0028] In addition, according to the present invention, it is preferable that a base end portion is fixed to the inner surface of the separation vessel between the outer circumferential surface of each of the plurality of magnetic disks and the inner surface of the separation vessel, And a sealing plate which is in contact with the sealing plate.

According to Claim 4, since a sealing plate is provided between the outer circumferential surface of each of the plurality of magnetic disks and the inner surface of the separation tank, a flow that makes the outer circumferential surface of the magnetic disk take a short route and flows over the magnetic disk surface It is possible to further improve the removal of the magnetic flux.

According to a fifth aspect of the present invention, in the magnetic disk apparatus according to any one of the first to fourth aspects of the present invention, the recovering means is disposed between the magnetic disks immediately before the rotating magnetic disk enters the raw water in the atmosphere, A groove normal scraper for scraping off the magnetic flux attracted to the surface of the magnetic disk by abutting the edge portion of the upper side of both sides with a predetermined urging force on the magnetic disk surface, And transporting means for transporting the magnetic flux dropped and deposited in the separation tank to the outside of the separation tank.

According to claim 5, since the rotating magnetic disk is grooved to the outside of the separating tank in the vicinity of the rotating shaft between the magnetic disks immediately before entering the raw water in the atmosphere, Even if there is a magnetic flux stuck to the surface of the magnetic disk by drying in air by providing a groove scraper for scraping the magnetic flux attracted to the surface of the magnetic disk by abutting against the magnetic disk surface, The flock can reliably be recovered into the groove scraper.

INDUSTRIAL APPLICABILITY As described above, the magnetic separation apparatus according to the present invention eliminates the problem of the adsorption separation efficiency and recovery efficiency of the magnetic flux possessed by the conventional magnetic separation apparatus, and can remove the magnetic flux contained in the raw water with high performance.

Hereinafter, preferred embodiments of the magnetic separator according to the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 is a block diagram for explaining the flow of assembling the magnetic separation apparatus 20 of the present invention to the polluted water purification system 10. Fig. 2 is a conceptual diagram of the flocculation apparatus 14, the magnetic separation apparatus 20, and the filter separation apparatus 24 constituting the sewage water purification system 10.

As shown in Fig. 1, the raw water is sent (sent) to the rapid stirring tank 14A of the flocculating apparatus 14 by the raw water pump 12 in the contaminated water purification system 10. In addition, a self-component addition device 16 for adding a magnetic component and a flocculant addition device 18 for adding a flocculant are provided during the piping connecting the raw water pump 12 and the rapid stirring tank 14A, And a flocculant are added in the raw water flowing in the piping. As the magnetic component, for example, iron oxide yellow can be preferably used. As the coagulant, a water-soluble inorganic coagulant such as aluminum chloride, iron chloride, ferric sulfate or the like can be preferably used. Although not shown, it is preferable that a relatively large dirt having a size of several millimeters is filtered by installing a strainer before the magnetic powder or coagulant is added to the raw water.

In the rapid stirring tank 14A, the raw water, the added magnetic component and the coagulant are rapidly stirred by a stirring blade 19 rotating at a high speed to form minute magnetic flocs (also referred to as magnetic micro flocs) of several tens of micrometers in size . It is preferable that the rotational speed at the tip of the stirring vane 19 is about 1 to 2 m / sec. Magnetic microfluxes contain self-components, solid suspended particles in raw water, bacteria, and plankton.

Then, the raw water containing the magnetic micro-flocs is sent (sent) to the slow stirring tank 14B of the coagulation apparatus 14. A polymer flocculant addition device 21 for adding a polymer flocculant to the vicinity of the communication chamber 14C connecting the rapid stirring tank 14A and the slow stirring tank 14B is provided and the communication chamber 14C The polymer flocculant is added to the raw water flowing through the column. As the polymer flocculant, an anionic type and a nonionic type can be suitably used.

The slow stirring vessel 14B stirs the magnetic microfluid and the polymer flocculant at a low speed with a stirring blade 19 rotating at a low speed to form a magnetic flux F having a size of several hundreds of micrometers to several millimeters. As shown in Fig. 2, the slow stirring tank 14B is preferably composed of a plurality of continuous multi-stage stirring vessels A, B and C. In this case, the rotating speed of the stirring vane 19 is set to be low as it moves from the slow stirring vessel A on the upstream side to the slow stirring vessel C on the downstream side. It is possible to prevent the magnetic flux F from growing along with the growth of the magnetic flux F from the slow stirring vessel A on the upstream side toward the slow stirring vessel C on the downstream side. For example, as the rotating peripheral speed at the tip of the stirring vane 19, the slow stirring tank A is about 0.5 to 1 m / sec, the slow stirring tank B is about 0.3 to 0.7 m / (C) is about 0.1 to 0.3 m / sec.

As shown in Fig. 2, the flocculation apparatus 14 is preferably configured as a unit having a unitary structure of the rapid stirring tank 14A, the communication chamber 14C, and the slow stirring tank 14B, but each of them may be a pipe .

Raw water containing magnetic flux F of increased size is fed to the magnetic separator 20 of the present invention. The magnetic separation device 20 adsorbs and separates the magnetic flux F in the raw water by the magnetic force and about 90% of the magnetic flux F in the raw water is separated and removed by the magnetic separation device 20. The configuration of the magnetic separation apparatus 20 will be described in detail after the entire flow of the polluted water purification system 10 is described.

The magnetic flux F removed from the magnetic separator 20 is reduced to a water content of about 80% by a dewatering device 25 such as a centrifugal separator or a belt press, and then discharged to a landfill or incinerator, .

On the other hand, the treated water processed by the magnetic separator 20 is then sent to and from the filter separator 24. In the filter separator 24, the process water is filtered from the inside to the outside of the rotary drum filter 26 to remove the magnetic flux F remaining in the process water.

As a result, raw water including dirt, solid suspended particles, bacteria, and plankton can be purified. The magnetic flux F attached to the rotary drum filter 26 is supplied to the rotary drum filter 26 by showering the washing water from a showering device 28 disposed above the rotary drum filter 26 And discharged out of the apparatus. In this case, a part of the treated water purified by the rotary drum filter 26 may be returned to the showering device 28 by the circulation pump 29 and reused as washing water. The soiled rinsing water containing the magnetic flux F by the shower ring is returned to the front end of the raw water pump 12 by the pump 30.

[Magnetic Separation Device]

FIG. 3 is a perspective view showing a part of the magnetic separation device 20 of the present invention, FIG. 4 is a side sectional view, and FIG. 5 is a front sectional view.

As shown in these drawings, the magnetic separation device 20 of the present invention comprises a separation tank 32 into which raw water containing magnetic flux F flows, A plurality of magnetic disks 36 which are arranged side by side at a predetermined interval in the magnetic disk 34 and which attract the magnetic flux F by a magnetic force and a recovery means 35 for recovering the magnetic flux F attracted to the magnetic disk 36 (38). Although the embodiment of the present embodiment is described as an example of three or four magnetic disks 36, the number is not limited to three.

The separating tank 32 is formed into a semicylindrical shape in which an upper surface is opened and both end surfaces are closed by side walls 41 (see FIG. 5). A pair of concave concave troughs 40 formed parallel to the rotating shaft 34 are integrally formed with the separating tank 32 at both sides of the separating tank 32 A concave flute collection tank 42 having a cross section parallel to the trough 40 is provided outside the trough 40. 3, the flux recovery tank 42 is provided on the right side (the right side in FIG. 3) of the rotating magnetic disk 36 entering the raw water.

5, a rotary shaft 34 is rotatably supported on a pair of side walls 41 of the separation tank 32 through a bearing 35 and one end of the rotary shaft 34 is connected to a motor 39 . A plurality of magnetic disks (36) having insertion holes at the center are inserted and supported on the rotary shaft (34) at predetermined intervals. Between the magnetic disks 36, there is provided a sleeve 31 for adjusting the distance between the magnetic disks 36 and fixing the inner peripheral portion of the magnetic disk 36. It is preferable that the interval between the magnetic disks 36 is set in the range of 1 to 3 times the thickness of the magnetic disk 36. [ If the distance is less than 1 time, the raw water flows between the magnetic disks 36, and if it is more than 3 times, it is difficult to generate a strong magnetic force between the magnetic disks 36.

It is also preferable that a plurality of magnetic disks 36 supported by the rotary shaft 34 are submerged at a ratio of 1/2 to 2/3 of the raw water in the separation tank 32. In the case where the magnetic disk 36 is partly submerged as described above, the magnetic flux F attracted to the magnetic disk 36 in the raw water is rotated by the magnetic disk 36 and the magnetic flux F is transported to the atmosphere And is recovered by the recovery means (38). Therefore, it is important to set the submergence rate of the magnetic disk 36 so that the efficiency of attraction and recovery of the magnetic flux F is maximized. For this reason, for example, a pair of bearings 35 that rotatably support the rotary shaft 34 is supported by a pair of elevators (not shown), and the magnetic disk 36 is lifted and lowered by a hydraulic mechanism or the like, It is also a good idea to configure it to do so.

A water supply port 44 is formed at the lower end of the separating tank 32 in the axial direction of the rotary shaft 34 so that the water supply port 44 and the outlet of the coagulation apparatus 14 are connected to a pipe 43 (see Fig. 4). A plurality of sorting members 46 (see FIG. 5) are disposed in the water supply port 44. 5, the separating member 46 is disposed immediately below each magnetic disk 36 so that the thickness W1 of the top surface is formed to be equal to the thickness W2 of the magnetic disk 36 And is formed into a cross-sectional wedge shape in which the thickness becomes thinner toward the lower end. 4, the width D1 of the separating member 46 is smaller than the width D2 of the water supply port 44 so that the raw water supplied to the water supply port 44 is supplied to the water supply port 44 and the separating member 44 (44A, 44B; gap) formed between the left and right gaps (46, 46).

The raw water supplied from the water supply port 44 by the separating member 46 impinges on the separating member 46 and is divided into left and right portions in the radial direction of the magnetic disk 36 as shown in FIG. The raw water supplied from the water supply port 44 impinges on the sorting member 46 and is classified as two flows in the left and right direction so that the flow rate of the raw water flowing between the magnetic disks 36 is reduced, So that they flow upwardly and flow slowly between them. The magnetic flux F in the raw water can be efficiently adsorbed to the magnetic disk 36. [ Further, by decelerating the flow rate of the upward flow, it becomes difficult for the magnetic flux F once attracted to the magnetic disk 36 to peel off.

The raw water flowing into the separating tank 32 from the water supply port 44 by the separating member 46 is also classified in the thickness direction of the magnetic disk 36 as shown in Fig. It is possible to prevent the magnetic flux F adsorbed on the magnetic disk 36 from peeling off by the water flow of the raw water supplied from the water supply port 44. 5, if the wedge-shaped separating member 46 is not provided, the outer peripheral surface 36a of the magnetic disk 36 is directly exposed to the upward flow of the raw water supplied from the water supply port 44 .

6, the flow of the raw water in the absence of the separating member 46 flows in the vicinity of the surface of the magnetic disk 36 with a flow of a high flow rate so as to appear as a dotted line, The magnetic flux F near the portion of the outer circumferential surface 36a of the magnetic flux F adsorbed on the surface is scraped off by the flow of the raw water and falls out of the raw water. On the other hand, the outer peripheral surface 36a of the magnetic disk 36 is not directly exposed to the flow of the raw water by the separating member 46 so that the raw water flowing in from the water feed port 44, (46), the flow velocity is slowed and is further divided into the thickness direction of the magnetic disk (36). The magnetic flux F once attracted to the magnetic disk surface is not scratched by the flow of the raw water.

4, the separation tank 32 seals a gap between the outer circumferential surface 36a of the magnetic disk 36 and the inner surface of the separation tank 32 and feeds the raw water supplied from the water supply port 44 A sealing plate 48 is provided to prevent the outer circumferential surface 36a of the magnetic disk 36 from shorting to the trough 40. [

7, the base end portion is fixed to the rotating shaft 50 rotatably supported by the separating tank 32 and the tip end portion is fixed to the outer peripheral surface 36a of the magnetic disk 36 as a free end Respectively. The rotating shaft 50 is rotationally urged in the direction of the arrow by a spring (not shown) or the like. The sealing plate 48 is brought into contact with the outer circumferential surface 36a of the magnetic disk 36 with a predetermined contact force so that the rotation of the magnetic disk is not hindered so that the raw water passes through the outer circumferential surface 36a of the magnetic disk 36, it is possible to prevent a short route. As the material of the sealing plate 48, an elastic body that is softer than the magnetic disk 36 is preferable, and for example, a rubber plate can be suitably used.

Next, the magnetic disk 36 will be described.

The magnetic disk 36 is constructed by disposing a disk substrate 33 of a ferromagnetic material sandwiched between permanent magnet pieces 37 in a case 45 of a nonmagnetic body in which a cavity on a torus is formed. Further, a hole for inserting the rotary shaft 34 is formed at the center of the disk substrate 33. Normally, three or more magnetic disks 36 are disposed on the rotating shaft 34.

8A, the outermost magnetic disk 36A disposed at both ends of the rotary shaft 34 and the outermost magnetic disk 36A disposed at both ends of the rotary shaft 34, Permanent magnet pieces 37 are disposed on both sides of an inner magnetic disk 36B disposed close to the disk substrate 33 and a disk substrate 33 having a ferromagnetic body. As a result, there arises a problem of magnetic leakage from the outermost magnetic disk 36A to the outside of the separating tank 32 and a problem of deformation of the outermost magnetic disk 36A.

In the case of the inner magnetic disk 36B, the magnetic force of the inner magnetic disk 36B maintains the equilibrium state as long as the magnetic disks 36 are arranged at equal intervals, There is no worry of.

As a countermeasure, as shown in Fig. 8 (B), the inner magnetic disk 36B is conventionally provided with permanent magnet pieces 37 on both sides of the disk substrate 33 to fix the disk substrate 33 of the ferromagnetic body to the permanent magnet pieces (37). On the other hand, with respect to the outermost magnetic disk 36A, the permanent magnet pieces 37 for exerting magnetic force are disposed only on the inner surface (the side surface of the inner magnetic disk 36B) on both surfaces of the disk substrate 33, One iron plate 52 is disposed on the outer surface of the substrate 33 so that the disk substrate 33 is sandwiched between the magnet and the iron plate 52. In this case, the disk substrate 33 is essentially a ferromagnetic body, but the iron plate 52 may be a ferromagnetic body or a non-magnetic body. Further, the disc substrate 33 and the iron plate 52 may be formed of a single thick ferromagnetic body as an integral body. The stiffness of the outermost magnetic disk 36A is made larger than the stiffness of the inner magnetic disk 36B. It is necessary that the outermost magnetic disk 36A is not deformed against the magnetic force of the inner magnetic disk 36B until the stiffness of the disk substrate 33 of the outermost magnetic disk 36A is increased. Therefore, the thickness of the iron plate 52 may be suitably set by the distance between the outermost magnetic disk 36A and the inner magnetic disk 36B, the magnetic force of the permanent magnet pieces 37, the material of the disk substrate 33, and the like.

In the case of the outermost magnetic disk 36A and the inner magnetic disk 36B, when the disk substrate 33 is made of a ferromagnetic material, the permanent magnet pieces 37 are directly applied to the disk substrate 33 But it is more preferable to adhere with an adhesive. At this time, a structure in which resin is molded in the space formed inside the case 45 is also possible.

In order to increase the rigidity of the magnetic disk 36, a pocket portion (not shown) for inserting the permanent magnet piece 37 is attached to the surface of the disk substrate 330 of the ferromagnetic body and the permanent magnet piece 37 is inserted into the pocket portion .

As a method of manufacturing the magnetic disk 36 in which the plurality of permanent magnet pieces 37 are fixed on the surface of the disk substrate 33, the disk substrate 33 is mounted on at least one surface of the substrate 33, And a permanent magnet piece (37) fitted in a pocket portion of the formed disk substrate (33); and a step of inserting the permanent magnet piece (37) into a disk And a housing process in which the substrate 33 is housed in a case 45 in which a cavity on a torus is formed.

Accordingly, the side wall of the pocket portion 56 serves as a reinforcing member, so that the rigidity can be increased. In this case, the pocket portion needs to be formed of a nonmagnetic material, and the pocket portion is adhered to the ferromagnetic disk substrate 33 with an adhesive. This is because when the pocket portion is formed of a magnetic body (in particular, a ferromagnetic body), magnetic flux is absorbed into the side wall of the pocket portion, so that only a magnetic field in the vicinity of the magnet surface is strengthened, and a high magnetic field is produced at a position away from the permanent magnet piece 37 It becomes difficult.

By configuring the outermost magnetic disk 36A in this way, it is possible to solve the magnetic leakage without providing a magnetic shield or a magnetic coil as a simple countermeasure, and there is no deformation of the outermost magnetic disk 36A. In order to manufacture the inner magnetic disk 36B having the pocket portion, pocket portions may be formed on both sides of the disk substrate 33. [

However, by not providing the permanent magnet piece 37 on the outer surface of the disk substrate 33 of the outermost magnetic disk 36A, the gap between the outer surface of the outermost magnetic disk 36A and the inner surface of the separating tank 32 There is a risk that the passing raw water flows out to the trough 40 without the magnetic flux F being adsorbed and separated. 5, a clearance between the outer surface of the outermost magnetic disk 36A and the inner surface of the separating tank 32 is embedded in the shielding member 54 that does not hinder the rotation of the outermost magnetic disk 36A . As the shielding member 54, it is necessary not to inhibit the rotation of the outermost magnetic disk 36A, and a soft material having a small friction such as a resin or a sponge can be suitably used. The magnetic flux F does not flow out to the trough 40 without the permanent magnet piece 37 being disposed on the outer surface of the outermost magnetic disk 36A. 5, a concave gap is formed between the outer surface of the outermost magnetic disk 36A and the inner surface of the separating tank 32. However, when the outermost magnetic disk 36A is formed, The centrifugal force acts so that the raw water does not stay in the concave clearance.

In order to increase the rigidity of the outermost magnetic disk 36A, there is a method of making the case 45 itself of the magnetic disk 36 a honeycomb structure. By employing this method, the weight of the magnetic disk 36 can be reduced . The method of this honeycomb structure is not limited to the outermost magnetic disk 36A but can also be applied to the inner magnetic disk 36B.

Next, the description will be made of the flux collecting means 38 for collecting the magnetic flux F attracted to the magnetic disk 36. FIG.

The flock collecting means 38 is mainly composed of a groove-type scraper 60 and a conveying means 62.

The grooved normal scraper 60 is provided between the magnetic disk 36 immediately before the rotating magnetic disk 36 enters the raw water in the atmosphere (see FIG. 5) To the top of the groove. The edge portions 60A at the upper ends of both side surfaces of the groove normal scraper 60 are brought into contact with the surface of the magnetic disk 36 with a predetermined urging force, F).

The transporting means 62 is disposed in the groove normal scraper 60 and scraped to transport the magnetic flux F dropped and accumulated in the groove normal scraper 60 to the upper side of the flux recovery tank 42, ). As the conveying means 62, a screw conveyor 64 and a belt conveyor 66 with a fin can be preferably used. Figs. 9 to 11 are for the case of the screw conveyor 64, In the case of a belt conveyor 66 with a fin. In FIGS. 9, 10 and 12, magnetic flux F is shown only in the atmosphere portion of the magnetic disk 36. FIG.

As shown in Fig. 9, in the groove normal scraper 60, the top edge portion 60A of the side surface abuts against the surface of the magnetic disk 36 with a predetermined pressing force, and the top edge portion 60A Is formed in a thin and thin shape. The magnetic flux F adsorbed on the surface of the magnetic disk 36 rotating in the clockwise direction is scraped by the upper edge portion 60A of the groove normal scraper 60 and falls into the groove normal scraper 60. [

As shown in Figs. 9 to 11, a screw portion 64A of a screw conveyor 64 is housed in the groove normal scraper 60, and one end of the screw portion 64A is connected to the motor 64B. In this case, as shown in Fig. 11, the inner surface shape from the side surface to the bottom surface of the groove normal scraper 60 is preferably semi-circular so as not to form a dead space for transportation. The magnetic flux F dropped and accumulated in the groove normal scraper 60 is conveyed to the upper side of the fl ow collecting tank 42 by the screw conveyor 64 and falls on the fl ow collecting tank 42.

When a belt conveyor 66 with a fin is employed as the conveying means 62, the conveyor is constructed as shown in Figs. 12 and 13. Fig. That is, the belt conveyor 66 with a fin is provided with a pair of pulleys 68 on both sides in the radial direction of the magnetic disk 36, and a pair of pulleys 69 An endless belt 70 can be wound around and wound. One of the pair of pulleys 68 is connected to a driving means such as a motor (not shown). The endless belt 70 does not contact the surface of the magnetic disk 36. The fins 69 (fins) are formed on the outer surface of the endless belt 70 at a predetermined interval, and are formed perpendicular to the endless belt 70. In this case, as shown in Fig. 13, it is preferable that the inner surface shape from the side surface to the bottom surface of the grooved creper 60 is matched to the shape of the fin 69 (fin) so that a dead space of the conveyance is not formed. For example, when the shape of the pin 69 (fin) is an inverted trapezoid, the inner surface shape of the groove normal scraper 60 is also an inverted trapezoid.

9 to 13, the supporting structure of the groove normal scraper 60 and the supporting structure of the pulley 68 of the pin-belt conveyor 66 are not specifically shown. However, for example, . The inclination of the groove normal scraper 60 is shown in Fig. 10 (screw conveyor) to be tilted to the right, while in Fig. 12 (the belt conveyor with a pin) the right side is inclined downward. However, . This is because while the magnetic flux F dropped in the groove normal scraper 60 is conveyed to the conveying means 62 while the moisture in the magnetic flux flows on the groove normal scraper 60, It is possible to prevent water from flowing into the fl ow collecting tank 42. It is important to reduce the volume of the magnetic flux F recovered in the flux recovery tank 42 by making it as low as possible. Therefore, it is preferable to provide adjusting means (not shown) for adjusting the inclination of the entire collecting means 38 so as to adjust the inclination of the upper inclination of the groove normal scraper 60. For example, in the case of the screw conveyor type recovery means 38, the longitudinal center portion of the groove normal scraper 60 is supported by a rotation shaft, and the groove normal scraper 60 is rotated by a stretching device such as a cylinder device It may be configured to be swingable.

Next, the operation of the magnetic separator 20 configured as described above will be described.

The raw water containing the magnetic flux F flows from the water supply port 44 formed at the lower end of the separation tank 32 and is divided by the separating member 46. By this separating member 46, the raw water is divided into left and right sides with respect to the surface of the continuously rotating magnetic disk 36, and is classified so as to flow into the ferromagnetic space between the magnetic disks 36. The magnetic flux F in the raw water is adsorbed on the surface of the magnetic disk 36 while the sorted raw water rises in the separating tank 32. The treated water to which the magnetic flux F is adsorbed and purified is overflowed to a pair of troughs 40 installed on the left and right sides of the magnetic flux F. [

On the other hand, the magnetic flux F attracted to the magnetic disk 36 is transported to the atmosphere on the water surface by the continuous rotation of the magnetic disk 36, and is exposed to the atmosphere. The magnetic flux F is exposed to the atmosphere so that the moisture of the magnetic flux F flows through the surface of the magnetic disk 36 into the separating tank 32 by gravity. Furthermore, the magnetic flux F attracted to the magnetic disk 36 is compacted by the magnetic force of the magnetic disk 36. As a result, the dehydration of the magnetic flux F is promoted, resulting in a sludge state having a water content of about 90%.

The magnetic flux F with dehydration promoted is conveyed to the position of the groove normal scraper 60 by the continuous rotation of the magnetic disk 36 and scratched to the side edge portion 60A of the groove normal scraper 60, (60). The magnetic flux F dropped in the groove normal scraper 60 is conveyed by the conveying means 62 of the screw conveyor 64 or the pin attached belt conveyor 66 and conveyed to the upper side of the fl ow collecting tank 42, And drops to the recovery tank 42.

Since the separating member 46 is provided just below the plurality of magnetic disks 36 in the magnetic separation of the magnetic flux F by the installed magnetic separator 20, (36).

The sealing plate 48 is provided between the magnetic disk and the separating tank to shorten the outer circumferential surface of the magnetic disk 36 on which the magnetic force is not exerted by the shortest route to the trough 40 ). So that there is no deterioration in the water quality of the treated water that flows through the trough 40 (trough).

As for the inner magnetic disk 36B among the plurality of magnetic disks 36 disposed on the rotary shaft 34, the permanent magnet pieces 37 are disposed on both sides of the disk substrate 33 as conventionally, while the outermost magnetic disk 36A, permanent magnet pieces 37 for exerting a magnetic force are disposed only on the inner surface of the disk substrate 33 (the side surface of the inner magnetic disk). The stiffness of the disk substrate 33 for laying out the permanent magnet pieces of the outermost magnetic disk 36A is made larger than the stiffness of the disk substrate of the inner magnetic disk. In this case, if the magnetic disk 36 having a honeycomb structure is employed, it is possible to achieve weight reduction while securing required rigidity.

Furthermore, the shielding member 54 is embedded between the outer surface of the outermost magnetic disk 36A and the inner surface of the separating tank 32. Magnetic leakage or deformation from the outermost magnetic disk 36A can be prevented and the outer surface of the outermost magnetic disk 36A can be prevented from flowing through the trough 40 Therefore, the quality of treated water does not deteriorate.

Further, by providing the groove normal scraper 60 as the recovery means 38, the magnetic flux F adsorbed to the magnetic disk 36 can be reliably recovered.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing the flow of a polluted water purification system incorporating the magnetic separation device of the present invention;

2 is a conceptual diagram of an apparatus constituting the polluted water purification system,

3 is a perspective view showing a section of a part of the magnetic separation apparatus of the present invention,

4 is a side cross-sectional view of the magnetic separator of the present invention,

5 is a front sectional view of the magnetic separation device of the present invention,

6 is an explanatory view for explaining the action of the sorting member installed in the magnetic separating apparatus of the present invention,

7 is a perspective view illustrating a sealing plate installed in the magnetic separation device of the present invention,

8 is an explanatory diagram for explaining a difference between an outermost magnetic disk according to the related art and the present invention,

9 is an explanatory view for explaining the relationship between the magnetic disk and the groove normal scraper of the magnetic separator of the present invention,

Fig. 10 is an explanatory view for explaining a screw conveyer-type collecting means;

11 is an explanatory view for explaining the relationship between a screw conveyer and a groove-type scraper,

12 is an explanatory view for explaining a recovery means of a belt-conveyor type with a pin,

Fig. 13 is an explanatory view for explaining the relationship between the fin-type belt conveyor type pin and the groove normal scraper.

Description of the Related Art

10: sewage water purification system 12: raw water pump

14: Coagulation apparatus 14A: Rapid stirring tank

14B: Slowly stirring tank 16: Self-component addition device

18: coagulant addition device 19: stirring blade

20: magnetic separation device 24: filter separation device

25: dehydrator 26: rotary drum filter

28: showering device 29: circulation pump

30: Pump 31: Sleeve

32: separator 33: disk substrate

34: rotating shaft 35: bearing

36: magnetic disk 37: permanent magnet piece

38: recovery means 39: motor

40: trough 41: side wall

42: Flux recovery tank 43: Square normal piping

44: Water supply port 45: Case

46: separating member 48: sealing plate

50: Pivot shaft 52: Reinforcing member

55: lid member 60: groove normal scraper

62: conveying means 64: screw conveyor

66: Belt conveyor with pin 68: Pulley

69: pin 70: endless belt

F: magnetic flux

Claims (5)

A separating tank into which raw water containing magnetic flocs flows and a rotating shaft disposed in the separating tank at a predetermined interval are provided, A plurality of magnetic disks for attracting the magnetic flux by a magnetic force, and a recovery means for recovering the attracted magnetic flux, the magnetic separation device comprising: Wherein said plurality of magnetic disks are half-molten in said raw water of said separating tank and supply said raw water from said feed port formed at the lower end of said separating tank as an upward flow into said separating tank; Wherein a splitting member (splitting member) for splitting the raw water supplied from the water supply port in the lateral direction of the magnetic disk surface and in the thickness direction of the magnetic disk is provided immediately below each of the plurality of magnetic disks Excreted; Wherein a pair of troughs are provided on both sides of the separating tank parallel to the rotation axis, wherein the magnetic flux is removed from the raw water by the magnetic disk to overflow the process water; Wherein the sorting member divides the raw water and guides the sorted raw water to flow into a gap between adjacent magnetic disks. 2. The magnetic separation apparatus according to claim 1, wherein the separating member is formed in a wedge shape in which the thickness of the top surface is formed to be equal to the thickness of the magnetic disk, and the thickness is thinned toward the bottom. The magnetic separation apparatus according to claim 1 or 2, wherein the water supply port is formed in a rectangular tube shape that is long in the direction of the rotation axis. 2. The magnetic disk apparatus according to claim 1, wherein a base end portion is fixed to the inner surface of the separation vessel between the outer circumferential surface of each of the plurality of magnetic disks and the inner surface of the separation vessel, and a sealing plate having a distal end portion as a free end contacting with the outer circumferential surface of the magnetic disk And the magnetic separator. 2. The magnetic disk apparatus according to claim 1, wherein the recovering means is disposed between the magnetic disks immediately before the rotating magnetic disk enters the raw water in the atmosphere, and is grooved normally from the vicinity of the rotation axis to the outside of the separating tank, A groove normal scraper for scraping off a magnetic flux attracted to a surface of a magnetic disk by abutting the surface of the magnetic disk with a predetermined urging force, a magnetic flux scraping device scraped off into the groove normal scraper, And a conveying means for conveying the object to the outside of the separating tank.

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