JP2018089560A - Magnet separator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve a recovery rate of a magnet separator comprising a main drum which discharges magnetic sludge out of treated liquid and a sub-drum which is arranged at an upstream side of the main drum and magnetizes the magnetic sludge in the treated liquid.SOLUTION: A magnet separator comprises a main drum which discharges magnetic sludge out of treated liquid and a sub-drum which is arranged at an upstream side of the main drum and magnetizes the magnetic sludge in the treated liquid. The sub-drum is submerged in the treated liquid and has an upper flow passage through which the treated liquid flows formed at an upper section thereof and a lower flow passage through which the treated liquid flows formed at a lower section thereof.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a magnet separator for recovering magnetic sludge such as metal components contained in a liquid to be treated. More specifically, the present invention relates to a magnet separator provided with a main drum for recovering magnetic sludge from the liquid to be treated and a sub-drum disposed upstream thereof for magnetizing the magnetic sludge.

  As a metal processing machine, there is a processing machine using a magnetic metal as a material to be cut, and cutting oil containing cutting waste is discharged from such a metal processing machine. A magnet separator is known as a cutting waste processing apparatus for separating cutting waste from such cutting oil. The magnet separator includes a rotating drum having magnets arranged on the outer periphery, and the cutting waste is separated from the cutting oil by adsorbing the cutting waste by the rotating drum. Among them, a technique for improving the recovery rate by giving the sub-drum a function of magnetizing a magnetic material has attracted attention.

  For example, Patent Document 1 discloses a rotary drum type magnetic separation device including a first rotary drum (main drum) in which a plurality of magnets are arranged, and a second rotary drum (sub drum) upstream thereof. Yes. According to this apparatus, by giving the second rotating drum a function of magnetizing the magnetic material, the magnetic materials adsorbed on the second rotating drum are magnetized and attracted to each other to form large particles. Large particles are easily guided to the first rotating drum, and can be reliably collected by the first rotating drum.

Japanese Patent Laid-Open No. 2006-68057

  An object of the present invention is to provide a main drum that discharges magnetic sludge to the outside of the liquid to be processed, a sub drum that is disposed upstream of the main drum and magnetizes the magnetic sludge in the liquid to be processed to form a magnetized aggregate. In the magnet separator provided with the magnetic sludge, the recovery rate of the magnetic sludge is further improved.

As a result of intensive studies on the above problems, the present inventor has found that the recovery rate of magnetic sludge is improved by providing a flow path for circulating the liquid to be processed in the upper part and the lower part of the sub drum submerged in the liquid to be processed. As a result, the present invention has been completed.
That is, this invention is the following magnet separators.

  In order to solve the above problems, a magnet separator according to the present invention is a magnet separator that removes magnetic sludge from a liquid to be treated, a main drum that discharges the magnetic sludge to the outside of the liquid to be treated, and an upstream side of the main drum. And a sub drum that forms a magnetic aggregate by magnetizing magnetic sludge in the liquid to be processed, and the sub drum is disposed in a state of being submerged in the liquid to be processed. And a lower flow path for flowing the liquid to be processed is formed below the sub drum.

According to this magnet separator, the liquid to be treated flows through both the upper part and the lower part of the sub drum, so that the magnetic sludge can be magnetized using the entire circumference of the sub drum. Therefore, the amount of the magnetic aggregate formed by the sub drum increases. Since the magnetized aggregate is larger than the magnetic sludge before aggregation, the magnetized aggregate easily receives the magnetic force of the main drum, and the magnetic adhesion to the main drum is promoted. Based on such an action, the magnet separator of the present invention has an effect of improving the recovery rate of magnetic sludge. Furthermore, since the magnetic sludge magnetically attached to the sub drum in the lower flow path is magnetized for a long time, the effect of the sub drum to form a magnetized aggregate is further exhibited.
In addition, the liquid to be treated that circulates in the upper part of the sub drum has an effect of transferring the magnetic sludge magnetically attached to the sub drum to the main drum at the subsequent stage.

As one embodiment of the magnet separator of the present invention, the liquid to be treated that has flowed through the upper flow path forms a flow that passes between the sub drum and the main drum and then flows through the lower portion of the main drum. The liquid to be processed that has circulated is guided toward the region between the sub drum and the main drum, and is merged with the flow of the liquid to be processed from the upper flow path.
According to this feature, the flow of the liquid to be processed including the magnetic sludge that flows through the upper flow path and the liquid to be processed that flows through the lower flow path merge between the sub drum and the main drum. In the region between them, a stirring action occurs. Therefore, since the magnetic sludge in the liquid to be treated flows in a region between the sub drum and the main drum, there is an effect that the chance of approaching the main drum increases and it is easy to be magnetized to the main drum.

One embodiment of the magnet separator of the present invention is characterized in that the flow rate of the liquid to be processed in the lower flow path is larger than the flow rate of the liquid to be processed in the upper flow path.
If the flow rate of the liquid to be treated in the lower flow path is made larger than the flow rate of the liquid to be treated in the upper flow path, the amount of magnetic sludge flowing through the lower flow path side increases, so that a lot of magnetic sludge is magnetically applied to the sub drum in the lower flow path. To wear. Therefore, the magnetized time is increased, and the effect of facilitating the formation of a magnetized aggregate is achieved.
Also, in the agitating action between the sub-drum and the main drum described above, the agitating action in the upward direction is strengthened, so that the chance that the magnetic sludge is close to the main drum is further increased, and magnetic adhesion is facilitated.

As one embodiment of the magnetic separator of the present invention, one end abuts against the sub drum and the other end is disposed on the main drum side and fixed, and the other end of the scraper is disposed on the lower flow path. It has the feature of having an opening for feeding the liquid to be treated to the main drum.
According to this feature, since the scraper for the sub drum extends from the sub drum to the main drum side, the magnetic sludge scraped off at one end of the scraper flows along the scraper to the main drum side. . When the magnetic sludge reaches the other end side of the scraper, it is caused to flow toward the main drum by the liquid to be treated from the opening disposed on the other end side of the scraper. Therefore, the chance that the magnetic sludge is close to the main drum is increased, and the effect of facilitating magnetic attachment to the main drum is achieved.

As one embodiment of the magnet separator of the present invention, the opening has a feature that the liquid to be treated in the lower flow path is fed in the rotation direction of the main drum.
According to this feature, since the magnetic sludge flows along the rotation direction of the main drum, the magnetic adhesion of the magnetic sludge to the main drum can be further promoted.

As one embodiment of the magnet separator of the present invention, the sub drum includes an outer cylinder fixed to the magnet separator main body, and an inner cylinder in which a plurality of magnets are arranged at intervals on the outer circumferential surface. It has a feature that it rotates in the direction opposite to the flow direction of the liquid to be treated flowing through the lower flow path.
According to this feature, since a plurality of magnets are arranged on the outer peripheral surface of the inner cylinder at intervals in the circumferential direction, regions having a strong magnetic force and regions having a low magnetic force are alternately arranged on the outer peripheral surface of the outer tube. It is formed. Therefore, the magnetic sludge is magnetically attached on the outer peripheral surface of the outer cylinder with an interval in the circumferential direction. The magnetic sludge magnetically attached to the outer peripheral surface of the outer cylinder moves in the circumferential direction of the outer cylinder by rotating the inner cylinder in the direction opposite to the flow direction of the liquid to be processed flowing through the lower flow path, and is used for the sub drum. It is scraped off with a scraper. The magnetic sludge that has reached the scraper stays at the end of the scraper by the magnetic force until a region having a strong magnetic force passes through the end of the scraper, and forms a large magnetic aggregate. And when the area | region where a magnetic force is weak passes through the edge part of a scraper, magnetic sludge peels off from a scraper as a big magnetic aggregate, and moves to a main drum direction. Due to such an action, the magnetic aggregate of the magnetic sludge can be made larger, so that the magnetic attachment to the main drum can be performed more reliably.

  According to the present invention, there is provided a magnet separator including a main drum that discharges magnetic sludge to the outside of the liquid to be processed, and a sub drum that is disposed upstream of the main drum and magnetizes the magnetic sludge in the liquid to be processed. Thus, it is possible to provide a magnetic separator having excellent magnetic sludge recovery performance.

It is a schematic explanatory drawing which shows the structure of the magnet separator of the 1st embodiment of this invention. It is a schematic explanatory drawing which shows the detailed structure of the 2nd scraper and opening part of the magnet separator of a 1st embodiment of this invention. It is a schematic explanatory drawing explaining the liquid feeding direction of the opening part of the magnet separator of the 1st embodiment of this invention. (A) In the magnet separator of the 1st embodiment of this invention, it is a schematic explanatory drawing explaining the stirring action between a sub drum and a main drum. (B) It is an enlarged view of the area | region of E in FIG. 4 (A). It is a schematic explanatory drawing which shows the structure of the cross section (XX cross section of FIG. 1) of the sub drum of the magnet separator of the 1st embodiment of this invention, an upper flow path, and a lower flow path. It is a graph showing the recovery rate at the time of processing a coolant liquid using a magnet separator. (A) in a graph is a graph which shows the recovery rate in the conventional magnet separator which is not equipped with a sub drum, and (B) in a graph is a graph which shows the recovery rate in the magnet separator of the 1st embodiment of the present invention. It is. It is a schematic explanatory drawing which shows the structure of the magnet separator of the 2nd embodiment of this invention.

  The magnetic separator of the present invention collects magnetic sludge contained in the liquid to be treated by magnetic force. The liquid to be treated of the present invention is not particularly limited as long as it is a liquid containing magnetic sludge, and may be an oily liquid or a water-soluble liquid. Examples of a general liquid to be treated include a coolant liquid in a metal polishing machine using a magnetic metal as a work material, a plating liquid in an apparatus for plating a steel plate, and the like. The magnet separator of the present invention can clean the liquid to be processed by collecting magnetic sludge from these liquids to be processed. In addition, the magnetic separator of the present invention can also be used, for example, for recovering rare metals from industrial waste, removing foreign substances from beverages, edible oils, and the like.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
[First embodiment]
[Magnet separator]
FIG. 1 shows the structure of a magnet separator 100 according to the first embodiment of the present invention. A magnetic separator 100 of the present invention includes a main body 1 formed of a substantially rectangular casing, an input portion 4 for supplying a liquid to be processed containing magnetic sludge into the main body 1, and a processing liquid from which magnetic sludge has been removed. A treatment liquid discharger 6a and a magnetic sludge discharger 6b for discharging magnetic sludge are provided. Further, a liquid reservoir 5 for storing the liquid to be processed is provided inside the main body 1, and the inside of the main body 1 is configured to be able to store the liquid to be processed up to a predetermined water level.

  The input part 4 is provided on one end side (right side in FIG. 1) of the main body 1, and the treatment liquid discharge part 6a and the magnetic sludge discharge part 6b are provided on the other end side (left side in FIG. 1) of the main body 1. . And the to-be-processed liquid thrown in from the injection | throwing-in part 4 passes the liquid storage part 5, and is comprised so that it may flow toward the process liquid discharge part 6a.

  Inside the main body 1, a magnetic drum is magnetically deposited and discharged to the outside of the liquid to be treated, and the main drum 2 is disposed upstream of the main drum 2. The magnetic sludge in the liquid to be treated is magnetized and magnetized. A sub drum 3 for forming an aggregate is provided. The sub drum 3 is disposed in a state of being submerged in the liquid to be processed, and an upper flow path 13 and a lower flow path 14 through which the liquid to be processed flows are formed in an upper portion and a lower portion thereof.

  Inside the main body 1, a rectifying wall 8 is installed so as to be separated from the inlet of the charging portion 4. The rectifying wall 8 positively guides the flow of the inputted liquid to be processed toward the lower flow path 14 and promotes magnetic adhesion of the magnetic sludge in the lower flow path 14. In addition, since the flow of the liquid to be processed having a high flow velocity flowing in from the input unit 4 is restricted by installing the rectifying wall 8, the amount of magnetic sludge that passes through the upper flow path 13 without being magnetized by the sub drum 3 is reduced. Can be reduced.

<Main drum>
The main drum 2 is a rotating drum that is supported substantially horizontally in a direction orthogonal to the flow of the liquid to be processed. The main drum 2 is installed so that the lower half of the main drum 2 is immersed below the liquid surface of the liquid to be treated, and the upper half of the upper side of the main drum 2 is exposed from the liquid surface.

  The main drum 2 includes an outer cylinder 2a that is rotatably supported and an inner cylinder 2b in which a plurality of magnets are arranged on the outer peripheral surface. The inner cylinder 2b having a plurality of magnets is fixed inside the outer cylinder. ing. The rotation direction of the outer cylinder 2a is opposite to the flow of the liquid to be processed passing through the lower part (counterclockwise when viewed from the paper surface of FIG. 1).

  The polarities of the plurality of magnets arranged in the inner cylinder 2b are arranged such that a predetermined magnetic flux is generated on the outer peripheral surface of the outer cylinder so that magnetic sludge can be magnetized. In the magnet separator 100 of the first embodiment, as shown in FIG. 1, N-pole and S-pole magnets are alternately arranged. In addition, the plurality of magnets are disposed in approximately two-thirds of the outer peripheral surface of the inner cylinder 2b, and are not disposed in the remaining substantially one-third so that no magnetic force acts. It is configured.

  The main drum 2 can discharge the magnetic sludge magnetically attached to the outer peripheral surface of the outer cylinder 2a to the outside of the liquid to be treated by rotating the outer cylinder 2a. The configuration of the main drum is not particularly limited as long as the magnetic sludge in the liquid to be processed is magnetized by a magnetic force and the magnetic sludge magnetized can be transferred to the outside of the liquid to be processed. It is good also as a structure which arrange | positions a magnet to an inner peripheral surface and rotates the outer cylinder provided with the magnet, and is good also as a structure which fixes an outer cylinder and rotates the inner cylinder provided with the magnet.

Near the top of the main drum 2, a roller 7 is installed behind the top in the rotational direction, and a first scraper 11 is installed ahead of the top in the rotational direction.
The roller 7 is provided with an elastic body such as rubber on the surface, and is in contact with the outer peripheral surface of the outer cylinder 2a of the main drum 2 with a predetermined pressure. Since the magnetic sludge magnetized between the outer cylinder 2a and the roller 7 passes, the liquid content of the magnetic sludge is squeezed out, so that the magnetic sludge having a small liquid content can be separated and recovered.

  As the elastic body arranged on the surface of the roller 7, elastic bodies such as CR (chloroprene) rubber and NBR (nitrile) rubber are mainly used. For example, an uncrosslinked polyurethane material mainly composed of polyester polyol is used. It may be used.

  The first scraper 11 is in contact with the outer peripheral surface of the outer cylinder 2a of the main drum 2, and is configured to scrape the magnetic sludge whose liquid content has been squeezed out by the roller 7 from the outer peripheral surface of the outer cylinder 2a. . In addition, the 1st scraper 11 is provided in the area | region where the magnet of the inner cylinder 2b is not arrange | positioned.

  At the lower part of the main drum 2, a first bottom wall 9 is installed apart from the outer periphery of the main drum 2. The shape of the first bottom wall 9 is a shape along the outer periphery of the main drum, and a flow path through which the liquid to be processed flows is formed between the main drum 2 and the first bottom wall 9. By providing the first bottom wall 9, the liquid to be treated passes in the vicinity of the outer periphery of the main drum 2, so that the magnetic adhesion of the magnetic sludge can be promoted.

  The magnetic sludge magnetized on the outer periphery of the main drum 2 is transferred onto the liquid surface while being magnetized around the outer cylinder 2 a as the outer cylinder 2 a rotates, and the liquid content is squeezed out by the roller 7. Further, when the magnetic sludge is transferred to a region where no magnet is disposed, the magnetic sludge is released from the magnetic force and scraped off by the first scraper 11. The magnetic sludge scraped off is discharged to the outside of the main body 1 from the magnetic sludge discharge portion 6b.

<Sub drum>
The sub drum 3 is a rotating drum having a smaller diameter than the main drum 2 and is arranged on the upstream side of the main drum 2 (the front side in the flow direction of the liquid to be processed). The sub drum 3 is disposed so as to be submerged in the liquid to be processed, and an upper channel 13 through which the liquid to be processed is circulated in the upper part of the sub drum 3 and a lower channel 14 through which the liquid to be processed is circulated at the lower part. Is formed.

  The structure of the sub drum 3 includes an outer cylinder 3a fixed so as to penetrate the main body 1, and an inner cylinder 3b having a plurality of magnets arranged on the outer peripheral surface. The inner cylinder 3b having a plurality of magnets is an outer cylinder 3a. It is fixed so that it can rotate. The rotation direction is the direction opposite to the flow direction of the liquid to be processed flowing through the lower flow path 14 (counterclockwise as viewed from the paper surface of FIG. 1). Further, the outer cylinder 3a is fixed in a liquid-tight state with respect to the wall of the main body 1 so that the liquid to be processed does not flow into the inner cylinder 3b that is rotationally driven. According to this configuration, since the liquid does not touch the rotation mechanism of the inner cylinder 3b, troubles such as failure of the rotation mechanism can be reduced. Further, it is possible to prevent the liquid to be processed from leaking out of the main body 1 from between the outer cylinder 3 a and the wall of the main body 1. The configuration of the sub-drum 3 is an example, and is not particularly limited as long as it is a configuration that can magnetically deposit magnetic sludge in the liquid to be processed by magnetic force and transfer the periphery of the outer cylinder 3b as with the main drum 2.

As for the arrangement of the magnets of the sub drum 3, as shown in FIG. 1, an even number (eight sets) of magnet groups in which the S pole and the N pole are adjacent to each other are arranged. Adjacent magnet groups are arranged so that the same poles face each other with a gap. With this arrangement, a region having a weak magnetic adhesion force is formed between adjacent magnet groups.
Moreover, it arrange | positions so that the same pole may mutually oppose with the magnet arrange | positioned on the opposite side of the sub drum 3. FIG.

  In the lower part of the sub drum 3, similarly to the main drum 2, a second bottom wall 10 having a shape along the outer periphery of the sub drum 2 is disposed apart from the outer periphery of the sub drum 3. Thereby, the effect of promoting the magnetic attachment of the magnetic sludge to the sub drum 3 is produced.

  A second scraper 12 for scraping off magnetic sludge magnetically attached to the sub drum 3 is provided near the top of the sub drum 3. One end of the second scraper 12 is in contact with the sub drum 3, and the other end extends to the main drum 2 side and is fixed to the first bottom wall 9 by welding. Further, on the other end side of the second scraper 12, an opening 15 for feeding the liquid to be processed in the lower flow path 14 in the rotation direction of the main drum 2 is formed. The detailed structure of the second scraper 12 and the opening 15 is shown in FIG.

  In the first embodiment, the opening 15 is configured by an opening opened on the end side of the second scraper 12, but the liquid to be treated in the lower flow path 14 is fed toward the main drum 2. Any configuration is possible as long as possible. For example, without fixing the other end of the second scraper to the first bottom wall 9, the gap between the other end of the second scraper and the first bottom wall 9 is used as an opening or has an opening. You may comprise with a mesh or provide the nozzle which the area of an opening reduces gradually.

Here, the liquid feeding direction of the opening 15 will be described with reference to FIG. 3. The liquid feeding direction of the opening 15 is the center of the surface (broken line L _{1 in} FIG. 3) constituting the opening 15 ( It is the direction of a perpendicular line (arrow L _{2 in} FIG. 3) passing through P) in FIG.
The opening for feeding the liquid to be treated from the lower flow path 14 to the main drum 2 is a tangent to the main drum 2 in which the liquid feeding direction (L ₂ ) of the opening passes through the center P of the opening. It means a configuration that is directed in the range of (a one-dot chain line in FIG. 3).
Further, the opening through which the liquid to be treated from the lower flow path 14 is fed in the rotation direction of the main drum 2 means that the feeding direction (L ₂ ) of the opening is the center of the main drum 2 (in FIG. 3). Q) and a line passing through the center P of the opening (broken line L _{3 in} FIG. ₃ ) means a configuration that is directed forward in the rotation direction of the main drum 2.

  Next, the operation of the upper flow path 13 and the lower flow path 14 will be described in detail while explaining the flow of the liquid to be processed. The flow of the liquid to be processed is indicated by arrows in FIG. 1 and FIG.

  The liquid to be treated containing the magnetic sludge charged from the charging unit 4 is changed to a downward flow by the rectifying wall 8 and is stored in the liquid reservoir 5. Since the liquid to be treated stored in the liquid reservoir 5 flows separately in the upper flow path 13 and the lower flow path 14, the magnetic sludge can be magnetized using the entire periphery of the sub drum 3. Since the magnetic sludge magnetically attached to the sub drum 3 is magnetized and attracts each other, fine particles gather to form a magnetized aggregate. When the magnetic sludge becomes a large magnetic aggregate, it is easy to receive a magnetic force, and the effect of promoting magnetic attachment to the main drum 2 is achieved, thereby improving the recovery rate of the magnetic sludge. Further, since the magnetic sludge magnetized on the sub drum 3 in the lower flow path 14 is magnetized for a long time, the magnetic sludge magnetized on the main drum 2 is further promoted in order to form a larger magnetized aggregate. Can do.

  The magnetic sludge magnetically attached to the sub drum 3 moves in the circumferential direction of the sub drum as the magnet rotates in the circumferential direction of the sub drum, and is scraped off at the end of the second scraper 12. At that time, the magnetic sludge that has moved to the end of the scraper 12 stays at the end of the scraper 12 by the magnetic force until the region where the magnet is disposed passes through the end of the scraper 12, and forms a large magnetic aggregate. And when the area | region where the magnet is not arrange | positioned passes the edge part of the scraper 12, the big magnetization aggregate which consists of magnetic sludge is peeled off from the scraper 12, and moves to the direction of the main drum 2. FIG. Due to such an action, the magnetic aggregate of the magnetic sludge can be made larger, so that the magnetic adhesion to the main drum 2 can be performed more reliably.

  The liquid to be processed that has passed through the upper flow path 13 then passes between the sub-drum 3 and the main drum 2, and then flows through the lower portion of the main drum 2. The magnetized aggregate of magnetic sludge scraped off by the second scraper 12 is transferred to the main drum 2 side along this flow and is magnetically attached to the main drum 2. Then, the processing liquid from which the magnetic sludge has been removed by the main drum 2 is discharged out of the main body 1 toward the processing liquid discharge portion 6a.

  On the other hand, the liquid to be processed that has passed through the lower flow path 14 is also guided toward the region between the sub drum 3 and the main drum 2 and merges with the flow from the upper flow path 13. As a result, a stirring action occurs in the region between the sub drum 3 and the main drum 2. Note that the liquid to be treated from the lower flow path 14 contains almost no magnetic sludge.

  FIG. 4 is a schematic explanatory diagram for explaining the stirring action. As shown in FIG. 4, the liquid to be processed that has passed through the upper flow path 13 passes between the sub drum 3 and the main drum 2, and then flows between the main drum 2 and the first bottom wall 9 (see FIG. 4). Solid line arrow in 4). In addition, the liquid to be processed that has passed through the lower flow path 14 is guided to the region (R) between the sub drum 3 and the main drum 2 by the second bottom wall 10 and merges with the flow from the upper flow path 13. (Dotted arrows in FIG. 4). The region (R) between the sub drum 3 and the main drum 2 is a line connecting the tangents on the upper side of the sub drum 3 and the main drum 2 and a line connecting the tangents on the lower side (in FIG. 4). It is a region between the alternate long and short dash lines).

  As shown in FIG. 4B, when the liquid to be processed from the lower flow path 14 joins the flow from the upper flow path 13, the magnetic sludge contained in the flow from the upper flow path 13 flows upward. Receive. Therefore, the chance that the magnetic sludge approaches the main drum 2 is increased, and the effect of facilitating magnetic adhesion to the main drum 2 is achieved.

  In the magnetic separator 100 of the first embodiment, the liquid to be processed from the lower flow path 14 merges with the flow from the upper flow path 13 through the opening 15. The liquid feeding direction of the opening 15 feeds the liquid to be treated in the lower flow path 14 in the rotation direction of the main drum 2, so that the magnetic sludge can flow toward the main drum 2.

  In order to obtain a stirring action by the merging, the opening 15 does not have to be provided, and the liquid to be processed from the lower flow path 14 can be guided to the region (R) between the sub drum 3 and the main drum 2. A structure provided with a simple guide member may be used.

  The flow rate of the liquid to be processed flowing through the upper flow path 13 and the lower flow path 14 is appropriately set so that the magnetic sludge can be magnetically attached to the sub drum 3 in consideration of the magnetic adhesion force of the sub drum 3 and the like. From the viewpoint of increasing the magnetizing time of the magnetic sludge, it is preferable that the flow rate of the liquid to be processed in the lower flow path 14 is larger than the flow rate of the liquid to be processed in the upper flow path 13. Further, by increasing the flow rate of the liquid to be processed in the lower flow path 14, the magnetic sludge strongly flows when the liquid to be processed from the lower flow path 14 merges with the flow from the upper flow path 13, and the main drum There is also an effect that the opportunity to approach 3 is further increased.

  Here, the flow rate of the liquid to be processed flowing through the lower flow path 14 is determined by the cross-sectional area of the lower flow path 14 and the minimum cross-sectional area of the opening area of the opening 15. Further, the flow rate of the liquid to be processed flowing through the upper flow path 13 can be adjusted by the flow rate of the liquid to be processed input from the input unit 4.

FIG. 5 shows a vertical cross-sectional view (dashed line XX in FIG. 1) at the center of the sub drum 3. Since the minimum cross-sectional area of the upper flow path 13 is the cross-sectional area (R1) of the flow path directly above the sub drum 3, the minimum cross-sectional area (R1) of the upper flow path 13 varies depending on the height of the liquid surface. For example, if the minimum cross-sectional area of the lower flow path 14 is the cross-sectional area (R2) of the flow path directly below the sub-drum 3, the liquid level is high so that R2> R1 By adjusting the amount, the flow rate of the liquid to be processed in the lower flow path 14 can be made larger than the flow volume of the liquid to be processed in the upper flow path 13.
In the flow rate adjustment described above, the flow rate is adjusted according to the operating conditions. However, a flow rate adjusting unit such as a wall may be provided on the upper portion of the sub drum 3 to set the minimum cross-sectional area of the upper flow path 13 constant.

In FIG. 6, the graph showing the collection rate at the time of processing a coolant liquid using the magnetic separator 100 of 1st embodiment was shown. (A) in a graph is a graph which shows the collection | recovery rate in the conventional magnet separator which is not equipped with a sub drum, and (B) in a graph shows the collection | recovery rate in the magnetic separator 100 of the 1st embodiment of this invention. It is a graph.
From the graph, it can be seen that the recovery rate of the magnetic separator of the present invention is improved by about 1.5 times compared to the conventional magnetic separator not provided with the sub drum.

[Second Embodiment]
In FIG. 7, the structure of the magnet separator 101 of the 2nd embodiment of this invention is shown. In the magnet separator 101 of the second embodiment of the present invention, one end of the second scraper 12 is fixed to the outer peripheral surface of the sub drum 3 and the other end is not fixed. For this reason, a gap is formed between the other end of the second scraper 12 and the first bottom wall 9, and this gap acts as an opening 16 through which the liquid to be treated flows in the lower flow path 14. Further, the opening 16 is configured to send the liquid to be processed in the lower flow path 14 to the main drum 2.

  The other end of the second scraper 12 is curved toward the main drum 2. According to this shape, the magnetic sludge conveyed by the flow of the liquid to be treated in the upper flow path 13 flows in the direction of the main drum 2 along the curved shape at the other end of the second scraper 12, so that the magnetic sludge There is an effect of promoting the magnetic adhesion of sludge to the main drum 2.

  Further, the magnet separator 101 of the second embodiment includes a flow rate adjusting unit 17 that is suspended from the top surface and fixed inside the main body 1. The flow rate adjusting unit 17 is a member for adjusting the flow rate of the liquid to be processed in the upper flow path 13, and sets the flow rate of the liquid to be processed in the upper flow path 13 to be smaller than the flow rate of the liquid to be processed in the lower flow path 14. can do. Further, according to this member, even when the input amount of the liquid to be processed from the input unit 4 is increased, the flow rate of the liquid to be processed in the upper channel 13 is smaller than the flow rate of the liquid to be processed in the lower channel 14. Can be maintained.

  Further, the flow rate adjusting unit 17 has a shape along the sub drum 3, and forms a flow path between the sub drum 3. Thereby, the magnetic attachment of the magnetic sludge to the sub drum 3 can be further promoted.

[Method of treating liquid to be treated containing magnetic sludge]
The method for separating and recovering magnetic sludge from the liquid to be treated using the magnet separator of the present invention is performed by the following steps.
Contains magnetic sludge using a magnetic separator that includes a main drum that discharges magnetic sludge to the outside of the liquid to be treated, and a sub drum that is arranged upstream of the main drum and magnetizes the magnetic sludge in the liquid to be treated. In a method for treating a liquid to be treated,
(Step 1) A step of introducing the liquid to be processed into a magnet separator,
(Step 2) A step of circulating the liquid to be processed put into the magnet separator to the upper part of the sub drum,
(Step 3) A step of circulating the liquid to be processed put into the magnet separator under the sub drum,
(Step 4) A step of flowing the magnetic sludge contained in the liquid to be treated which has circulated in the upper part of the sub drum by joining the liquid to be treated which has circulated in the upper part of the sub drum and the liquid to be treated which has circulated in the lower part of the sub drum. , And are provided.

Furthermore, in the above processing method,
(Step 5) It is preferable to include a step of adjusting the flow rate of the liquid to be processed flowing in the lower part of the sub drum so as to be larger than the flow rate of the liquid to be processed flowing in the upper part of the sub drum.
In addition, you may add use of each structure of the said magnetic separator of this invention as a process of a processing method.

  The magnetic separator of the present invention recovers magnetic sludge contained in the liquid to be treated by magnetic force, and a high recovery rate is realized regardless of oiliness or water solubility. Examples of the liquid to be treated include a coolant liquid in a metal polishing machine using a magnetic metal as a work material, a plating liquid in an apparatus for plating a steel plate, and the like.

  Moreover, the magnet separator of this invention can be utilized if it is operation which isolate | separates magnetic sludges, such as a metal, from a liquid. For example, you may utilize for collection | recovery of the rare metal from industrial waste, the removal of the foreign material from a drink, edible oil, etc.

DESCRIPTION OF SYMBOLS 100,101 ... Magnet separator, 1 ... Main body, 2 ... Main drum, 2a ... Outer cylinder, 2b ... Inner cylinder, 3 ... Sub drum, 3a ... Outer cylinder, 3b ... Inner cylinder, 4 ... Input part, 5 ... Liquid reservoir part , 6a ... treatment liquid discharger, 6b ... magnetic sludge discharger, 7 ... roller, 8 ... rectifying wall, 9 ... first bottom wall, 10 ... second bottom wall, 11 ... first scraper, 12 ... first 2 scrapers, 13 ... upper flow path, 14 ... lower flow path, 15, 16 ... opening, 17 ... flow rate adjusting section, S ... magnetic sludge

Claims (6)

In the magnetic separator that removes magnetic sludge from the liquid to be treated,
A main drum for discharging magnetic sludge to the outside of the liquid to be treated;
A sub-drum disposed upstream of the main drum and magnetizing magnetic sludge in the liquid to be treated to form a magnetized aggregate;
The sub drum is disposed in a state of being submerged in the liquid to be processed, and an upper flow path for flowing the liquid to be processed is formed above the sub drum, and a lower flow path for flowing the liquid to be processed is formed below the sub drum. A magnetic separator. The liquid to be treated that has flowed through the upper flow path passes between the sub drum and the main drum, and then forms a flow that flows through the lower portion of the main drum,
The liquid to be processed that has flowed through the lower flow path is guided toward a region between the sub drum and the main drum, and merges with the flow of the liquid to be processed from the upper flow path. The magnet separator according to 1.   The magnet separator according to claim 1 or 2, wherein a flow rate of the liquid to be processed in the lower flow path is larger than a flow volume of the liquid to be processed in the upper flow path. A scraper that is fixed with one end abutting on the sub-drum and the other end arranged on the main drum side, and
The magnet according to claim 1, further comprising an opening that is disposed on the other end side of the scraper and feeds the liquid to be processed in the lower flow path to the main drum. Separator.   The magnet separator according to claim 4, wherein the opening feeds the liquid to be treated in the lower flow path in the rotation direction of the main drum.   The sub drum includes an outer cylinder fixed to the magnet separator body, and an inner cylinder in which a plurality of magnets are arranged at intervals on an outer peripheral surface, and the inner cylinder is a liquid to be processed that circulates in the lower flow path. The magnet separator according to claim 4 or 5, wherein the magnet separator rotates in a direction opposite to the flow direction.

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