KR102119355B1 - sand recycling apparatus - Google Patents

Abstract

The present invention relates to a sand recycling apparatus for recycling sand used in, for example, a mold or a heat-resistant material of a furnace. In the sand recycling apparatus, particles or lumps (1) of a metal component contained in a heat-resistant material transported by a first conveyor (15) are primarily removed by means of a first magnetic sorter (20). Then, the heat-resistant material is crushed by means of a first crusher (30). Then, the crushed heat-resistant material is classified by size by means of a screen sorting device (40). The crushed material that is smaller than a reference is supplied to a third conveyor (45), and the crushed material that is larger than the reference is re-crushed by means of a second crusher (50) and supplied to the third conveyor (45). The particles or lumps (1) of the metal component in the crushed material transported by the third conveyor (45) are sorted by means of a second magnetic sorter (A) and discharged. Accordingly, the heat-resistant material is crushed, the particles or lumps (1) of the metal component in the crushed material are effectively sorted, and thus sand can be effectively recycled with the heat-resistant material crushed.

Description

Sand recycling apparatus

The present invention relates to a sand regeneration device for regenerating sand used in a heat-resistant material or a mold of a furnace.

In general, a heat-resistant material installed around the furnace or a mold for manufacturing a casting product is produced by molding sand.

In addition, these heat-resistant materials and molds are crushed and discarded after use.

However, as described above, the heat-resistant material or the mold contains a large amount of particles or lumps of the iron component cooled while the molten metal is attached, and thus, the heat-resistant material or the mold must be treated with special waste when discarded. Accordingly, a problem in that a large amount of cost is generated when disposing of the heat-resistant material or the mold.

Therefore, recently, these heat-resistant materials or molds are not simply discarded, and the sand-recycling device is used to crush the heat-resistant materials or molds into small pieces, and then the particles or lumps of iron components contained in the heat-resistant materials or molds are sorted and removed, and the remaining sand A recycling method was developed.

However, the conventional sand regeneration device has a problem in that it is difficult to effectively separate particles or lumps of iron components contained in a heat-resistant material or a mold.

Therefore, there is a need for a new method to solve this problem.

Public utility model 20-2014-0001471,

The present invention is to solve the above problems, and after crushing the heat-resistant material or mold of the furnace made of sand, to effectively separate the particles or agglomeration of iron components so that the heat-resistant material or sand components of the mold can be recycled The purpose is to provide a sand regeneration device.

The present invention for achieving the above object, a heat-resistant material or a mold is stored, and on one side, a vibratory supply device (10) having an outlet (12a) is formed, and from the outlet (12a) of the vibratory supply device (10) forward A first conveying conveyor 15 which is extended and transports the heat-resistant material or mold discharged from the vibratory supply device 10, and is provided at an upper side of the middle of the first conveying conveyor 15, and the first conveying conveyor 15 A first magnetic sorter 20 for sorting and discharging particles or lumps 1 of iron components contained in a heat-resistant material or mold transferred by the heat-resistant material or a heat-resistant material or mold transferred through the first transfer conveyor 15 The first crusher 30 for pulverizing and discharging, and a second conveying conveyor 35 extending forward from the first crusher 30 and transferring the pulverized material discharged from the first crusher 30 to the front. , The crushed material conveyed through the second conveying conveyor 35 is sorted by size, and pulverized materials having a size smaller than the standard are discharged to the lower first outlet 42b, and crushed materials having a larger size than the standard are measured. A screen sorting device 40 for separating and discharging the second discharge port 42c in the direction, and a third transport conveyor 45 for transporting the pulverized material discharged from the first discharge port 42b of the screen sorting device 40 And, the fourth transfer conveyor 46 for transferring the pulverized material discharged from the second outlet (42c) of the screen sorting device 40, and is provided in the upper middle portion of the third transfer conveyor 45, the first 4 The second crusher 50 for supplying the upper surface of the third conveyer 45 by secondly crushing the crushed material conveyed by the conveyer 46 and the crushed crushed by the second crusher 50 The particles or lumps 1 of the iron component contained in the pulverized material which is provided on the upper side of the fourth transport conveyor 46 and transported by the fourth transport conveyor 46 are selected so as to be located behind the position where the water is supplied, There is provided a sand regeneration device characterized in that it comprises a second magnetic separator (A) to discharge.

According to another feature of the invention, the first magnetic sorter 20 is provided with a support frame 21 provided to be spaced upward from the upper surface of the first transport conveyor 15, and the lower surface of the support frame 21 The magnet member 22 provided in, the driving wheel 23 provided on one side of the support frame 21 and driven to one side by a driving motor 23a, and the other side of the support frame 21 A driven wheel 24 and a driving belt 23 and a transfer belt 25 of a synthetic resin material coupled to the circumference of the driven wheel 24, the width of the lateral direction of the support frame 21 is the It is configured wider than the lateral width of the first transport conveyor 15, and the magnet member 22 is corresponding to the lateral width of the first transport conveyor 15 on the lower surface of the support frame 21. The transfer belt 25 is provided with a semicircular connection portion 25a coupled to the outer surfaces of the drive wheel 23 and the driven wheel 24, and a transfer portion 25b connecting the lower end of the connection portion 25a And, including a circulating portion (25c) connecting the upper end of the connecting portion (25a), the transfer portion (25b) is in close contact with the lower surface of the magnet member 22 on the upper surface and the lateral width of the magnet member (22) ) Is wider than the width of the second magnetic separator (A) is composed of a support frame 61 provided on the upper side of the third transfer conveyor 45, and a bar shape extending in the front-rear direction, and the front end portion The lifting frame 62 rotatably coupled to the support frame 61 in the vertical direction, and the rear end of the lifting bar 62 is rotatably coupled to the lateral direction, and the extended portions 63b extending rearward on both sides ) Is formed of a rotating bar (63) formed and a cylindrical shape of the steel material extending in the lateral direction is rotatably coupled to the extension portion (63b) by a rotating shaft (64b) extending in the lateral direction from the center portion at both sides It is mounted on the upper surface of the third transfer conveyor 45, the magnet drum 64 provided with a plurality of magnet members 64a therein, and connected to the magnet drum 64 to drive the rotation of the magnet drum 64 Motor 65 and the magnet The guide roller 66 is rotatably coupled to the extension portion 63b of the rotation bar 63 so as to be located on the rear upper side of the rum 64, and is composed of a plate shape made of steel and the magnetic drum 64 The magnet plate 67 is provided on the extension portion 63b so as to extend from the lower circumferential surface to the rear upper side, and the magnet plate 67 provided with a magnet member 67a on the upper surface, and the lower surface of the magnet drum 64 and the magnet plate 67 and the The transfer belt 68 of synthetic resin material coupled to circulate the circumferential surface of the magnet drum 64 and the lower surface of the transfer belt 68 so as to extend rearward from the rear end of the magnet plate 67, and on the upper surface A suction case 69 having an opening 69a and a suction device connected to the suction case 69 to suck particles or lumps 1 of iron components falling into the suction case 69 and discharge them to the outside. (71), is provided on the extension portion (63b) so as to be located on the upper side of the suction case (69), is in close contact with the inner surface of the transfer belt (68) and passes through the upper portion of the suction case (69) Vibration means 72 to vibrate (68) to drop particles or lumps (1) of iron components attached to the conveyance belt (68), and the suction case (69) to be located at the rear lower side of the magnet plate (67). ) Is provided to face the inside of the camera 73 for photographing particles or lumps 1 of iron components attached to the lower surface of the transfer belt 68, and provided on the upper side of the camera 73 The air blower 74 that blows the particles or lumps 1 of iron component to the upper side of the camera 73 in the lateral direction, and receives the signals of the camera 73, and the transfer belt 68 Control to measure the amount of the iron component particles or lumps 1 attached to the lower side and to control the operation of the vibrating means 72 to cause the vibrating means 72 to vibrate the conveyance belt 68 strongly or weakly A sand regeneration device is provided, comprising means (75).

In the sand regeneration device according to the present invention, after the particles or lumps 1 of metal components contained in the heat-resistant material transferred by the first conveyer 15 are first removed using the first magnetic sorter 20, After crushing the heat-resistant material using the first crusher 30, the crushed materials of the crushed heat-resistant material are classified by size using a screen sorting device 40, and crushed materials smaller than the standard are transferred to the third conveying conveyor ( 45), the crushed material larger than the standard is again crushed using a second crusher 50 and supplied to a third conveying conveyor 45, and a third conveying conveyor using a second magnetic sorter (A) ( Particles or lumps (1) of metal components contained in the pulverized material conveyed by 45) are sorted and discharged.

Therefore, by crushing the heat-resistant material and effectively separating particles or lumps 1 of metal components contained in the pulverized crushed material, there is an advantage that the sand crushed the heat-resistant material can be effectively recycled.

1 is a side configuration diagram showing a sand regeneration device according to the present invention,
Figure 2 is a side cross-sectional configuration diagram showing a vibration supply device of the sand regeneration device according to the present invention,
Figure 3 is a front cross-sectional configuration showing a first magnetic separator of the sand regeneration device according to the present invention,
Figure 4 is a side cross-sectional configuration diagram showing a first crusher of the sand regeneration device according to the present invention,
5 is a side cross-sectional configuration diagram showing a screen sorting device of a sand regeneration device according to the present invention,
Figure 6 is a side cross-sectional configuration diagram showing a second crusher of the sand regeneration device according to the present invention,
Figure 7 is a side cross-sectional configuration diagram showing a second magnetic sorter of the sand regeneration device according to the present invention,
8 is an enlarged side sectional side view of a main portion of a second magnetic sorter of a sand regeneration device according to the present invention;
9 is a plan view showing a second magnetic sorter of the sand regeneration device according to the present invention.
10 is a circuit diagram of a second magnetic sorter of the sand regeneration device according to the present invention.

Hereinafter, the present invention will be described in detail based on the attached exemplary drawings.

1 to 10 show a sand regeneration device according to the present invention, after crushing the heat-resistant material of the furnace composed of sand components, by separating the particles or lumps (1) of the iron component contained in the crushed crushed material By discharging, it is illustrated that only pure sand components are discharged to regenerate sand.

According to this, in the sand regeneration device according to the present invention, the heat-resistant material is stored, and on one side, a vibratory supply device 10 having an outlet 12a formed thereon, and extending forward from the outlet 12a of the vibratory supply device 10, A first transfer conveyor 15 for transporting the heat-resistant material discharged from the vibratory supply device 10, and heat resistance provided on the upper middle of the first transfer conveyor 15 and transferred by the first transfer conveyor 15 A first magnetic sorter (20) for sorting and discharging particles or lumps (1) of iron components contained in ashes or molds, and for pulverizing and discharging heat-resistant materials or molds transferred through the first transfer conveyor (15) The first crusher 30, a second conveying conveyor 35 extending forward from the first crusher 30 and transferring the pulverized material discharged from the first crusher 30 to the front, and the second conveying The crushed material conveyed through the conveyor 35 is sorted by size, and pulverized products having a size smaller than the standard are discharged to the lower first outlet 42b, and crushed products having a larger size than the standard are discharged from the lateral direction. A screen sorting device 40 for separating and discharging with 42c, a third transport conveyor 45 for transporting the pulverized material discharged from the first outlet 42b of the screen sorting device 40, and the screen sorting A fourth transfer conveyor 46 for transporting the pulverized material discharged from the second outlet 42c of the device 40 and an upper middle portion of the third transfer conveyor 45, the fourth transfer conveyor 46 2) second crushing the crushed material conveyed by the second conveyer 50 to supply the top surface of the third conveyer 45, and the rear of the position where the crushed material crushed by the second crusher is supplied A second magnetic sorter for sorting and discharging particles or agglomerations of iron components contained in the pulverized material transported by the fourth transport conveyor 46 to be located at the upper side of the fourth transport conveyor 46 ( A).

In detail, as shown in FIG. 2, the vibrating supply device 10 is configured in a cylindrical shape with a support 11 fixed to a bottom surface, an upper surface open, and the outlet 12a formed on a rear surface. The storage cylinder 12 is vibratingly coupled to the support 11 through a spring 12b and a vibrator 13 connected to the storage cylinder 12 to vibrate the storage cylinder 12 in the vertical direction. It is composed.

At this time, the inner bottom surface of the storage cylinder 12 is configured to be inclined downward toward the outlet 12a.

In addition, the heat-resistant material supplied to the storage cylinder 12 is crushed to an appropriate size during the loading and transportation steps, and is firstly separated into particles or lumps 1 of sand and metal components to the storage cylinder 12. It is supplied and stored.

Therefore, when the vibrator 13 is driven in a state in which a large amount of heat-resistant material is stored in the storage tube 12, the heat-resistant material stored inside the storage tube 12 is vibrated while the storage tube 12 vibrates. It is discharged to the transport conveyor (15).

The first transport conveyor 15 uses a belt conveyor arranged to extend from the outlet 12a of the vibrating device to the upper side of the first crusher 30.

The first magnetic sorter 20, as shown in Figure 3, the support frame 21 provided to be spaced upward from the upper surface of the first transport conveyor 15, and the lower surface of the support frame 21 The magnet member 22 provided in, the driving wheel 23 provided on one side of the support frame 21 and driven to one side by a driving motor 23a, and the other side of the support frame 21 It consists of a driven wheel (24), a transfer belt (25) of synthetic resin material coupled to the circumference of the drive wheel (23) and the driven wheel (24).

The support frame 21 is configured to have a wider lateral width than the lateral width of the first transport conveyor 15.

The magnet member 22 is provided to correspond to the lateral width of the first transfer conveyor 15 on the lower surface of the support frame 21.

At this time, the magnet member 22 is composed of a plurality, it is provided on the lower side of the support frame 21 so that the side surfaces are close to each other.

The transfer belt 25 includes a semicircular connection portion 25a coupled to the outer surfaces of the drive wheel 23 and the driven wheel 24, and a transfer portion 25b connecting the lower end of the connection portion 25a, and Consisting of a circulating portion (25c) connecting the top of the connecting portion (25a), the transfer portion (25b) is in close contact with the lower surface of the magnet member (22) on the upper surface and the lateral width is the magnet member (22) ) Is wider than the width.

To this end, the driving wheel 23 and the driven wheel 24 are provided at both ends of the support frame 21 wider than the lateral width of the first transport conveyor 15.

Therefore, when the heat-resistant material discharged from the vibratory supply device 10 is conveyed by the first transfer conveyor 15, when the heat-resistant material passes through the lower side of the first magnetic sorter 20, it is transferred together with the heat-resistant material. Particles or lumps 1 of iron component are in close contact with the lower surface of the transfer portion 25b of the transfer belt 25 by the magnetism of the magnet member 22.

At this time, when the driving wheel 23 is driven using the driving motor 23a, the conveying part 25b is circulated in the lateral direction, and particles or lumps 1 of iron components attached to the conveying part 25b are It is transferred in the lateral direction together with the transfer portion 25b.

In addition, when the particles or lumps 1 of the iron component are spaced in the lateral direction more than the lower side of the magnet member 22 by the transfer portion 25b, the magnetic force of the magnet member 22 is the iron component particles or It does not act on the lump 1, and accordingly, the particles or lump 1 of the iron component falls down by its own weight and is discharged.

As shown in FIG. 4, the first crusher 30 is provided with a case 31 in which an inlet 31a is formed on an upper surface and an outlet 31b is formed at a lower side, and is provided inside the case 31. It is composed of a crushing unit 32 for crushing the heat-resistant material introduced into the input port 31a, and is provided so that the input port 31a is located below the front end of the first transfer conveyor 15.

Therefore, when the heat-resistant material transferred by the first conveying conveyor 15 is introduced into the inlet 31a, the heat-resistant material is crushed into small pieces while the heat-resistant material passes through the crushing unit 32 and discharged downward through the outlet 31b. It is configured as possible.

The pulverizing unit 32 has been developed and used in various types, detailed description thereof will be omitted.

The second transport conveyor 35 uses a belt conveyor extending from the lower side of the first crusher 30 to the upper side of the screen selection device.

As shown in FIG. 5, the screen sorting device 40 is composed of a support case 41 provided on the rear end of the third conveyor device and a cylindrical shape with the upper and lower sides open, a spring 42a. Through the support case 41, the upper side of the support case 41 is provided to be vibrating, a first outlet 42b is formed on the lower side, a second outlet 42c is formed on one side, and a perforated plate 42d is provided on the second outlet ( 42c) is provided to be connected to the upper case 42, and is provided on the upper side of the upper case 42 is composed of a vibrator 43 for vibrating the upper case 42.

The perforated plate 42d has a plurality of through holes having a diameter of 30 mm.

Therefore, in the state in which the vibrator 43 is driven to vibrate the upper case 42, the pulverized material of the heat-resistant material that has been crushed through the first crusher 30 is transferred to the second transport conveyor 35 to be transferred to the upper part. When supplied to the upper side of the case 42, the pulverized material is discharged toward the second outlet 42c while vibrating on the upper surface of the perforated plate 42d.

At this time, among the pulverized material placed on the perforated plate 42d, the pulverized material having a diameter of less than 30 mm passes through the through hole of the perforated plate 42d and falls to the lower side, and then is discharged to the first outlet 42b, and has a diameter. The pulverized material of 30 mm or more is discharged to the second outlet 42c.

The third transport conveyor 45 uses a belt conveyor provided to extend in the lateral direction from the lower side of the first outlet 42b of the screen sorting device 40.

The fourth transfer conveyor 46 uses a belt conveyor extending from the lower side of the second outlet 42c of the screen sorting device 40 to the upper side of the second crusher 50.

As shown in FIG. 6, the second crusher 50 is provided with a support 51 provided at an intermediate portion of the third conveyor, and an inlet 52a at an upper surface and an outlet 52b at a lower side. Grinding unit 53 for crushing the crushed material provided in the case 52 and the case 52 provided on the support 51, the inside of the case 52 so as to be located on the upper side of the third conveyor As configured as, the inlet (52a) is installed to be located at the lower end of the front end of the fourth transfer conveyor (46).

Therefore, when the pulverized material conveyed by the fourth conveying conveyor 46 is supplied to the inlet 52a, the pulverized material is pulverized while passing through the crushing unit 53, and then the third conveying conveyor 45 It is supplied to the top surface.

The second magnetic sorter (A) is composed of a support frame 61 provided on the upper side of the third transfer conveyor 45 and a bar shape extending in the front-rear direction, as shown in FIGS. 7 to 9. The front end portion is rotatably coupled to the support frame 61 in the vertical direction to be rotated in the vertical direction, and the rear end portion of the lift bar 62 is rotatably coupled to the lateral direction, and both sides are extended to the rear. Rotating bar (63b) is formed is formed of a cylindrical shape of the steel material extending in the lateral direction and is rotatably rotatable to the extension portion (63b) by a rotating shaft (64b) extending in the lateral direction from the center of both sides Combined and mounted on the upper surface of the third transport conveyor 45, the magnet drum 64 is provided with a plurality of magnet members 64a therein, and is connected to the magnet drum 64 to rotate the magnet drum 64 The driving motor 65 and the guide roller 66 rotatably coupled to the extension portion 63b of the rotating bar 63 so as to be located on the rear side of the magnet drum 64, and the plate shape of steel material It is composed of a magnet plate (64) is provided in the extending portion (63b) so as to extend from the lower circumferential surface to the rear upper side and the upper surface of the magnet plate (67a) with a magnet member (67), and the magnetic drum (64) And a transfer belt 68 of synthetic resin material coupled to circulate the lower surface of the magnet plate 67 and the circumferential surface of the magnet drum 64, and the transfer belt to extend rearward from the rear end of the magnet plate 67 ( 68) is provided on the lower side and the upper surface of the suction case 69 is formed with an opening (69a), and is connected to the suction case 69, the particles or lumps of iron components (1) falling into the interior of the suction case (69) ) Is provided in the extension portion (63b) so as to be located on the upper side of the suction device (71) and the suction case (69) to suck out and close to the inner surface of the transfer belt (68) and the suction case Vibration means 72 to vibrate the transfer belt 68 passing through the upper portion of the 69 to cause particles or lumps 1 of iron components attached to the transfer belt 68 to fall, and of the magnet plate 67 Rear lower The camera 73 is provided so as to be positioned upwards inside the suction case 69 so as to be located on the lower surface of the transfer belt 68 to photograph particles or lumps 1 of iron components and the camera It is provided on the upper side of the 73, the air blower 74 for blowing the particles or lumps 1 of the iron component in the lateral direction falling to the upper side of the camera 73, and receives a signal from the camera 73 And the vibration means for measuring the amount of particles or lumps (1) of the iron component attached to the lower surface of the transfer belt 68 and the vibration means 72 to vibrate the transfer belt 68 strongly or weakly ( It consists of a control means (75) for controlling the operation of 72).

The rotation bar 63 is configured in a bar shape extending in the lateral direction, and the extension portion 63b extends backward from both ends of the rotation bar 63.

At this time, the rotation bar 63 is provided with a support tube (63a) that extends forward to the front center portion and is rotatably coupled to the rear end of the lifting bar (62), to the rear end of the lifting bar (62) It is rotatably coupled laterally.

In addition, the lateral width of the rotating bar 63 is configured to be wider than the lateral width of the third conveyor.

The magnet drum 64 is configured such that the lateral width corresponds to the lateral width of the third conveyor.

The guide roller 66 has a smaller diameter than the magnetic drum 64.

The magnet plate 67 is disposed such that the front end portion is close to the lower end of the circumferential surface of the guide roller 66.

The transfer belt 68 is a semi-circular connection portion 68a coupled to the outer surfaces of the magnet drum 64 and the guide roller 66, and a transfer portion 68b connecting the lower end of the connection portion 68a, and Consisting of a circulating portion (68c) connecting the upper end of the connecting portion (68a), the transfer portion (68b) is an upper surface is in close contact with the lower surface of the magnet plate (67), the lateral width is the side of the magnetic drum (64) It is configured equal to the width of the direction.

At this time, the conveyance belt 68 is composed of a pulverized material and a color distinct from the appearance of the particles or lumps 1 of the metal material mixed in the crushed material, for example, red color.

The suction case 69 is composed of a cylindrical shape of a high-strength metal material, and is fixed to the extension portion 63b so that the upper surface is close to the lower surface of the transfer portion 68b of the transfer belt 68.

The suction device 71 is provided in the middle of the suction pump 69a and the exhaust pump 71a connected to the suction case 69 through the suction pipe 71b and in the air sucked through the suction pipe 71b It is composed of a filtering device (71c) to filter out the particles or lumps (1) of the contained metal component.

The vibrating means 72 is configured such that both sides are fixed to the extension portion 63b so that the lower side is in close contact with the upper surface of the transfer portion 68b, and when operated, the transfer portion 68b is vibrated in the vertical direction.

The camera 73 is provided so as to face upward on the upper surface of the horizontal bar 73a provided inside the suction case 69, the iron being transferred to the rear along with the transfer portion 68b of the transfer belt 68 It is configured to photograph particles or lumps 1 of the component.

The air blower (74) is the top of the camera (73) on the top of the vertical bar (74a) extending upward from the horizontal bar (73a), that is, the side of the lens provided in the camera 73 facing upward The air injection nozzle (74b) provided to extend in the direction, and connected to the air injection nozzle (74b) through the air supply pipe (74d) to the air compressor (74c) for supplying high pressure air to the air injection nozzle (74b) It is configured, when operating the air compressor (74c), by injecting high-pressure air to the upper side of the camera 73 through the air injection nozzle (74b), as described later, iron falling to the upper side of the camera (73) By blowing the particles or the lump 1 of the component in the lateral direction, the lens of the camera 73 is prevented from being contaminated by the lens or the lump 1 of the iron component.

The control means 75 analyzes the image taken by the camera 73, the image analysis program for measuring the amount of particles or lumps 1 of the iron component attached to the lower surface of the transfer belt 68 ( 75a) is mounted, in proportion to the amount of particles or lumps 1 of the iron component attached to the lower surface of the conveyance belt 68, the vibration means 72 is the strength to vibrate the conveyance belt 68 It is configured to adjust.

That is, when the amount of iron particles or lumps 1 attached to the lower surface of the conveyance belt 68 is large, the control means 75 operates the vibrating means 72 strongly so that the conveyance belt 68 is strong. The vibration, and the smaller the amount of iron particles or lumps 1 attached to the lower surface of the transfer belt 68, the control means 75 operates the vibration means 72 weakly to move the transfer belt 68 ) Is adjusted to vibrate violently.

The operation of the second magnetic selector (A) is as follows.

First, the magnetic drum 64 and the conveying belt 68 are in close contact with the upper surface of the crushed material conveyed backward by the third conveying conveyor 45.

At this time, the magnetic drum 64 is supported by the lifting bar 62 and the rotating bar 63 to be rotatable and laterally rotatable, depending on the size of the crushed material conveyed by the third conveying conveyor 45 Particles of metal components that are properly raised and rotated and are as close as possible to particles or agglomerates 1 of metal components transferred to the rear with the pulverized substance and transferred backward with the pulverized substance by the magnetic force of the magnetic drum 64 Alternatively, the lump 1 is attached to the lower surface of the transfer portion 68b.

Then, when the driving drum 65 is rotated by driving the driving motor 65, the conveying belt 68 is conveyed to the rear, and accordingly, particles and lumps 1 of metal components are also conveyed to the rear. , While passing through the lower surface of the magnet plate 67, is attached to the lower surface of the transfer portion 68b of the transfer belt 68 by the magnetic force of the magnet plate 67.

Then, when the magnet drum 64 is further rotated, particles and lumps 1 of metal components attached to the transfer portion 68b of the transfer belt 68 are transferred to the rear of the magnet plate 67, the magnet plate 67 ) Will no longer act, and accordingly, particles and lumps 1 of metal components attached to the transfer unit 68b are dropped by their own weight and fall into the inside of the suction case 69. When the suction device 71 is operated, particles and lumps 1 of metal components falling into the suction case 69 are discharged and removed.

At this time, the camera 73 photographs the lower surface of the transfer part 68b at the rear position of the magnet plate 67, and the control means 75 analyzes the image taken by the camera 73 to analyze the magnet plate 67 ) Check whether there are particles and lumps 1 of metal components attached to the lower surface of the transfer unit 68b without being dropped in the transferred state of the transfer unit, and control the operation of the vibration means 72 to control the transfer unit 68b By vibrating ), the particles and lumps 1 of the metal component attached to the transfer part 68b are dropped to the lower side to be dropped into the suction case 69.

That is, since the transfer belt 68 is made of synthetic resin material, even if the magnetic force is removed while the particles and lumps 1 of the metal component are attached to the lower surface of the transfer portion 68b by magnetic force, the transfer portion 68b is immediately transferred. In the case of remaining without falling off from the lower side of the case, in this case, the control means 75 analyzes the image photographed by the camera 73 to confirm this, and the metal component attached to the transfer unit 68b Depending on the amount of particles and lumps 1, the strength of the vibrating means 72 is controlled to effectively remove particles and lumps 1 of metal components attached to the transfer section 68b.

The sand regeneration device configured as described above is firstly removed by using the first magnetic sorter 20, particles or lumps 1 of metal components contained in the heat-resistant material conveyed by the first conveying conveyor 15, 1 After crushing the heat-resistant material using the crusher 30, the crushed materials of the crushed heat-resistant material are classified by size using a screen sorting device 40, and the crushed material smaller than the standard is transferred to the third conveyer 45 ), and the crushed material larger than the standard is again crushed using the second crusher 50 and supplied to the third conveying conveyor 45, and the third conveying conveyor 45 using the second magnetic sorter A ) And sorts and discharges particles or lumps (1) of metal components contained in the pulverized material conveyed by ).

Therefore, by crushing the heat-resistant material and effectively separating particles or lumps 1 of metal components contained in the pulverized crushed material, there is an advantage that the sand crushed the heat-resistant material can be effectively recycled.

In the case of the present invention, although it was illustrated to recycle the heat-resistant material of the furnace composed of sand components, the sand regeneration device according to the present invention can be utilized for various purposes, such as crushing and recycling a mold.

10. Vibration type feeding device 15. First conveying conveyor
20. 1st magnetic sorter 30. 1st crusher
35. Second transfer conveyor 40. Screen sorting device
45. Third transfer conveyor 45. Fourth transfer conveyor
50. Second crusher A. Second magnetic sorter

Claims (2)

A heat-resistant material or a mold is stored, and on one side, a vibration-type supply device 10 having an outlet 12a formed therein,
A first transfer conveyor (15) extending forward from the outlet (12a) of the vibratory feeder (10) to transport the heat-resistant material or mold discharged from the vibratory feeder (10),
A first magnetic which is provided on the upper side of the middle portion of the first conveyer 15 and selects and discharges particles or lumps 1 of iron components contained in a heat-resistant material or mold conveyed by the first conveyer 15 Selector 20 and,
A first crusher 30 for pulverizing and discharging the heat-resistant material or the mold transferred through the first transfer conveyor 15,
A second conveying conveyor 35 extending forward from the first crusher 30 to convey the pulverized material discharged from the first crusher 30 to the front;
The crushed material conveyed through the second conveying conveyor 35 is sorted by size, and pulverized material having a size smaller than the standard is discharged to the lower first outlet 42b, and crushed material having a larger size than the standard is lateral. Screen separating device 40 for separating and discharging to the second outlet (42c) of,
A third transfer conveyor 45 for transporting the pulverized material discharged from the first discharge port 42b of the screen sorting device 40,
And a fourth transfer conveyor 46 for transferring the pulverized material discharged from the second outlet (42c) of the screen sorting device 40,
A second crusher which is provided in the upper middle portion of the third conveyer 45 and supplies the top surface of the third conveyer 45 by secondaryly crushing the crushed material conveyed by the fourth conveyer 46. 50 and,
The crushed material crushed by the second crusher 50 is provided on the upper side of the fourth conveying conveyor 46 so as to be positioned behind the supplied position, and is included in the crushed material conveyed by the fourth conveying conveyor 46. A second magnetic sorter (A) for sorting and discharging particles or lumps (1) of iron components,
The first magnetic sorter 20 is
A support frame 21 provided to be spaced apart from the upper surface of the first transport conveyor 15;
And a magnet member 22 provided on the lower surface of the support frame 21,
A driving wheel 23 provided on one side of the support frame 21 and driven to one side by a driving motor 23a,
A driven wheel 24 provided on the other side of the support frame 21,
It comprises a transfer belt 25 of a synthetic resin material coupled to the circumference of the drive wheel 23 and the driven wheel 24,
The width of the support frame 21 in the lateral direction is wider than the width of the first transport conveyor 15.
The magnet member 22 is provided on the lower surface of the support frame 21 to correspond to the lateral width of the first transport conveyor 15,
The transfer belt 25 includes a semicircular connection portion 25a coupled to the outer surfaces of the drive wheel 23 and the driven wheel 24, and a transfer portion 25b connecting the lower end of the connection portion 25a, and It includes a circulation portion (25c) connecting the top of the connecting portion (25a),
The transfer portion 25b is in close contact with the lower surface of the magnet member 22 on the upper surface, and the lateral width is wider than the width of the magnet member 22,
The second magnetic selector (A) is
And a support frame 61 provided on the upper side of the third transfer conveyor 45,
The lifting bar 62 is composed of a bar shape extending in the front-rear direction and the front end is rotatably coupled to the support frame 61 in the vertical direction.
The rotation bar 63 is rotatably coupled laterally to the rear end of the lifting bar 62, and the extension bar 63b extending on both sides is formed,
It is composed of a cylindrical shape of the steel material extending in the lateral direction and is rotatably coupled to the extension portion 63b by a rotating shaft 64b extending in the lateral direction from the center portions at both sides, so that the upper surface of the third transfer conveyor 45 It is mounted on the inside and the magnet drum 64 is provided with a plurality of magnet members (64a),
A driving motor 65 connected to the magnetic drum 64 to rotate the magnetic drum 64,
A guide roller 66 rotatably coupled to the extension portion 63b of the rotation bar 63 so as to be located on the rear upper side of the magnet drum 64,
It is composed of a plate shape of a steel material and is provided in the extension portion 63b so as to extend from the lower circumferential surface to the rear upper side of the magnetic drum 64, and the magnetic plate 67 provided with a magnetic member 67a on the upper surface,
A transfer belt 68 of synthetic resin material coupled to circulate the lower surface of the magnet drum 64 and the magnet plate 67 and the circumferential surface of the magnet drum 64,
And the suction case 69 is provided on the lower surface of the transfer belt 68 so as to extend rearward from the rear end of the magnet plate 67, an opening (69a) is formed on the upper surface,
A suction device 71 connected to the suction case 69 to inhale particles or lumps 1 of iron components falling into the suction case 69 and discharged to the outside;
It is provided on the extension portion 63b so as to be located on the upper side of the suction case 69 and is in close contact with the inner surface of the transfer belt 68 and vibrates the transfer belt 68 passing through the upper portion of the suction case 69 Vibration means 72 to cause the iron component particles or lumps 1 attached to the conveyance belt 68 to fall,
It is provided so as to face the inside of the suction case 69 so as to be located at the rear lower side of the magnet plate 67 to photograph particles or lumps 1 of iron components attached to the lower side of the transfer belt 68. Camera (73),
An air blower (74) provided on the upper side of the camera (73) to blow particles or lumps (1) of iron components falling to the upper side of the camera (73) laterally,
Receiving a signal from the camera 73 and measuring the amount of particles or lumps 1 of iron components attached to the lower surface of the transfer belt 68, and the vibration means 72 strongly strengthens the transfer belt 68 Or a sand regeneration device characterized in that it comprises a control means (75) for controlling the operation of the vibrating means (72) to vibrate weakly. delete

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