JP2013176743A - Electrostatic sorting apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electrostatic sorting apparatus capable of securely sorting resin pieces.SOLUTION: An electrostatic sorting apparatus 1 includes an electrifying container 3 which electrifies resin pieces, a vibration feeder 5 which conveys the electrified resin pieces, a pair of electrodes 7 which produce an electrostatic field separating the electrified resin pieces, a recovery container 10 which recovers the resin pieces, and a collection electrode 11 which collects wear powder (resin powder). The collection electrode 11 for collecting the wear powder is arranged above the vibration feeder 5.

Description

  The present invention relates to an electrostatic sorting device, and more particularly to an electrostatic sorting device that sorts charged resin pieces by type using an electrostatic field.

  In recent years, technology development for reusing resources has been promoted from the viewpoint of effectively using resources. Here, a case where the resin is reused as one of such resources will be described. In order to reuse a resin piece crushed for recycling as a resin raw material, it is required to select and collect the resin piece according to its material (type).

  In order to sort the resin by material, an electrostatic sorting method is widely used in which resin pieces are charged and sorted by an electrostatic field using the difference in charged state depending on the material. For example, for household appliances, polypropylene (PolyPropylene) resin (hereinafter referred to as “PP resin”), acrylonitrile butadiene styrene resin (hereinafter referred to as “ABS resin”), Polystyrene resin (hereinafter referred to as “PS resin”) is used.

  One method for sorting and collecting these resins used in discarded home appliances is to use a specific gravity sorting method in combination with an electrostatic sorting method. In this method, first, a PP resin having a low specific gravity is selected and collected by a specific gravity sorting method, and then a resin containing the remaining ABS resin and PS resin (including residual PP resin) is obtained by ABS using an electrostatic sorting method. The resin and PS resin are sorted and collected.

  Further, when the main two-component resin (ABS resin, PS resin) is taken out from the three-component resin (ABS resin, PS resin, PP resin) by the electrostatic sorting method, for example, electrostatic sorting treatment is performed by 2 There is a method of combining in stages. ABS resin is sorted and collected by the first stage electrostatic sorting process, and PS resin is collected from the mixture of PS resin and PP resin by the second stage electrostatic sorting process. In particular, the electrostatic sorting method is applied to sorting a mixture of crushed resin pieces that are close in specific gravity and difficult to separate and collect by the specific gravity sorting method.

  In the reuse (recycling) of resin, improving sorting accuracy and increasing the amount of recovered resin are extremely important themes for the purpose and business of material recycling. In order to realize these, Patent Document 1 proposes a resin sorting apparatus that sorts resin pieces by detecting the charge amount of the resin pieces.

  This resin sorting apparatus includes a charging container that stirs and charges a resin piece, and a monitoring window is formed in the charging container. The resin pieces that are color-coded by type and are charged in the charging container stick to the monitoring window. The resin piece stuck to the monitoring window is imaged by a CCD (Charge Coupled Device) camera. In the image processing unit, the type of the resin piece attached to the monitoring window is identified based on the image data.

  When one kind of resin piece attached to the monitoring window occupies a predetermined ratio or more of the area of the monitoring window, the charge determining unit determines that the charge amount of the resin is close to saturation. In this way, in this resin sorting device, by sufficiently charging the resin pieces, even if the type and conditions of the sorting object change, erroneous sorting due to insufficient charging is suppressed, and the resin is sorted accurately and reliably. It is supposed to be possible.

  Patent Document 2 proposes a resin sorting device that transports a resin while charging it. In this resin sorting apparatus, the inner wall of the resin sorting apparatus is lined with a material that promotes charging of the sorting material, including synthetic resin. Thereby, in this resin sorting device, the charge amount of the resin piece to be sorted is improved when transported, the accuracy of sorting the resin can be increased, and by shortening the sorting time of the resin, It is said that the amount of resin recovered can be increased.

JP 2002-355578 A JP 07-328482 A

  However, the conventional resin sorting apparatus has the following problems. In the step of selecting the resin, in the step of charging the resin piece and the step of transporting the resin piece, the resin pieces may come into contact with each other to generate wear powder. The wear powder is also charged with other resin pieces because it has undergone a charging process, and has a positive or negative charge. Further, since the wear powder is in a powder state, the amount of charge per weight is larger than that of other resin pieces, and therefore, the wear powder is easily affected by an electric field.

  In the process of sorting the resin pieces, the charged wear powder may be attracted to the electrode having the opposite polarity to the charged polarity (plus or minus) and adhere to the electrode. When wear powder having a polarity opposite to the polarity of the electrode adheres, the potential of the electrode is canceled, the apparent voltage is lowered, and the electric field generated between the electrodes is weakened. In addition, since the electrodes are insulated by air, the wear powder adheres to the electrodes, so that the insulating properties are lowered, and the distance between the electrodes is apparently shortened to facilitate discharge.

  If the electric field generated between the electrodes is weakened or a discharge occurs between the electrodes, the resin pieces to be sorted will not be put into the desired electrostatic field, and the resin pieces can be reliably sorted by material. There is a possibility that it will not be possible.

  The present invention has been made to solve the above problems, and an object of the present invention is to provide an electrostatic sorting device capable of reliably sorting resin pieces.

  An electrostatic sorting apparatus according to the present invention is an electrostatic sorting apparatus that charges a resin piece and sorts and collects the charged resin piece for each material by a predetermined electrostatic field while transporting the charged resin piece. And a pair of second counter electrodes. The charging unit charges the resin piece. The sorting unit includes a pair of first counter electrodes that are provided on the downstream side in the transport direction with respect to the charging unit and sort a resin piece by generating a predetermined electrostatic field. The pair of second counter electrodes are disposed at a position in the direction intersecting the transport direction so as to sandwich the resin piece to be transported, at a position in the middle of transporting the resin piece from the charging unit to the sorting unit, Another predetermined electrostatic field is generated.

  According to the electrostatic sorting apparatus according to the present invention, it is possible to reliably sort resin pieces.

It is a side view which shows typically the structure of the electrostatic selection apparatus which concerns on Embodiment 1 of this invention. FIG. 6 is a side view for explaining the operation of the electrostatic sorting device in the same embodiment. In the same embodiment, it is the 1st partial side view for explaining the principle which sorts a resin piece. In the same embodiment, it is the 2nd partial side view for explaining the principle which sorts a resin piece. FIG. 4 is a partial side view schematically showing a collecting electrode for removing wear powder and a structure in the vicinity thereof in the embodiment. In the embodiment, it is a partial side view schematically showing another collection electrode for removing wear powder and the structure in the vicinity thereof. In the same embodiment, it is a side view which shows typically the structure of the electrostatic selection apparatus which concerns on a modification. FIG. 4 is a partial side view schematically showing a collecting electrode for removing wear powder and a structure in the vicinity thereof in the embodiment. In the same embodiment, it is a fragmentary perspective view which shows typically the structure of the collection electrode for removing abrasion powder, and its vicinity. In the same embodiment, it is the 1st partial side view which shows typically the other electrode for collection for removing abrasion powder, and the structure of the vicinity. In the same embodiment, it is the 2nd partial side view which shows typically the other electrode for collection for removing abrasion powder, and the structure of the vicinity. It is a side view which shows typically the structure of the electrostatic selection apparatus which concerns on Embodiment 2 of this invention. FIG. 4 is a partial side view schematically showing a collecting electrode for removing wear powder and a structure in the vicinity thereof in the embodiment. It is a side view which shows typically the structure of the electrostatic selection apparatus which concerns on Embodiment 3 of this invention. FIG. 4 is a partial side view schematically showing a collecting electrode for removing wear powder and a structure in the vicinity thereof in the embodiment.

Embodiment 1
An electrostatic sorting apparatus according to Embodiment 1 of the present invention will be described. As shown in FIG. 1, an electrostatic sorting apparatus 1 includes a charging container 3 for charging a resin piece, a vibration feeder 5 for conveying the charged resin piece, and a pair of electrodes for forming an electrostatic field for separating the charged resin piece. (A pair of first counter electrodes) 7, a collection container 10 that collects resin pieces, and a collection electrode 11 that collects wear powder (resin powder).

  The pair of electrodes 7 includes a high voltage electrode 7a connected to a high voltage and a ground electrode 7b connected to a ground voltage. The collection container 10 includes collection containers 10a and 10b for collecting the resin sorted by charging, and a collection container 10c for collecting the resin that has not been sorted.

  Next, the operation of the electrostatic sorting device 1 described above will be described. Here, ABS resin and PS resin are taken as examples of the resin piece, the resin piece of ABS resin is the resin piece 2a, the resin piece of PS resin is the resin piece 2b, and these resin pieces 2a and 2b are selected and collected. An outline of the case will be described.

  As shown in FIG. 2, first, the crushed resin pieces 2 a and 2 b are put into an inclined charging container 3. As the charging container 3 rotates, the resin pieces 2a and 2b in the charging container 3 are agitated. The resin pieces 2a and 2b are rubbed against each other by stirring the resin pieces 2a and 2b, and the resin pieces 2a and 2b are charged by the friction. According to the resin triboelectric charge train, the resin piece 2a (ABS resin) is charged positively (+), and the resin piece 2b (PS resin) is charged negatively (-).

  Next, the charged resin pieces 2 a and 2 b are discharged from the charging container 3, sent onto the vibration feeder 5, and conveyed while being spread evenly. While being conveyed, the wear powder is collected by the collecting electrode 11. This will be described in detail later. The resin pieces 2a and 2b conveyed by the vibration feeder 5 are put into a space between the high voltage electrode 7a and the ground electrode 7b. In this space, an electrostatic field for separation for sorting resin pieces is formed by the high voltage electrode 7a and the ground electrode 7b.

  Here, the selection of resin pieces by an electrostatic field will be described. As shown in FIG. 3, while the resin pieces 2a and 2b pass through the separation electrostatic field formed between the high voltage electrode 7a and the ground electrode 7b, the resin piece 2a charged positively (+) is Then, it is dropped while being pulled toward the ground electrode 7b by the Coulomb force acting between the resin piece 2a and the ground electrode 7b, and is recovered in the recovery container 10a. On the other hand, the negatively charged resin piece 2b falls while being pulled toward the high voltage electrode 7a by the Coulomb force acting between the resin piece 2b and the high voltage electrode 7a, and is collected in the collection container 10b. It will be.

  Also, as shown in FIG. 4, the resin pieces 2a and 2b that are not sufficiently charged in the charging container 3 are not subjected to the Coulomb force required for sorting when dropped, and are dropped as they are to recover the recovery container 10a and the recovery container 10a. It will be collected in a collection container 10c arranged between the containers 10b.

  The above-described sorting and collection of resin pieces will be described more specifically. The resin pieces 2a and 2b supplied to the electrostatic sorting device 1 are collected from discarded home appliances, crushed so that the size (diameter) is about 8 mm or less, and passed through a 2 mm sieve. is there. As this resin piece, a mixture of resin pieces having an ABS resin content of about 35%, a PS resin content of about 55%, and a residual PP resin content of about 10% is assumed.

  In this case, the ABS resin is charged positively (+) and the PS resin and the remaining PP resin are negatively charged (-) by stirring the mixture of resin pieces in the charging container 3 for 10 minutes or more. . The mixture of the charged resin pieces 2a and 2b is conveyed by the vibration feeder 5 and passed between the electrodes 7 that have generated an electrostatic field of 200 kV / m or more, thereby positively charging the resin piece (ABS resin). ) 2a is recovered in the recovery container 10a, and negatively charged resin pieces (PS resin and residual PP resin) 2b are recovered in the recovery container 10b.

  As already described, when the resin pieces are stirred in the charging container, the resin pieces may come into contact with each other to generate wear powder (resin powder). When charged wear powder adheres to the electrode of the opposite polarity to the charged polarity (plus or minus), the electrostatic field is weakened or discharge occurs between the electrodes to ensure the resin pieces to be sorted. It is assumed that it will not be possible to sort them.

  In the electrostatic sorting apparatus 1 described above, the vibration feeder 5 and the collection electrode 11 are arranged at a distance as a pair of second counter electrodes, and the wear powder is collected above the vibration feeder 5. The collecting electrode 11 is arranged. Here, as shown in FIG. 5, it is assumed that the vibration feeder 5 is connected to the ground voltage and the collecting electrode 11 is connected to a positive voltage. Then, out of the abrasion powders 2c and 2d mixed in the resin pieces 2a and 2b conveyed between the vibration feeder 5 and the collecting electrode 11, the abrasion powder 2d charged to minus (−) is caused by the Coulomb force. It is attracted to the collection electrode 11 side and adheres to the collection electrode 11. On the other hand, when collecting the wear powder 2c charged positively (+), the wear powder 2 can be attached to the collecting electrode 11 by connecting the collecting electrode 11 to a negative voltage.

  According to the electrostatic sorting device 1 described above, it is possible to collect the wear powders 2c and 2d generated and charged when the resin pieces 2a and 2b are stirred by the collecting electrode 11. Thereby, it can suppress that the charged abrasion powder adheres to the electrode 7a or the electrode 7b. As a result, the electrostatic field is weakened or the discharge between the electrodes 7a and 7b is prevented, the resin pieces 2a and 2b to be sorted are reliably sorted, and a predetermined collection container 10 (10a, 10b, 10c).

  In addition, in the electrostatic sorting apparatus mentioned above, the case where the collection electrode 11 connected to the positive voltage or the negative voltage was provided was demonstrated. As the collection electrode 11, as shown in FIG. 6, a collection electrode 11 a connected to a positive voltage and a collection electrode 11 b connected to a negative voltage may be arranged in parallel. In this case, the wear powder 2d charged to plus (+) is attached to the collecting electrode 11b, and the wear powder 2c charged to minus (−) is attached to the collecting electrode 11a. Both wear powder 2c and 2d with wear powder 2d can be collected. In addition, the arrow shown by FIG. 6 shows the flow of the resin pieces 2a and 2b.

  In the electrostatic sorting apparatus 1, the size of the vibration feeder 5 and the collection electrode 11 connected to a predetermined voltage is adjusted to set a larger area where an electrostatic field is generated. By using a structure that moves longer in the electric field and a structure in which a plurality of collecting electrodes connected to the same voltage are arranged, the amount of wear powder removed can be further increased.

  Furthermore, the greatest feature of the electrostatic sorting apparatus 1 described above is that the size of the abrasion powder to be removed can be changed by controlling the voltage applied to the collecting electrode 11. The voltage to be applied is determined by the specific gravity of the wear powder to be removed or the charge amount. For example, assuming the case of ABS resin or PS resin, the wear powder to be removed is a wear powder having a size (diameter) of about 30 μm. Then, when frictionally charged until the wear powder is saturated, the wear powder can be removed by applying a voltage of 3000 V / m or more to the collecting electrode 11.

  The method of collecting the wear powder by the collecting electrode can selectively remove the wear powder mixed in the resin piece as compared with general air suction such as a vacuum cleaner. That is, in the air suction, if the air suction amount that can reliably remove the abrasion powder is used, even the resin piece of the size to be collected is sucked. In comparison, the wear powder can be selectively removed.

Modified Example The wear powder collected on the collecting electrode is removed to prevent the electrostatic field formed between the vibration feeder 5 and the collecting electrode 11 from being weakened. There is a need to. Here, an example of an electrostatic sorting device having a function of removing wear powder collected by the collecting electrode will be described.

  As shown in FIG. 7, the collecting electrode 11 of the electrostatic sorting apparatus 1 is provided with a rotating shaft 12, and an air nozzle 22 is disposed above the collecting electrode 11. Since the configuration other than this is substantially the same as the configuration of the electrostatic sorting apparatus shown in FIG. 1, the same members are denoted by the same reference numerals and the description thereof will not be repeated.

  Next, the operation of the electrostatic sorting device 1 described above will be described. The charged abrasion powders 2c and 2d generated when the resin pieces 2a and 2b are agitated are transported between the vibration feeder 5 and the collecting electrode 11 together with the resin pieces 2a and 2b. As described above, the minus (−) charged abrasion powder 2d adheres to the side (first side surface portion) facing the vibration feeder 5 in the collecting electrode 11 by Coulomb force.

  Next, the collecting electrode 11 is rotated by 180 ° around the rotating shaft 12, and the first side surface portion to which the wear powder 2 d is attached is disposed on the side opposite to the side facing the vibration feeder 5. Next, the wear powder 2d is removed by sucking the wear powder 2d adhering to the first side surface portion by the air nozzle 22. While the wear powder 2d adhering to the first side surface portion is being removed, the side facing the vibration feeder 5 (second side surface portion) of the collecting electrode 11 is newly worn by Coulomb force. Powder 2d will adhere.

  After the abrasion powder 2d adhering to the first side surface portion is removed, the collecting electrode 11 is further rotated by 180 ° around the rotation shaft 12, and the first side surface portion from which the abrasion powder 2d is removed is While arrange | positioning on the side facing the vibration feeder 5, the 2nd side part to which the abrasion powder 2d adhered newly is arrange | positioned on the opposite side to the side facing the vibration feeder 5. FIG. Thereafter, the attachment and removal of the above-mentioned wear powder 2d are alternately repeated on each of the first side surface portion and the second side surface portion of the collecting electrode 11. In addition, when collecting the abrasion powder 2c charged positively (+), the electrode 11 for collection is connected to a negative voltage, and adhesion and removal may be repeated similarly to the case of the abrasion powder 2d.

  According to the electrostatic sorting device 1 described above, the abrasion powder 2d (2c) can be continuously removed without repeating the electrostatic field by repeatedly attaching and removing the abrasion powder 2d (2c). it can.

  The operation for rotating the collecting electrode 11 includes a continuous operation and an intermittent operation, but the effect of removing the abrasion powder varies depending on the relationship between the shape of the electrode and the state of the electrostatic field. Become. In a flat plate-shaped collecting electrode that can easily form a flat electrostatic field, it is preferable to rotate the collecting electrode intermittently. On the other hand, it is preferable that the collecting electrode is continuously rotated in a curved collecting electrode whose electrostatic field is unlikely to change even when rotating. Thereby, the removal operation | work of abrasion powder can be performed continuously and the collection | recovery of a resin piece can be performed efficiently, without stopping a selection operation | work.

  Further, as a method of removing the wear powders 2c and 2d by the air nozzle 22, there is a method of using a suction nozzle as the air nozzle and sucking and removing the wear powder while scanning the surface of the collecting electrode. In addition, there is a method in which an air blow nozzle and a suction nozzle are used as air nozzles, and wear powder adhering to the collecting electrode is blown off by the air blow nozzle, and the blown-off wear powder is sucked and removed by the suction nozzle.

  In particular, when the abrasion powder is blown off by the air blow nozzle, it is preferable to provide the cover 13 so that the air discharged from the air blow nozzle does not flow outside as shown in FIG. Further, a receiving part (not shown) for receiving the wear powder may be arranged so that the blown-off wear powder does not fall on the collecting electrode 11 again. By doing so, the effect of removing wear powder can be further enhanced.

  Furthermore, although the collecting electrode 11 connected to one of the positive voltage and the negative voltage is taken as an example of the collecting electrode of the electrostatic sorting device 1 described above, the collecting electrode 11 is connected to the collecting electrode 11. The voltage to be switched may be switched between a positive voltage and a negative voltage. For example, as shown in FIG. 10, a collecting electrode 11 is assumed in which an electrode plate 11a and an electrode plate 11b made of a conductive material are opposed to each other with an insulating material 11c interposed therebetween.

  Then, first, the negatively charged wear powder 2d adheres by connecting a positive voltage to the electrode plate 11b facing the vibration feeder 5 (see FIG. 9). Next, as shown in FIG. 11, the collection electrode 11 is rotated 180 ° so that the electrode plate 11 b faces the air nozzle 22. Next, the voltage connected to the electrode plate 11b is switched from a positive voltage to a negative voltage or no voltage. By switching the voltage, the Coulomb force acting between the wear powder 2d and the electrode plate 11b is weakened, and the wear powder 2d is easily sucked by the air nozzle 22.

  By repeating this operation, the effect of removing the wear powder 2d can be maintained for a longer time. In addition, what is necessary is just to reverse a voltage, when attracting the abrasion powder 2c electrically charged to plus.

  In addition to this, in order to make it easy to remove the wear powder, there is a method of electrically neutralizing the charge of the wear powder by means of static elimination blow. In addition, a method of electrically neutralizing by increasing the humidity around the wear powder to easily release the charge of the wear powder is also effective. Such a technique can also be applied to an electrostatic sorting device described later.

Embodiment 2
An electrostatic sorting apparatus according to Embodiment 2 of the present invention will be described. As shown in FIG. 12, in the electrostatic sorting device 1, a mesh electrode 21 is disposed as a collecting electrode. In addition, since it is substantially the same as that of the electrostatic sorting apparatus 1 shown in FIG. 1 about the structure other than this, the same code | symbol is attached | subjected to the same member and the description is not repeated.

  Next, the operation of the electrostatic sorting device 1 described above will be described. As shown in FIG. 12, the abrasion powders 2c and 2d that are generated and charged when the resin pieces 2a and 2b are stirred are transported between the vibration feeder 5 and the mesh electrode 21 together with the resin pieces 2a and 2b. As shown in FIG. 13, in the meantime, the abrasion powder 2d charged to minus (−) is attracted to the mesh electrode 21 connected to the positive voltage by Coulomb force.

  By sucking air using the air nozzle 22 disposed on the mesh electrode 21 as a suction nozzle, the wear powder 2d attracted to the mesh electrode 21 passes through the mesh electrode 21 and is sucked by the air nozzle 22. Removed. In addition, what is necessary is just to connect the mesh electrode 21 to a negative voltage, when removing the abrasion powder 2c. After the abrasion powders 2c and 2d are removed, the resin pieces 2a and 2b are separated from the static electricity for separation formed between the high voltage electrode 7a and the ground electrode 7b in the same manner as described for the electrostatic sorting device described above. It is collected in a predetermined collection container 10 by the electric field.

  In the electrostatic sorting apparatus 1 described above, the mesh electrode 21 is disposed as a collecting electrode. Accordingly, the wear powder attracted to the mesh electrode 21 or the wear powder attached to the mesh electrode 21 is sucked by the air nozzle 22 through the mesh electrode without providing a mechanism for rotating the collection electrode. Can be removed. Thus, by removing the abrasion powder, the electrostatic field for separation formed between the high voltage electrode 7a and the ground electrode 7b is stabilized, and the resin pieces 2a and 2b can be reliably recovered in the predetermined recovery container 10. it can.

Embodiment 3
An electrostatic sorting apparatus according to Embodiment 3 of the present invention will be described. As shown in FIG. 14, in the electrostatic sorting device 1, a polygonal columnar electrode 31 is arranged as a collecting electrode. In addition, since it is substantially the same as that of the electrostatic sorting apparatus 1 shown in FIG. 1 about the structure other than this, the same code | symbol is attached | subjected to the same member and the description is not repeated.

  Next, the operation of the electrostatic sorting device 1 described above will be described. As shown in FIG. 14, the charged abrasion powders 2 c and 2 d generated when the resin pieces 2 a and 2 b are stirred are conveyed between the vibration feeder 5 and the polygonal columnar electrode 31 together with the resin pieces 2 a and 2 b. As shown in FIG. 15, in the meantime, the minus (−) charged abrasion powder 2d is attracted to the polygonal columnar electrode 31 connected to the positive voltage by Coulomb force.

  At this time, by rotating the polygonal columnar electrode 31 around the rotation axis 12, the wear powder 2d is sequentially attached to each side surface of the polygonal columnar electrode 31, and the wear powder 2d is continuously removed. In addition, what is necessary is just to connect a negative voltage to each side part of the polygonal columnar electrode 31 when removing the abrasion powder 2c. After the abrasion powders 2c and 2d are removed, the resin pieces 2a and 2b are separated from the static electricity for separation formed between the high voltage electrode 7a and the ground electrode 7b in the same manner as described for the electrostatic sorting device described above. It is collected in a predetermined collection container 10 by the electric field.

  In the electrostatic sorting device 1 described above, a polygonal columnar electrode 31 is disposed as a collecting electrode. By rotating the polygonal columnar electrode 31, the abrasion powders 2 d and 2 c can be sequentially attached to the side portions of the polygonal columnar electrode 31, and the abrasion powders 2 d and 2 c can be continuously removed.

  Further, it is preferable that the side surfaces of the polygonal columnar electrode 31 are electrically separated from each other so that a voltage can be individually applied to each side surface. By doing so, when the abrasion powder 2d (2c) adhering to the side surface portion is removed by an air nozzle (not shown), the Coulomb force acting between the abrasion powder 2d (2c) and the side surface portion is weakened. By applying a predetermined voltage to the side surface, wear powder 2d (2c) adhering to the side surface can be efficiently removed as described in the modification of the first embodiment. Thus, by removing the abrasion powder, the electrostatic field for separation formed between the high voltage electrode 7a and the ground electrode 7b is stabilized, and the resin pieces 2a and 2b are reliably recovered in the predetermined recovery container 10. Can do.

  In each of the above-described embodiments, the ABS resin and the PS resin have been described as examples of the resin to be selectively collected. Resins are not limited to these resins, and other resins that can be charged can be applied according to their charging characteristics. Further, the present invention is not limited to resin, and can also be applied to selecting materials that can be charged such as rubber.

  Further, in each of the above-described embodiments, the case where the vibration feeder 5 and the collection electrode 11 are arranged in the vertical direction as a pair of second counter electrodes has been described as an example, but the wear powder is removed. The arrangement is not limited to the vertical direction.

  The embodiment disclosed this time is an example, and the present invention is not limited to this. The present invention is defined by the terms of the claims, rather than the scope described above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  The present invention is effectively used in a technology for recycling a resin.

  DESCRIPTION OF SYMBOLS 1 Electrostatic sorting device, 2a, 2b Resin piece, 2c, 2d Wear powder, 3 Charging container, 5 Vibrating feeder, 7 Pair of electrodes, 7a High voltage electrode, 7b Ground electrode, 10, 10a, 10b, 10c Collection container 11 Electrode for collection, 11a Electrode plate, 11b Electrode plate, 11c Insulating material, 12 Rotating shaft, 13 Cover, 21 Mesh electrode, 22 Air nozzle, 31 Polygonal columnar electrode.

Claims (8)

An electrostatic sorting device that charges a resin piece and sorts and collects the material by a predetermined electrostatic field while conveying the charged resin piece,
A charging unit for charging the resin piece;
A sorting unit that is provided downstream of the charging unit in the transport direction and includes a pair of first counter electrodes that sort the resin pieces by generating the predetermined electrostatic field;
Another predetermined electrostatic field is arranged at a position in the direction intersecting the transport direction so as to sandwich the transported resin piece at a position in the middle of transporting the resin piece from the charging unit to the sorting unit. An electrostatic sorting device comprising a pair of second counter electrodes for generating The pair of second counter electrodes includes one electrode and the other electrode that are spaced apart from each other,
The electrostatic sorting apparatus according to claim 1, wherein the one electrode and the other electrode are arranged in parallel. In the one electrode, a first side surface portion and a second side surface portion facing each other are provided,
The one electrode is rotatably arranged such that each of the first side surface portion and the second side surface portion faces the other electrode,
The electrostatic sorting apparatus according to claim 2, wherein an air suction part is disposed on a side opposite to the side on which the other electrode is disposed with respect to the one electrode. In the one electrode, voltage can be individually applied to each of the first side surface portion and the second side surface portion,
In the first side surface portion and the second side surface portion,
In a state facing the other electrode, a predetermined voltage that generates the other predetermined electrostatic field is applied,
The electrostatic sorting device according to claim 3, wherein another predetermined voltage different from the predetermined voltage is applied in a state of facing the air suction unit. The pair of second counter electrodes includes one electrode and the other electrode that are spaced apart from each other,
The one electrode has a mesh structure;
The electrostatic sorting apparatus according to claim 1, wherein an air suction part is disposed on a side opposite to the side on which the other electrode is disposed with respect to the one electrode. The pair of second counter electrodes includes one electrode and the other electrode that are spaced apart from each other,
The one electrode has a polygonal columnar structure,
The one electrode is rotatably arranged such that each side surface portion of the polygonal columnar structure faces the other electrode,
The electrostatic sorting apparatus according to claim 1, wherein an air suction part is disposed on a side opposite to the side on which the other electrode is disposed with respect to the one electrode. In the one electrode, voltage can be individually applied to each side surface of the polygonal columnar structure,
In each said side part,
In a state facing the other electrode, a predetermined voltage that generates the other predetermined electrostatic field is applied,
The electrostatic sorting device according to claim 6, wherein another predetermined voltage different from the predetermined voltage is applied in a state of facing the air suction unit.   The electrostatic sorting apparatus according to any one of claims 1 to 7, wherein the pair of second counter electrodes are arranged in the vertical direction with the gap therebetween.

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