KR101659409B1 - Apparatus for separating complex waste and separation method of complex waste - Google Patents

Abstract

A composite waste separation apparatus and a separation method are disclosed. An apparatus for separating a composite waste from a synthetic resin capable of being regenerated and foreign matter other than the synthetic resin, comprising: a primary crusher for first crushing the composite waste; A front separator for separating the primary pulverized composite waste into recycled resin and a first foreign matter through blowing air, using a difference in air blowing intensity and a difference in weight between the recycled resin and the first foreign matter; A first dust collecting part for collecting the first foreign substance separated by the front separating part; A secondary pulverizing unit for secondary pulverizing the regenerated resin separated by the front separating unit; At least one rear separator for separating the regenerated resin and the second foreign matter from the secondary pulverized regenerated resin by blowing air using the difference between the blowing intensity and the weight difference between the regenerated resin and the second foreign matter; And a second dust collecting part for collecting the second foreign object separated by the rear separating part.

Description

Technical Field [0001] The present invention relates to a composite waste separation apparatus and a separation method therefor,

The present invention relates to a composite waste separation apparatus and a separation method, and more particularly, to a composite waste separation apparatus and a separation method which separate a recyclable synthetic resin (hereinafter referred to as "recycled resin") mixed with a composite waste and foreign matters such as paper, The present invention relates to a composite waste separation apparatus and a separation method capable of separating a composite waste without using a separate water treatment process and improving the separation rate compared to the conventional method.

Generally, the technology for separating vinyl and papermaking fibers of pulp-coated paper, which is used as one of the prior art, is continuously supplied from the pretreatment process, and separating the papermaking fibers and vinyl (PVC, etc.) by blowing and separating them, A technique of dropping the papermaking fibers into the bottom is used.

However, this technology segregates and separates papermaking fibers attached to vinyl through washing water, which causes excessive waste water to cause pollution of water quality. Therefore, there is a problem that an additional facility such as a wastewater treatment facility for purifying the generated wastewater is required.

In addition, as another separation technique, separation technology using a chemical agent has been applied. However, in order to reduce environmental pollution such as wastewater generated in the separation process, there is an environmental problem that requires the use of another chemical And the separation rate is not high.

Korean Registered Patent No. 10-1113973 (registered on February 21, 2012)

An object of the present invention is to provide a composite waste separation apparatus capable of separating a recycled resin mixed with a composite waste and foreign matter such as paper and separating the composite waste without a separate water treatment process using a dry processing technique, And a separation method.

According to an aspect of the present invention, there is provided an apparatus for separating a composite waste from a recycled resin and a foreign matter other than the recycled resin, the apparatus comprising: a primary crusher for first crushing the composite waste; A front separator for separating the primary pulverized composite waste into recycled resin and a first foreign matter through blowing air, using a difference in air blowing intensity and a difference in weight between the recycled resin and the first foreign matter; A first dust collecting part for collecting the first foreign substance separated by the front separating part; A secondary pulverizing unit for secondary pulverizing the regenerated resin separated by the front separating unit; At least one rear separator for separating the regenerated resin and the second foreign matter from the secondary pulverized regenerated resin by blowing air using the difference between the blowing intensity and the weight difference between the regenerated resin and the second foreign matter; And a second dust collecting part for collecting the second foreign matter separated by the rear separating part.

According to another aspect of the present invention, there is provided a method of separating a composite waste from a recycled resin and a foreign material other than the recycled resin, comprising the steps of: (a) separating the composite waste from the primary recycled resin into a recycled resin and a first foreign matter, A first separating step of separating the recycled resin and the first foreign substance by using a difference in strength between the strength and the regenerated resin; (b) a second pulverizing step of secondly pulverizing the recycled resin separated through the first separating step; And (c) a second separation step of separating the second foreign matter from the second-order recycled resin by blowing air using the difference between the blowing intensity and the weight difference between the recycled resin and the second foreign matter, A separation method can be provided.

According to the present invention, foreign matter such as paper is separated from the recycled resin through a total three-step separation process through the front separator, the rear separator, and the vibration separator, and is regenerated at a very high separation rate So that the resin can be separated.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a schematic view showing a composite waste separation apparatus according to an embodiment of the present invention.
2 is a view showing a front separator and a rear separator of the composite waste separation apparatus according to the first embodiment of the present invention.
3 is a view showing a front separator of the composite waste separation apparatus according to the second embodiment of the present invention.
Fig. 4 is a plan view of Fig. 3. Fig.
5 is a view showing a front separation unit of the composite waste separation apparatus according to the third embodiment of the present invention.
6 is a view showing a front separation unit of a composite waste separation apparatus according to a fourth embodiment of the present invention.
7 is a view showing a front separation unit of the composite waste separation apparatus according to the fifth embodiment of the present invention.
Fig. 8 is a plan view of Fig. 7. Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Wherein like reference numerals refer to like elements throughout.

The composite waste separation apparatus according to the preferred embodiment of the present invention separates the recycled resin (for example, regenerated PVC) from the waste synthetic resin through the dry method and the foreign matter (for example, nonwoven fabric, paper, etc.) The separation efficiency can be further improved while preventing environmental pollution by use of the washing water. In this embodiment, the regenerated water separated from the waste synthetic resin can be recycled, and the separated foreign materials can also be used for recycling and the like.

That is, the composite waste used throughout the present application means that a foreign material such as paper or nonwoven fabric is bonded to a reproducible synthetic resin, and the foreign materials such as synthetic resin, paper, and nonwoven fabric separated according to the present invention are all recycled .

Hereinafter, the present invention will be described with reference to various embodiments, and repetitive description of the same configuration will be omitted.

FIG. 1 is a schematic view showing a composite waste separation apparatus according to an embodiment of the present invention, and FIG. 2 is a view showing a front separation unit and a rear separation unit of the composite waste separation apparatus according to the first embodiment of the present invention.

1, the composite waste separation apparatus according to the first embodiment of the present invention (hereinafter, referred to as a "separation apparatus") is a system for regenerating composite waste for other purposes, (100) for firstly crushing a composite waste, a first crushing unit (100) for separating the composite crushing waste into a recycled resin and a first foreign matter through blowing air, the first crushing unit A front separator 110 for separating the regenerated resin crushed by the crushing unit 100 by using a weight difference between the regenerated resin crushed by the crushing unit 100 and the first foreign matter, A secondary pulverizing unit 140 for secondary pulverizing the regenerated resin separated by the front separating unit 110, and a regeneration resin and a second foreign material are separated from the regenerated secondary pulverized resin by blowing air, , The blowing intensity and the regenerated resin pulverized by the secondary crushing part (140) and the second foreign matter At least one rear separating part 150 for separating using a weight difference between the first and second separating parts 150 and 150 and a second dust collecting part 160 for collecting the second foreign material separated by the rear separating part 150.

The separating apparatus according to the first embodiment of the present invention further includes a vibration separating unit 170 for separating the third foreign matter from the regenerated resin separated by the rear separating unit 150 through vibration imparting, And a third dust collecting part 180 for collecting the third foreign matter separated by the first dust collecting part 170.

That is, according to the present invention, foreign matter is separated from the recycled resin through the total of three steps through the front separator 110, the rear separator 150, and the vibration separator 170. Finally, The recycled resin can be separated at a high separation rate as compared with the conventional method.

First, the primary crushing section 100 includes a shearing machine and a crusher, and the shearing machine cuts, for example, the composite waste, and the crusher receives the composite waste cut at the shearing machine, And cut to have a length smaller than the length.

Next, the front separator 110 receives the pulverized composite waste from the primary pulverizer 100 and separates the recovered resin and the first foreign material. The waste synthetic resin pulverized from the primary crushing unit 100 may be transferred to the front separating unit 110 through a manual supply system by an operator or an automatic supply system through a separate supply pipe or the like.

Here, the front separator 110 separates the primary pulverized composite waste into recycled resin and a first foreign matter through blowing air, and separates the mixed waste using the difference in weight between the pulverized recycled resin and the first foreign matter .

2, the front separating section 110 includes a separating tank 111 for providing a space to which the regenerated resin is supplied, a blowing fan 111 for blowing air to the upper region in the inner lower region of the separating tank 111, A suction induction pipe 113 provided in the form of a venturi pipe inside the separation tank and a suction induction pipe 113 communicating with the suction induction pipe 113 in the upper region of the separation tank 111 to pass through the suction induction pipe 113 A foreign matter discharge pipe 115 for discharging separated foreign substances and a regenerated resin discharge pipe 116 for discharging the regenerated resin separated at the lower part of the separating tank 111. [

The waste synthetic resin supply pipe 125 is provided in the separation tank 111 so that the pulverized synthetic resin is supplied from the primary crushing unit 100 and the waste synthetic resin supply pipe 125 is selectively blocked A first valve 126 is provided.

Similarly, the foreign matter discharge pipe 115 is provided with a second valve 128 for selectively blocking the discharge of foreign matter, and the regenerated resin discharge pipe 116 is provided with a third valve 127 for selectively blocking the discharge of the regenerated resin, . Here, the foreign matter discharge pipe 115 is connected to the primary dust collecting unit 130 side, and the recycled resin discharge pipe 116 is connected to the secondary crushing unit 140 side.

As described above, the pulverized waste synthetic resin is supplied to the inside of the separation tank 111 through the waste synthetic resin supply pipe 125 and then diffused and moved in the separation tank 111 by the wind pressure through the blower 112 have. Alternatively, the pulverized waste synthetic resin may be supplied to the blowing pipe connecting the blower 112 and the separating tank 111, and then supplied into the separating tank 111 by the wind pressure.

Hereinafter, the process of supporting the regenerated water separated from the waste synthetic resin and discharging the first foreign matter will be described as follows.

First, when the composite waste is supplied into the separation tank 111 and then the separated first foreign matter is discharged through the foreign matter discharge pipe 115, the control unit turns off the opening of the third valve 127, The second valve 128 is opened. In this state, the first foreign matter separated by the wind pressure and the difference in weight between the pulverized recycled resin and the first foreign matter can be discharged to the foreign matter discharge pipe 115 side by wind pressure.

On the other hand, when it is intended to discharge the regenerated resin separated by the difference between the wind pressure, the pulverized regenerated resin and the first foreign matter, the control unit turns off the opening of the second valve 128, Lt; / RTI > In this state, the regenerated water accumulated on the bottom of the separation tank 111 can be discharged to the regenerated resin discharge pipe 116 side by the wind pressure. Thus, the regenerated water in the separated state discharged to the regenerated resin discharge pipe 116 is supplied to the secondary crushing unit 140 side through an automatic transfer system by an operator or an automatic transfer apparatus by an operator.

First, the primary pulverized waste synthetic resin is transferred to the inside of the separation tank through a separate waste synthetic resin supply pipe 125, or is discharged to the outside through the blower 112. [ And may be transferred to the inside of the separation tank 111 by the wind pressure through the blower 112 after being supplied to the blowing pipe connecting the separation tank 111 and the blowing pipe.

A foreign matter discharge pipe 115 is formed in the upper part of the separation tank 111 to form a foreign matter discharge path so as to transfer a foreign matter (first foreign matter) separated from the primary pulverized waste synthetic resin to the first dust collecting part 130 do. In addition, a regenerated resin discharge pipe 116 for discharging regenerated resin separated from the primary pulverized waste synthetic resin is provided in the lower portion of the separation tank 111. The regenerated water discharged through the regenerated resin discharge pipe 116 may be supplied to the secondary crushing unit 140 side through the above-described method.

Next, the blower 112 supplies air to the upper region from the lower inner region of the separation tank 111, and at this time, the primary pulverized waste synthetic resin can be simultaneously introduced into the separation tank 111 side together with the air through the air blowing .

In the first embodiment of the present invention, as shown in FIG. 2, a suction induction pipe 113 is provided in the interior of the separation tank 111 in the form of a venturi tube. Specifically, the suction induction pipe 113 is formed such that its diameter decreases gradually from the lower end facing the lower side of the separation tank 111 to the upper end adjacent to the foreign matter discharge pipe 115. Accordingly, the first foreign material moved to the area close to the initial inlet (lower end) of the suction induction pipe 113 passes through the suction induction pipe 113, and the flow rate increases, so that the foreign matter can be discharged to the foreign matter discharge pipe 115 more quickly.

In this case, the waste synthetic resin is separated into the recycled resin and the first foreign matter. In this case, the waste synthetic resin introduced into the separating tank 111 with a certain blowing intensity (wind pressure) And the first foreign matter is relatively lighter due to the difference in weight between the recycled resin and the first foreign matter (for example, paper), and moves upward from the inside of the separation tank 111 .

Meanwhile, in the present embodiment, the front separator 110 further includes a control unit (not shown) for controlling the blowing intensity of the blower 112. The controller controls the blowing intensity of the blower 112 according to the particle size of the foreign matter to be discharged to the dust collector (first dust collector).

For example, when the particle size of the first foreign substance to be discharged is relatively small, the control unit further reduces the blowing intensity of the blower 112. On the contrary, when the particle size of the first foreign substance to be discharged is relatively large, The blowing intensity of the blower 112 can be further increased.

In other words, in this embodiment, the regenerated resin and the first foreign matter can be more efficiently separated from the waste synthetic resin by using the wind pressure by the blower 112 and the weight difference between the regenerated resin and foreign matter separated.

2, a meshed mesh 114 is further provided on the inside of the suction induction pipe 113 so as to selectively filter the first foreign matter according to the particle size of the first foreign matter It is possible.

The first foreign matter smaller than the mesh size is discharged to the foreign matter discharge pipe 115 through the mesh net 114. The first foreign matter having a size larger than the mesh size is discharged to the outside through the mesh net 114, And may be discharged to the regenerated resin discharge pipe 116 side together with the regenerated resin or discharged to the foreign matter discharge pipe 115 after the particulate size is further reduced by the wind pressure. That is, the mesh network 114 may be a kind of separator that can discharge only the first foreign matter less than a certain particle size.

In addition, in the present embodiment, the front separating unit 110 is configured to apply a rotational force to the composite waste supplied into the separating tank 111, thereby causing a phenomenon that the separated regenerated resin and the first foreign substance cohere to each other. And a rotation unit 117 capable of reducing the rotation speed.

The rotary part 117 provides a centrifugal force to the composite waste in addition to the wind pressure by the blower 112 to assist the regeneration resin and the first foreign matter to be easily separated from each other due to the weight difference without being agglomerated.

The rotating portion 117 includes a driving motor 118 and at least one rotating blades 119 provided on a driving shaft of the driving motor 118. The plurality of rotary vanes 119 may be spaced apart from each other along the longitudinal direction of the drive shaft.

As shown in FIG. 2, the front separator 110 may further include a vibrating part 121 for imparting vibration to the separating tank 111.

The vibrating motor 121 may be a vibration motor of a kind provided as a plurality of vibrating motors at a lower portion of the separating tank 111 and may be attached to the inner wall surface of the separating tank 111, The regenerated resin can be lowered downward.

Next, the first dust collecting part 130 collects the first foreign matter discharged through the front separating part 110, in particular, the foreign matter discharge pipe 115. The first dust collecting part 130 may include a first foreign matter storage tank (not shown) for providing a space for storing the first foreign matter.

Next, the secondary crushing unit 140 secondarily crushes the recycled resin discharged through the front separator 110, that is, the recycled resin discharge pipe 116. In addition, the secondary crushing unit 140 re-crushes the recycled resin discharged from the front separator 110, and the crushed length of the secondary crushing unit 140 is smaller than the crushing length of the primary crushing unit 100.

Thus, the regenerated water further crushed by the secondary crushing unit 140 can be supplied to the rear separating unit 150 side automatically and continuously through the conveying means such as a belt conveyor. In addition, And may be transferred to the separator 150 side.

Next, as shown in Figs. 1 and 2, the rear separating portion 150 is firstly separated from the first foreign matter by the front separating portion 110, and is again pulverized by the secondary crushing portion 140 The regenerated resin is supplied and the second foreign matter is separated therefrom. The rear separating unit 150 may have the same structure as the forward separating unit 110 or may have different structures such as an inner structure of the separating tank 111, a regenerated resin, and a foreign matter discharging structure.

The following description will be made on the basis of the case where the rear separating part 150 has the same structure as the front separating part 110. [

The rear separating unit 150 includes a separating tank 111 for providing a space for supplying regenerated resin, a blower 112 for supplying air to the upper region in an inner lower region of the separating tank 111, A suction pipe 113 provided in the form of a venturi tube and connected to the suction induction pipe 113 in an upper region of the separation tank 111 to discharge a foreign matter separated while passing through the suction induction pipe 113, A discharge pipe 115 and a regenerated resin discharge pipe 116 provided to discharge the regenerated resin separated at the lower part of the separating tank 111.

In the present embodiment, the second foreign matter separation process in the rear separation unit 150 is the same as the separation process of the front separation unit 110, and a detailed description of the separation process will be omitted.

1, the rear separating unit 150 can be performed a plurality of times at a plurality of places simultaneously or after a predetermined time interval after receiving the regenerated resin that has been regenerated from the front separating unit 110 . Although the rear separation unit 150 is described as two rows in the drawing, the rear separation unit 150 is shown as being capable of performing the second separation process at two places or devices, but the present invention is not limited thereto, The unit 150 may be provided in three or more.

Next, the second dust collecting unit 160 collects the second foreign substances discharged through the rear separating unit 150, particularly, the foreign matter discharge pipe 115. The second dust collecting unit 160 may include a second foreign matter storage tank (not shown) for providing a storage space for storing the second foreign matter.

Next, the vibration separating section 170 separates the recycled resin separated by the rear separating section 150, specifically, the recycled resin discharged through the recycled resin discharge pipe 116 of the rear separating section 150, Thereby separating foreign matter. The vibrating separator 170 includes a vibrating screen (not shown) having a mesh of a predetermined size and a vibrating motor (not shown) for vibrating the vibrating screen (not shown).

The regenerated water discharged from the rear separator 150 is supplied to the upper side of the vibration screen and the third foreign matter having a particle size smaller than that of the vibration screen net by the vibration motor is dropped below the vibration screen. Thus, the third foreign matter filtered by the vibration screen is discharged through a separate conveying pipe.

1, the third dust collecting unit 180 collects third foreign substances separated by the vibration separating unit 170, and is provided with a third foreign substance conveying path of the third foreign substances filtered by the vibration screen, A foreign matter discharge pipe (not shown), and a third foreign matter storage tank (not shown) in which the third foreign matter is stored. Here, the third foreign matter discharge pipe may be further provided with a separate blowing fan for providing the conveying pressure of the third foreign matter.

On the other hand, the regenerated water filtered by the vibration separator 170 can be moved to a place for packaging a product (recycled resin) through a belt conveyor, a screw conveyor, or the like.

FIG. 3 is a view showing a front separator of a composite waste separation apparatus according to a second embodiment of the present invention, and FIG. 4 is a plan view of FIG.

Hereinafter, a composite waste separation apparatus according to a second embodiment of the present invention will be described.

Prior to the description, repetitive description of the same configuration as that of the first embodiment will be omitted, and the same reference numerals as those in the first embodiment will be used.

In the separating apparatus according to the second embodiment of the present invention, the front separating unit and the rear separating unit may have the same structure or may have different structures.

Hereinafter, the front separator and the rear separator will be described with reference to the same structure, and the forward separator will be described as an example for convenience of explanation.

3, in the separating apparatus according to the second embodiment of the present invention, the front separating unit 210 includes a separating tank 211 for providing a space for supplying regenerated resin, A spiral guide 213 which continuously protrudes spirally from the inner circumferential surface of the separation tank 211 to guide the movement of the regenerated resin, the foreign matter and the air, A foreign matter discharge pipe 215 provided in the upper region of the tank 211 for discharging foreign matter separated by the spiral guide 213 and a regenerated resin discharge pipe 215 for discharging the regenerated resin separated at the lower portion of the separating tank 211 216).

First, the separation tank 211 is a chamber having an internal accommodation space. The primary pulverized waste synthetic resin is transferred to the inside of the separation tank through the waste synthetic resin supply pipe 225, or is transferred to the separation tank 211).

The first foreign matter separated from the primary pulverized waste synthetic resin, that is, the first foreign matter separated by the spiral guide 213, which will be described later, is transferred to the first dust collecting part 130 side at the upper part of the separation tank 211 A foreign matter discharge pipe 215 for forming a foreign matter discharge path is provided. In addition, a regenerated resin discharge pipe 216 for discharging regenerated resin separated from the primary pulverized waste synthetic resin is provided in the lower part of the separation tank 211. The control procedure for discharging the regenerated resin and the first foreign matter is the same as in the first embodiment.

Next, as shown in FIG. 4, the blower 212 supplies air to the inside of the separation tank 211 in a substantially tangential direction to the inner circumferential surface of the separation tank 211. That is, the air eccentrically supplied to the inside of the separation tank 211 by the blower 212 is rotatably movable inside the separation tank 211 as described above. At this time, the primary pulverized waste synthetic resin can be introduced into the separating tank 211 while simultaneously rotating with the air through the air blowing.

In the second embodiment of the present invention, as shown in Figs. 3 and 4, a spiral guide 213 is provided inside the separation tank 211. Fig. The spiral guide 213 continuously protrudes spirally from the inner circumferential surface of the separation tank 211 to guide the movement of the regenerated resin, the first foreign matter and the air.

The spiral guide 213 is inclined downward toward the center of the separating tank 211 and has a first bent portion 214 bent downward at an end thereof. In addition, a second bending portion 222 is provided at the connection portion of the separating tank 211 connected to the dust collector (particularly, the foreign matter discharge pipe) to be bent outwardly.

In this structure, the waste synthetic resin introduced into the separation tank 211 through the blower 212 is swirled upward along the spiral guide 213 along with the air, and during this swirling movement, The waste synthetic resin can be separated into the recycled resin and the first foreign matter due to the difference in weight between the recycled resin and the first foreign matter, and the centrifugal force due to the spiral rotation.

Further, while the regenerated resin and the first foreign material are pivotally moved upward along the helical guide 213, the regenerated water having a relatively heavy particle weight is lowered downward while the relatively light first foreign matter is guided along the helical guide 213 And is exhausted through the foreign matter discharge pipe 215. [0050]

Meanwhile, the second bent portion 222 is provided in the vicinity of the foreign matter discharge pipe 215 to increase the initial entrance area for discharging the foreign matter, so that the foreign matter can be discharged through the foreign matter discharge pipe 215 more easily.

The spiral guide 213 is provided so as to be inclined downward toward the center of the separation tank 211 so that the recycled resin particles moving while rotating along the upper surface of the spiral guide 213 are guided along the inclined surface of the spiral guide 213 So that it can be easily lowered to the bottom surface of the separation tank 211. The regenerated resin particles descending from the helical guide 213 to the bottom surface of the separation tank 211 are prevented from falling to the upper surface side of the helical guide 213 located relatively below by the first bent portion 214 .

5 is a view showing a front separation unit of the composite waste separation apparatus according to the third embodiment of the present invention.

Hereinafter, a composite waste separation apparatus according to a third embodiment of the present invention will be described.

Prior to the description, repetitive description of the same configuration as that of the first embodiment will be omitted, and the same reference numerals as those of the first embodiment will be used.

In the separating apparatus according to the third embodiment of the present invention, the front separating unit and the rear separating unit may have the same structure or may have different structures from each other.

Hereinafter, the front separator and the rear separator will be described with reference to the same structure, and the forward separator will be described as an example for convenience of explanation.

5, in the separating apparatus according to the third embodiment of the present invention, the front separating unit 310 includes a separating tank 311 for providing a space to which regenerated resin is supplied, A blower 312 for supplying air and a separating tank 311. The regeneration resin, the foreign matter and the air move upward from the lower side of the separating tank 311 in the longitudinal direction of the separating tank 311, A foreign matter discharge pipe 315 for discharging foreign matter separated by the flow guide 313 in the upper region of the separation tank 311 and a foreign matter discharge pipe 315 for discharging the foreign matter separated by the flow guide 313 in the upper region of the separation tank 311, And a regenerated resin discharge pipe 316 provided to discharge regenerated resin separated at the bottom.

Firstly, the separation tank 311 is a chamber having an internal accommodation space. The primary pulverized waste synthetic resin is transferred to the inside of the separation tank through a separate waste synthetic resin supply pipe 325, or separated by the wind pressure through the blower 312 And may be transferred to the inside of the tank 311. [

The first foreign matter separated from the primary pulverized waste synthetic resin, that is, the first foreign material separated by the plurality of flow guides 313, is transferred to the first dust collecting part 130 side at the upper part of the separation tank 311 A foreign matter discharge pipe 315 for forming a foreign matter discharge path is provided. In addition, a regenerated resin discharge pipe 316 for discharging regenerated resin separated from the primary pulverized waste synthetic resin is provided in the lower portion of the separation tank 311. The control procedure for discharging the regenerated resin and the first foreign matter is the same as in the first embodiment.

Next, the blower 312 may supply air to the inside of the separating tank 311, for example, in the direction of the inner side of the separating tank 311. However, the blown air may flow along the plurality of flow guides 313 sequentially It is possible to flow in any direction.

In the third embodiment of the present invention, as shown in Fig. 5, a plurality of flow guides 313 are provided inside the separation tank 311. In Fig. The plurality of flow guides 313 are spaced apart from each other along the longitudinal direction of the separating tank 311 so that the flow direction of the regenerated resin, the first foreign matter, and the air in the moving direction Can be switched plural times.

Each of the plurality of flow guides 313 is provided so that one end thereof is in contact with the inner circumferential surface of the separation tank 311 and the other end thereof is spaced apart from the inner circumferential surface of the separation tank 311, Be inclined. In addition, the plurality of flow guides 313 are provided with through holes 314 of different sizes.

Although a plurality of flow guides 313 are shown as being provided in the drawing, the present invention is not limited thereto, and more than two flow guides 313 may be provided. The diameter of the through hole 314 is further reduced toward the flow guide 313 disposed above the through hole 314 formed in the flow guide 313 disposed close to the bottom surface of the separation tank 311 . That is, it is possible to control the particle size of the discharged first foreign matter so that only the first foreign matter having a finer particle size can be discharged.

The waste synthetic resin introduced into the separating tank 311 by the blowing of the blower 312 is fed through the plurality of flow guides 313 to the inside of the separating tank 311, The flow direction is changed a plurality of times. Accordingly, the time for retaining the waste synthetic resin in the separation tank 311 is increased to provide a time (time for providing the separation requirement) in an increased state so that the waste synthetic resin can be separated into the recycled resin and the first foreign matter.

In addition, the waste synthetic resin is separated into the regenerated resin and the first foreign material in the process of gradually moving to the upper region of the separation tank 311, and the regenerated water is separated from the upper surface of the flow guide 313, The first foreign matter may ascend upward along the plurality of flow guides 313 or may ascend via the through holes 314.

On the other hand, when the regenerated resin having a small particle size rises upward along with the first foreign matter by the wind pressure, the regenerated water can hit the bottom surface of the plurality of flow guides 313 and can descend to the bottom, It will be possible to fall through.

That is, since the flow direction is changed a plurality of times by the plurality of flow guides 313 and the through holes 314 are provided, the separation time between the regenerated resin and the first foreign matter can be increased and the separation efficiency can be increased.

6 is a view showing a front separation unit of a composite waste separation apparatus according to a fourth embodiment of the present invention.

Hereinafter, a composite waste separation apparatus according to a fourth embodiment of the present invention will be described.

Prior to the description, repetitive description of the same configuration as that of the first embodiment will be omitted, and the same reference numerals as those of the first embodiment will be used.

In the separating apparatus according to the fourth embodiment of the present invention, the front separating unit and the rear separating unit may have the same structure or may have different structures from each other.

Hereinafter, the front separator and the rear separator will be described with reference to the same structure, and the forward separator will be described as an example for convenience of explanation.

6, in the separating apparatus according to the fourth embodiment of the present invention, the front separating unit 410 includes a separating tank 411 for providing a space for supplying regenerated resin, An air blower 412 for supplying air to the inside of the separating tank 411 and an air blower 412 for separating the separating tank 411 from the separating tank 411, A foreign matter discharge pipe 415 for discharging foreign matter separated by the flow guide 413 in the upper region of the separation tank 411 and a foreign matter discharge pipe 415 for discharging the foreign matter separated by the flow guide 413 and the separation tank 411, And a regenerated resin discharge pipe 416 provided to discharge the regenerated resin separated at the lower portion of the regenerated resin discharge pipe.

Firstly, the separation tank 411 is a chamber having an internal accommodation space. The primary pulverized waste synthetic resin is transferred to the inside of the separation tank through a separate waste synthetic resin supply pipe 425, or separated by the wind pressure through the blower 412 And can be transferred to the inside of the tank 411.

The first foreign matter separated from the primary pulverized waste synthetic resin, that is, the first foreign matter separated by the plurality of flow guides 413, is transferred to the first dust collecting part 130 side at the upper part of the separation tank 411 A foreign matter discharge pipe 415 which forms a foreign matter discharge path is provided. In addition, a regenerated resin discharge pipe 416 for discharging regenerated resin separated from the primary pulverized waste synthetic resin is provided in the lower portion of the separation tank 411. The control procedure for discharging the regenerated resin and the first foreign matter is the same as in the first embodiment.

Next, the blower 412 may supply air to the inside of the separation tank 411, for example, in the direction of the inside of the separation tank 411. However, the blown air may flow sequentially along the plurality of flow guides 413 It is possible to flow in any direction.

In the fourth embodiment of the present invention, as shown in Fig. 6, a plurality of flow guides 413 are provided in the interior of the separation tank 411. Fig. The plurality of flow guides 413 are spaced apart from each other along the longitudinal direction of the separating tank 411 so that when the regenerating resin, the first foreign matter, and the air move upward from the lower region of the separating tank 411, Is gradually increased.

Specifically, each of the plurality of flow guides 413 is provided so that its outer peripheral surface is in contact with the inner peripheral surface of the separation tank 411 and is inclined downward symmetrically toward its central region. Each of the plurality of flow guides 413 is provided with a through hole 414 having a different size in the central region thereof. In addition, the plurality of flow guides 413 are provided with through holes 422 of different sizes.

Although the figure shows that a plurality of flow guides 413 are provided in the figure, it is not limited to this, and more than two flow guides 413 may be provided. The diameter of the through hole 422 is further reduced toward the flow guide 413 disposed above the through hole 422 formed in the flow guide 413 disposed close to the bottom surface of the separation tank 411 . That is, it is possible to control the particle size of the discharged first foreign matter so that only the first foreign matter having a finer particle size can be discharged.

The diameter of the through hole 414 is further reduced as the flow guide 413 disposed above the through hole 414 formed in the flow guide 413 disposed close to the bottom surface of the separation tank 411 . That is, when the first foreign matter separated from the waste synthetic resin is moved upward by the wind pressure, it can be moved and discharged more quickly.

The waste synthetic resin introduced into the separation tank 411 by the blowing of the blower 412 has the same size as the through holes 414 in the separating tank 411, The flow speed gradually increases while passing through the plurality of flow guides 413 and the process of separating the regenerated resin into the first foreign matter is more rapidly generated due to the wind pressure and the flow velocity of the blower 412 .

In addition, the waste synthetic resin is separated into the regenerated resin and the first foreign substance in the process of gradually moving to the upper region of the separation tank 411, and the regenerated water is separated from the upper surface of the flow guide 413, The first foreign substances may rise upward along the plurality of flow guides 413 or may ascend via the through holes 422. In this case,

On the other hand, when the regenerated resin having a small particle size rises upward together with the first foreign matter by the wind pressure, the regenerated water can hit the bottom surface of the plurality of flow guides 413 and can descend to the bottom, It will be possible to fall through.

That is, by gradually decreasing the size of the through-hole 414 toward the upper side of the separation tank 411, a first foreign matter separated from the waste synthetic resin and having a relatively light particle weight is introduced into the foreign matter discharge pipe 415 ) To be discharged more quickly.

FIG. 7 is a view showing a front separation unit of a composite waste separation apparatus according to a fifth embodiment of the present invention, and FIG. 8 is a plan view of FIG.

Hereinafter, a composite waste separation apparatus according to a fifth embodiment of the present invention will be described.

Prior to the description, repetitive description of the same configuration as that of the first embodiment will be omitted, and the same reference numerals as those of the first embodiment will be used.

In the separating apparatus according to the fifth embodiment of the present invention, the front separating unit and the rear separating unit may have the same structure or may have different structures from each other.

Hereinafter, the front separator and the rear separator will be described with reference to the same structure, and the forward separator will be described as an example for convenience of explanation.

7, in the separating apparatus according to the fifth embodiment of the present invention, the front separating unit 510 includes a separating tank 511 for providing a space for supplying regenerated resin, a separating tank 511, And a plurality of slits 514 disposed on the outer surface of the separating tank 511 and extending in the longitudinal direction along the longitudinal direction of the separating tank 511. The blower 512 is provided at a central region of the separating tank 511, A connection guide 522 connecting the flow guide 513 and the inner circumferential surface of the separation tank 511 and a flow guide 513 in the upper region of the separation tank 511, A foreign matter discharge pipe 515 for discharging the foreign matter separated by the connection guide 522 and a regenerated resin discharge pipe 516 for discharging the regenerated resin separated at the lower part of the separating tank 511.

First, the separation tank 511 is a chamber having an internal accommodation space. The primary pulverized waste synthetic resin is transferred to the inside of the separation tank through a separate waste synthetic resin supply pipe 525 or separated by the wind pressure through the blower 512 And can be transferred to the inside of the tank 511.

A first foreign matter separated from the primary pulverized waste synthetic resin, that is, a first foreign matter separated by the flow guide 513 and the connection guide 522 is supplied to the upper portion of the separation tank 511 through the first dust collector 130 A foreign matter discharge pipe 515 which forms a foreign matter discharge path is provided. In addition, a regenerated resin discharge pipe 516 for discharging regenerated resin separated from the primary pulverized waste synthetic resin is provided in the lower portion of the separation tank 511. The control procedure for discharging the regenerated resin and the first foreign matter is the same as in the first embodiment.

8, the blower 512 supplies air to the inside of the separation tank 511 substantially in the tangential direction to the inner circumferential surface of the separation tank 511. As shown in FIG. That is, the air eccentrically supplied by the blower 512 to the inside of the separation tank 511 is rotatably movable inside the separation tank 511 as described above. At this time, the primary pulverized waste synthetic resin can be introduced into the separation tank 511 while being rotated together with the air through the air.

In the fifth embodiment of the present invention, as shown in Fig. 7, a flow guide 513 and a connection guide 522 are provided inside the separation tank 511. [ The flow guide 513 is formed such that the inside thereof penetrates the central portion of the separation tank 511 along the longitudinal direction of the separation tank 511 and a plurality of slits 514 are provided on the outer surface thereof. The connection guide 522 connects the outer surface of the flow guide 513 and the inner peripheral surface of the separation tank 511 to support the flow guide 513.

The connection guide 522 is preferably inclined downward from the one end of the separation tank 511 facing the inner surface of the separation tank 511 toward the bottom surface of the separation tank 511 toward the other end. And a plurality of through holes 523 are formed in an area adjacent to the through hole 523.

Although the figure shows that two flow guides 513 are provided, the flow guides 513 are not limited thereto and may be provided in more than one flow guide. Similarly, when two or more flow guides 513 are provided, the connection guides 522 are provided in corresponding numbers, and the plurality of connection guides 522 are provided with through holes 523 having different diameters, .

Specifically, the diameter of the through hole 523 is further reduced as the connection guide 522, which is disposed above the through hole 523 formed in the connection guide 522 disposed close to the bottom surface of the separation tank 511, . That is, it is possible to control the particle size of the discharged first foreign matter so that only the first foreign matter having a finer particle size can be discharged.

The waste synthetic resin introduced into the separating tank 511 by the blowing of the blower 512 is separated from the bottom surface of the separating tank 511 and the bottom surface of the separating tank 511, And flows into the flow guide 513 through the gap between the lower portions of the flow guide 513 disposed at the lowermost side. At this time, since the waste synthetic resin introduced into the separation tank 511 flows into the flow guide 513 while spirally turning, the regenerated water having a relatively large particle size and a heavy size collides with the inner wall of the flow guide 513, The first foreign matter is discharged through the slit 514 of the flow guide 513 and then moved up through the through hole 523 of the connection guide 522. [ Also, the first foreign matter may be discharged directly through the inner penetrating space of the plurality of flow guides 513. [

In addition, as the waste synthetic resin is gradually moved to the upper region of the separation tank 511, the regenerated resin is separated into the regenerated resin and the first foreign material, and the regenerated water collides against the inner wall of the flow guide 513 and descends downward. It is possible to rise upward along the plurality of flow guides 513 or to ascend via the through holes 523.

On the other hand, when the regenerated resin having a small particle size is discharged to the slit 514 together with the first foreign matter by the wind pressure, the regenerated water hits the bottom surface of the plurality of connection guides 522 and is guided along the inclined surface of the connection guide 522 And may be lowered to the bottom surface of the separation tank 511 through the through hole 523 after descending.

That is, by gradually decreasing the size of the through holes 523 of the plurality of connection guides 522 toward the upper side of the separation tank 511, a gradual increase of the flow velocity is induced, thereby separating from the waste synthetic resin and having a relatively light particle weight, So that the foreign matter can be discharged to the foreign matter discharge pipe 515 more quickly.

Although the present invention has been described with reference to the accompanying drawings and the preferred embodiments described above, the present invention is not limited thereto but is limited by the following claims. Accordingly, those skilled in the art will appreciate that various modifications and changes may be made thereto without departing from the spirit of the following claims.

100: primary crushing unit 110:
113: suction induction tube 117:
121: vibrating part 130: first collecting part
140: secondary crushing unit 150: rear separation unit
160: second dust collector 170: vibration isolator
180: third dust collector 213: spiral guide
313, 413, 513:
514: Slit 522: Connection guide

Claims (18)

An apparatus for separating composite waste from recycled resin and foreign matter other than recycled resin,
A primary pulverizing unit for primary pulverizing the composite waste; A front separator for separating the primary pulverized composite waste into recycled resin and a first foreign matter through blowing air, using a difference in air blowing intensity and a difference in weight between the recycled resin and the first foreign matter; A first dust collecting part for collecting the first foreign substance separated by the front separating part; A secondary pulverizing unit for secondary pulverizing the regenerated resin separated by the front separating unit; At least one rear separator for separating the regenerated resin and the second foreign matter from the secondary pulverized regenerated resin by blowing air using the difference between the blowing intensity and the weight difference between the regenerated resin and the second foreign matter; And a second dust collecting part for collecting the second foreign matter separated by the rear separating part,
At least one of the front separating portion and the rear separating portion includes:
A separation tank for providing a space to which the recycled resin is supplied; A blower for supplying air to the inside of the separation tank; Wherein the separating tank is disposed to be spaced apart from one another along the longitudinal direction of the separating tank and one end of the separating tank contacts the inner circumferential surface of the separating tank and the other end of the separating tank is spaced apart from the inner circumferential surface of the separating tank, A plurality of flow guides provided so that a moving direction of the regenerated resin, the foreign matter, and the air can be changed a plurality of times from a lower region of the separating tank to an upper side thereof; Holes of different sizes provided in each of the plurality of flow guides; A foreign matter discharge pipe for discharging foreign matter separated by the flow guide to an upper region of the separation tank; And a regenerated resin discharge pipe arranged to discharge the regenerated resin separated at the lower part of the separating tank,
A separation tank for providing a space to which the recycled resin is supplied; A blower for supplying air to the inside of the separation tank; Wherein the separating tank is provided with a plurality of through holes spaced apart from each other along a longitudinal direction of the separating tank, the outer circumferential surface being in contact with an inner circumferential surface of the separating tank and inclined downwardly symmetrically toward a central region thereof, A plurality of flow guides provided so that a moving speed of the regenerated resin, the foreign matter, and the air gradually increases from a lower side of the tank to an upper side thereof; A foreign matter discharge pipe for discharging foreign matter separated by the flow guide to an upper region of the separation tank; And a regenerated resin discharge pipe arranged to discharge the regenerated resin separated at the lower part of the separating tank,
A separation tank for providing a space to which the recycled resin is supplied; A blower for supplying air laterally along the inner circumferential surface of the separating tank; At least one flow guide provided in a central region of the separation tank, the inside of the separation tank being penetrated along the longitudinal direction of the separation tank and having a plurality of slits on its outer surface; Wherein the flow guide is provided for connecting the flow guide and the inner circumferential surface of the separating tank and is inclined downwardly from one end of the separating tank toward the other end toward the bottom of the separating tank, A connection guide provided with a through hole; ; A foreign matter discharge pipe for discharging foreign matter separated by the flow guide and the connection guide to an upper region of the separation tank; And a regenerated resin discharge pipe arranged to discharge the regenerated resin separated at a lower portion of the separating tank. The method according to claim 1,
A vibration separator for separating the third foreign matter from the regenerated resin separated by the rear separator through vibration imparting; And
Further comprising a third dust collecting part for collecting the third foreign matter separated by the vibration separating part. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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