KR20090003015A - Glassware clushing system - Google Patents

Abstract

A glass pulverization system for treating the waste glass is provided to allow the foreign substance contained in the waste glass to be removed automatically, thereby improving productivity. A glass pulverization system comprises a hopper(10) where the waste glass is accommodated; a breaking part(20) for breaking the waste glass; a first transport unit(30) for transporting the pulverized glass; a separation unit(40) which separates the transported waste glass by a size to discharge the separated one; and a second transport unit(50) for transporting the pulverized particle of large size separated from the separation part to the hopper.

Description

Glass Shredding System {GLASSWARE CLUSHING SYSTEM}

The present invention relates to a glass crushing system, and more particularly, to a glass crushing system capable of effectively separating and removing foreign substances generated during the crushing process of waste glass.

In general, glass products are widely used for various materials such as building materials and household goods due to the advantages of transparent materials while shielding the space, and a large amount of waste glass that is broken or discarded during use also occurs in large quantities. do.

And, although waste glass is a material that can be recycled by simple melting treatment, due to the disadvantage that the handling and processing process is dangerous and relatively large, it is not recycled except for the glass bottles for liquor and beverage storage. Most of them are treated as industrial wastes, thus wasting resources and polluting the environment.

Accordingly, as a method for facilitating the recycling of waste glass, glass crushers for crushing glass products have been proposed, and such glass crushers break down the waste glass into small particles, thereby enabling more efficient recycling.

However, considering that glass products are used together with auxiliary materials such as waste paper, silicone, rubber, and synthetic resins for use, installation, and assembly, the above-mentioned auxiliary materials are generated as a large amount of foreign substances during the crushing process of glass products. . Since these foreign matters have to be removed and rely on manual labor, there is a problem that the treatment efficiency is very low due to excessive treatment time.

SUMMARY OF THE INVENTION The present invention has been proposed in view of the above, and provides a glass crushing system capable of efficiently crushing waste glass and effectively separating and removing foreign matters generated during crushing of waste glass. have.

In order to achieve the above object, the glass shredding system of the present invention, a glass shredding system for shredding and processing the waste glass, the glass hopper; A shredding part configured to be disposed on the discharge side of the hopper to crush waste glass; A first transfer unit configured to transfer the crushed glass discharged from the crushed unit; Separation unit for passing the small diameter crushed particles having a particle size of less than a predetermined size from the crushed glass conveyed by the first transfer unit, separating and discharging large diameter crushed particles and foreign matter having a predetermined size or more; And a second transfer unit configured to transfer the large-diameter crushed particles separated from the separation unit onto the hopper.

Here, the separation unit, the separation net formed in a cylindrical shape by a mesh network having a distribution hole of the size through which the small diameter crushed particles; A conveying screw for conveying and discharging the large-diameter crushed particles and the foreign substances formed spirally on the inner circumferential surface of the separation network; A plurality of transfer pieces installed at predetermined intervals so as to have the same curvature on the inside and the outside in contact with the transfer screw to increase the discharge speed of the foreign matter; And a separating network driving means for applying a driving force to rotate the separating network.

And, the separation network is formed by separating the first separation network and the second separation network from the inlet side by the mesh network having different sizes of distribution holes, the distribution hole of the first separation network is the distribution hole of the second separation network It can be formed to have a smaller size.

It may include a foreign material removal unit configured to remove the foreign matter contained in the small diameter crushed particles passing through the separation unit.

The foreign material removal unit, the plate member is installed so that a predetermined inclination angle is formed in the vertical and horizontal directions, the vibration plate is installed so that the horizontal inclination angle has a larger inclination angle than the vertical direction; And it may include a vibrator for applying a vibration force to vibrate the diaphragm.

In addition, the foreign matter removal unit, the small diameter crushed particles are immersed in the fluid and transported, the foreign matter is inclined flow path of the fluid from the lower side corresponding to the discharge side of the separation so that the foreign matter is transported in a suspended state on the fluid Separating gutter having; A glass collecting part provided at the distal end of the separating gutter and collecting the small-diameter crushed particles conveyed with the fluid; A foreign matter collecting unit provided at the distal end of the separating gutter to collect the foreign matter; And a circulation pump connected to a pipe installed at both ends of the separation gutter to circulate the fluid.

The apparatus may further include a foreign matter suction unit for sucking and removing foreign substances by applying negative pressure to the crushed glass.

And, it may include a magnetic material configured on the first transfer portion to remove the metal component contained in the crushed glass.

The glass shredding system of the present invention can automatically remove foreign substances contained in the waste glass without depending on manual work, thereby improving workability and productivity of the shredding operation and improving recycling efficiency of the waste glass.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a technical concept of a glass crushing system according to the present invention. FIG. 2 is a view schematically showing a glass crushing system according to an embodiment of the present invention.

1 and 2, the glass shredding system according to an embodiment of the present invention, the hopper 10, the shredding portion 20, the first conveying portion 30, the separating portion 40, and the second conveying portion It is provided with 50 to crush and process the waste glass to the size that is easy to recycle.

Hopper 10 is a cylindrical receiving means having a predetermined size space therein to accommodate and store the waste glass to be shredded, is formed in a rectangular frame shape by a plate member is installed to have a predetermined height from the ground by the support frame .

The crushing unit 20 is a means for crushing the waste glass freely falling from the hopper 10 is configured on the discharge side of the hopper 10, it may be composed of a crusher having a cutter rotated by a drive motor.

The separating unit 40 passes small-diameter crushed particles having a particle size smaller than or equal to a predetermined size among the crushed glass conveyed by the first conveying unit 30, and foreign particles such as large-diameter crushed particles having a particle size of a predetermined size or larger, waste paper, silicon, rubber, It functions as a separator for separating and discharging water.

Figure 3 is a perspective view showing the separation of the glass shredding system according to an embodiment of the present invention, as shown in this, the separating portion 40 is a separation net 42 for separating the crushed glass, this separation network 42 The transfer screw 44 and the transfer piece 46 formed in the, and the separation network driving means 48 for applying a driving force to rotate the separation network 42 is provided.

The separating net 42 is formed in a cylindrical shape by a mesh net having a distribution hole having a size through which small-diameter crushed particles flowing from the discharge side of the first transfer part 30 pass, and are installed in the transverse direction. In addition, the separating net 42 has a rotating shaft 47 supported by the plurality of support members 45 at its inner center, and crushed glass falling on the inlet side and falling from the first transfer part 30 to the inside. It is further provided with a guide plate 41 for.

The separation network 42 is formed by separating the first separation network 42a and the second separation network 42b from the inlet side by mesh networks having different sizes of distribution holes, but the distribution holes of the first separation network 42a It is formed to have a size smaller than the flow hole of the second separation net (42b).

For example, the mesh size of the first separation net 42a is 12 × 12 mm, and the mesh size of the second separation net 42 b is 15 × 15 mm, so that the second separation net 42a is the second separation net. Compared to (42b), small-size crushed particles having a smaller particle size can be first separated to obtain crushed glass of higher quality.

The conveying screw 44 is configured to be coupled in a spiral shape on the inner circumferential surface of the separation network 42 using a linear member such as a pipe to convey and discharge the remaining large diameter crushed particles and foreign matter.

The conveying piece 46 is configured on the inner circumferential surface of the separating net 42 to increase the discharge rate of foreign matter. The conveying screw 44 has the same curvature as the conveying screw 44 by using a linear member having a predetermined length. It is installed in the inner and outer sides in contact with the), it is composed of a plurality to have a predetermined interval along the longitudinal direction. This, the conveying piece 46 is such that the foreign matter conveyed along the spiral orbit by the conveying screw 44 by the rotation of the separation network 42 is collapsing by the interaction with the conveying screw 44 to bounce off of the foreign matter Will increase.

The separating network driving means 48 includes a driving motor and a reduction gear, and the sprocket coupled to the output shaft of the reduction gear and the sprocket coupled on the rotation shaft 47 of the separating network 42 are connected to each other by a chain. 42).

The first conveying part 30 and the second conveying part 50 are constituted by a conveying means such as a belt conveyor device, and the first conveying part 30 is a discharge side of the crushing part 20 and an inflow of the separating part 40. It is installed between the sides to transfer the crushed glass discharged from the crushed portion 20 on the separating portion 40, the second conveying portion 50 is installed between the separating portion 40 and the hopper 10 is separated Large diameter crushed particles separated and discharged from the discharge side of the 40 are transferred onto the hopper 10.

The first transfer portion 30 is further provided with a magnetic body 70 for removing the metal component contained in the crushed glass. The magnetic body 70 is formed in the form of a roll by electromagnets or permanent magnets, and is installed on the frame of the first transfer part 30 so that the outer circumferential surface of the roll is close to the surface of the belt so as to adsorb metal components by magnetic force. .

In addition, the first transfer unit 30 further includes a foreign matter suction unit 80 that sucks and removes foreign matter by applying negative pressure to the crushed glass discharged from the crushed unit 20. The foreign matter suction unit 80 is installed on the first transfer unit 30 side, and the suction port 82 through which foreign substances such as waste paper and rubber are sucked in, the suction blower 84 that applies negative pressure to the suction port 82 side, and A collection tank 86 through which the foreign matter sucked through the suction port 82 is collected.

The glass crushing system according to the present embodiment further includes a foreign matter removing unit 200 capable of removing the fine foreign matter contained in the small diameter crushed particles passing through the separator 40.

Figure 4 is a perspective view showing an example of the foreign matter removing unit applied to the glass crushing system according to an embodiment of the present invention, as shown in the foreign matter removing unit 200 is a diaphragm 210 formed of a plate-like member And, the vibration plate 210 is configured to include a vibrator 220 for applying a vibration force to vibrate.

The diaphragm 210 is installed so that a predetermined inclination angle is formed in up, down, left, and right directions, and is installed so that the left and right inclination angle θ2 has a larger inclination angle than the up and down inclination angle θ1.

Figure 5 is a perspective view showing another example of the foreign matter removing unit applied to the glass shredding system according to an embodiment of the present invention, as shown in this, the foreign material removing unit 200 is a separating gutter 230, glass collection unit ( 240, the foreign matter collecting unit 250, and the circulation pump 260, to remove the foreign matter contained on the small diameter crushed particles by using the fluid flowing.

Separating gutter 230 is formed to have a downward inclined flow path of a predetermined length through which fluid flows from the lower side corresponding to the discharge side of the separation unit 40, the small diameter crushed particles are immersed and transferred to the lower side of the flow path, the upper side of the flow path Foreign matter is transported in a suspended state.

The glass collecting unit 240 is configured to collect small-diameter crushed particles which are provided under the distal end of the separating gutter 230 and transported with the fluid, and the foreign matter collecting unit 250 is provided above the distal end of the separating gutter 230. In addition, it is configured to collect the transferred foreign matter.

The circulation pump 260 is a pump connected to the pipe 270 installed to be connected to each other between the both ends of the separation gutter 230, and circulates the fluid to enable continuous foreign matter removal action.

On the other hand, in the glass shredding system according to the present embodiment for transporting the waste glass to the hopper 10, the third transfer unit 110 and the small-diameter crushed particles discharged from the separation unit 40 to transfer to a predetermined loading place The fourth transfer part 120 may be further configured by a transfer means such as a belt conveyor device.

Hereinafter, the operation of the glass crushing system according to an embodiment of the present invention.

As shown in FIG. 2, when the shredding unit 20 is operated while the waste glass stored in the yard, etc., is loaded in the third transfer unit 110 and put onto the hopper 10, the shredding action of the waste glass is performed. Is carried out and falls onto the first conveying part 30. The crushed glass dropped to the first transfer unit 30 is transported by the belt, and then guided to the guide plate 41 to be introduced into the separation net 42.

During the operation of the crushing unit 20, the metal powder or metal components contained in the waste glass are attracted by the magnetic force of the magnetic body 70 in the process of being transported through the first conveying unit 30. Attached and removed on the outer circumferential surface.

In addition, the foreign matter contained in the crushed glass is first removed by the foreign matter suction unit 80 in the transfer process by the first transfer unit 30. That is, when the crushed glass loaded and transported in the first transfer part 30 is positioned on the suction port 82 side, low density foreign substances such as waste paper, silicon, rubber, etc. are formed by the negative pressure formed on the inlet side by the operation of the suction blower 84. Is sucked into the interior and collected to the collection tank 86 side.

On the other hand, in the state in which the crushed glass is introduced into the separation network 42, when the separation network is rotated by the drive of the separation network driving means 48, the small-size crushed particles fall down, foreign matter and large-diameter crushed particles It is discharged to the discharge side of 42. At this time, the small diameter crushed particles having a particle size of 12 × 12 mm or less are discharged downwardly from the first separation network 42a, and the small diameter crushed particles having a particle size of 12 × 12 mm to 15 × 15 mm or less are moved downward to the second separation network 42b side. Discharged. As a result, the separation network 42 may be formed in a plurality of structures so that the small-size crushed particles are separated and discharged according to the particle size, thereby increasing the processing speed, and separating and collecting high-quality small-size crushed particles having a small size. .

The transfer of the crushed glass and the foreign matter in the separation net 42 is performed by the rotation of the moving screw 44 formed spirally therein. In other words, the crushed glass and foreign matter is transported along the spiral trajectory of the transfer screw (44). In addition, the foreign matter is transported in a form that is bounced by the interaction of the conveying piece 46 and the conveying screw 44, it is possible to discharge more quickly.

On the other hand, by finely removing the fine foreign matter contained in the small diameter crushed particles falling to the lower portion of the separation network 42 by the foreign matter removal unit 200 can be obtained a higher quality crushed glass. That is, as shown in FIG. 4, when the small-diameter crushed particles including foreign matter fall onto the diaphragm 210, the diaphragm 410 is vibrated by the vibrator 420, so that the small-diameter crushed particles having a high density move downward. As it is quickly discharged, foreign matter with high adhesion is discharged by moving to the side with a large inclination angle by vibration. As a result, the small-diameter crushed particles are discharged to the front of the diaphragm 410, the foreign matter is divided into the side of the diaphragm 410.

In addition, in the case where the foreign matter removing unit 200 of the type shown in FIG. 5 is configured, when the small diameter crushed particles including the foreign matter fall on the upper flow path of the separation gutter 230, the large diameter small crushed particles fall into the lower side of the fluid. It is immersed and transported by the flow rate, and low-density foreign matter is transported in a suspended state above the fluid. As such, the small-diameter crushed particles transferred to the distal end of the separating gutter 230 are collected in the glass collecting part 240, and the foreign matter is collected in the foreign material collecting part 250.

In addition, the large-diameter crushed particles discharged through the discharge side of the separation network 42 are transferred to the hopper 10 by the second transfer unit 50 again, and then re-crushed by the crushing unit 20 and the above-described process. It is formed through the small diameter crushed particles through.

What has been described above is only one embodiment for implementing the glass shredding system according to the present invention, and the present invention is not limited to the above-described embodiment, and as claimed in the following claims, the gist of the present invention Without departing, those skilled in the art to which the present invention pertains to the technical spirit of the present invention to the extent that various modifications can be made.

1 is a block diagram illustrating the technical idea of a glass crushing system according to the present invention;

2 is a view schematically showing a glass crushing system according to an embodiment of the present invention;

Figure 3 is a perspective view showing a separation portion of the glass shredding system according to an embodiment of the present invention,

Figure 4 is a perspective view showing an example of the foreign matter removing unit applied to the glass crushing system according to an embodiment of the present invention,

5 is a perspective view showing another example of the foreign matter removing unit applied to the glass crushing system according to an embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

10: Hopper 20: crushing unit

30: first transfer part 40: separation part

42: separation network 42a: first separation network

42b: second separation network 44: feed screw

46: conveying flight 50: second conveying part

70: magnetic material 80: foreign matter suction unit

82: suction port 84: suction blower

86: collection tank 110: third transfer unit

120: fourth transfer unit 200: foreign matter removal unit

210: vibration plate 220: vibrator

230: separation gutter 240: glass collection

250: foreign matter collection unit 260: circulating pump

Claims (8)

In the glass shredding system for shredding and processing the waste glass, A hopper in which waste glass is accommodated; A shredding part configured to be disposed on the discharge side of the hopper to crush waste glass; A first transfer unit configured to transfer the crushed glass discharged from the crushed unit; Separation unit for passing the small diameter crushed particles having a particle size of less than a predetermined size from the crushed glass conveyed by the first transfer unit, separating and discharging large diameter crushed particles and foreign matter having a predetermined size or more; And And a second conveying portion for conveying the large diameter crushed particles separated from the separating portion onto the hopper. The method of claim 1, The separation unit, A separation network formed into a cylindrical shape by a mesh network having a distribution hole having a size through which the small-diameter crushed particles pass; A conveying screw for conveying and discharging the large-diameter crushed particles and the foreign substances formed spirally on the inner circumferential surface of the separation network; A plurality of transfer pieces installed at predetermined intervals to have the same curvature on the inside and the outside in contact with the transfer screw so that the discharge speed of the foreign matter is increased; And And a separating network driving means for applying a driving force to rotate the separating network. The method of claim 2, The separation network is formed by separating the first separation network and the second separation network from the inlet side by different mesh networks having different sizes of distribution holes, wherein the distribution holes of the first separation network are smaller than the distribution holes of the second separation network. Glass crushing system, characterized in that formed to have a size. The method of claim 1, And a foreign material removing unit configured to remove foreign substances contained in the small diameter crushed particles passing through the separating unit. The method of claim 4, wherein The foreign material removing unit, A diaphragm provided with a plate member such that a predetermined inclination angle is formed in a vertical direction and a left and right direction, wherein the diaphragm is installed such that the horizontal inclination angle has a larger inclination angle than the vertical direction; And And a vibrator for applying a vibrating force to vibrate the diaphragm. The method of claim 4, wherein The foreign material removing unit, The small diameter crushed particles are immersed in the fluid and transported, and the foreign matter is separated from the inclined flow passage having a predetermined length in which the fluid flows from the lower side corresponding to the discharge side of the separation so as to be transported in a suspended state on the fluid; A glass collecting part provided at the distal end of the separating gutter and collecting the small-diameter crushed particles conveyed with the fluid; A foreign matter collecting unit provided at the distal end of the separating gutter to collect the foreign matter; And And a circulation pump connected to a pipe installed to connect both ends of the separation gutter to circulate the fluid. The method of claim 1, The glass crushing system further comprises a foreign matter suction unit for sucking and removing foreign matter by applying negative pressure to the crushed glass. The method of claim 1, And a magnetic material disposed on the first transfer part to remove metal components contained in the crushed glass.

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