KR100506002B1 - Separation apparatus - Google Patents

Abstract

An object of the present invention is to provide an aggregate sorting device which is intended to prevent the aggregates from being stacked unevenly under the inlet by supplying the aggregates radially into the mesh cylinder. Rotating through itself and made of one or more mesh cylinders; A conveyor including aggregate into the input portion behind the mesh cylinder and including a support frame and a front rotary shaft wound around the belt; And a drive main body connected to the support frame and provided at the front of the conveyor and connected to the front rotating shaft to rotate the vertical rotating shaft, and a horizontally mounted at the lower end of the vertical rotating shaft to diffuse and inject aggregate. It is characterized in that it comprises an aggregate diffusion portion consisting of a rotating body, and a cover plate connected to the support frame and provided on the rear of the diffusion rotating body.

Description

Separation apparatus

The present invention relates to a waste aggregate sorting apparatus, and more particularly, to an aggregate sorting apparatus for classifying waste aggregates obtained by crushing construction waste according to size.

In general, construction wastes are wastes generated by dismantling structures such as buildings, bridges, and roads. Recently, construction wastes are widely known.

First, in the case of regenerating construction wastes universally, the construction wastes are first crushed in a lump form, and the reinforcing bars are separated from the crushed crushed matters.

In the crushed matter, the aggregate that can be recycled into aggregate is put into a crusher and then crushed into secondary particles. Next, the crushed aggregate (hereinafter referred to as aggregate) is put into a sorting apparatus and sorted by size. And finally to remove the foreign substances while washing the classified aggregates with wash water to produce recycled aggregates.

Therefore, the present invention is to improve the sorting device for the aggregate by the size, first described the conventional aggregate sorting device as follows.

Conventionally known sorting apparatus is provided in the upper portion of the base in front and consists of a mesh cylinder that rotates itself through the drive to filter the aggregate, and a conveyor for introducing the aggregate into the mesh cylinder rear input.

The drive unit for rotating the mesh cylinder is composed of a sprocket provided around the mesh cylinder and a drive motor connected to the sprocket by a chain to rotate the sprocket.

In addition, the lower front, rear of the mesh cylinder is supported by a plurality of rollers to enable the rotation of the mesh cylinder.

In addition, the front and the lower portion of the mesh cylinder is provided with a conveying conveyor for transporting the aggregate filtered through the mesh and the aggregate passed through the mesh.

Accordingly, when the aggregate is introduced into the inside of the mesh rotating body through the conveyor while rotating the mesh rotating body through the operation of the driving unit, the aggregate having a larger particle size than the mesh is discharged and transferred forward, and the aggregate having a smaller particle size than the mesh is meshed. By passing through and discharged to the bottom, the aggregate can be selected according to the particle size.

However, when the aggregate is selected using the mesh cylinder, aggregate is concentrated concentrated on the input side into which the aggregate is input.

Therefore, aggregate is accumulated on the input side, and thus, the aggregate is added to the input side is discharged directly without being selected, there is a problem that the precise selection of the aggregate is impossible.

In addition, when the aggregates are concentrated in the input unit as described above, there is a problem that the phenomenon of intensively damaging or clogging the input side is frequently caused by the weight of the aggregate.

Accordingly, the present invention has been invented to solve the above problems, the object of the present invention is to provide a sorting device to prevent the aggregates are deposited unevenly in the lower portion of the input by supplying the aggregates radially diffused into the inside of the network cylinder. It is done.

In addition, there is also an object to prevent clogging phenomenon of the network constituting the network rotating body.

The present invention for achieving the above object, is mounted on top of the base and rotates itself through a drive unit consisting of one or more mesh cylinders; A conveyor including aggregate into the input portion behind the mesh cylinder and including a support frame and a front rotary shaft wound around the belt; And a drive main body connected to the support frame and provided at the front of the conveyor and connected to the front rotating shaft to rotate the vertical rotating shaft, and a horizontally mounted at the lower end of the vertical rotating shaft to diffuse and inject aggregate. It is characterized in that it comprises an aggregate diffusion portion consisting of a rotating body, and a cover plate connected to the support frame and provided on the rear of the diffusion rotating body.

Hereinafter, the configuration and operation of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a temporary example of the sorting apparatus of the present invention, Figure 2 is a cross-sectional view taken along the line AA of Figure 1, Figure 3 is an enlarged perspective view showing the aggregate diffusion portion according to the present invention, Figure 4 is Figure 1 It is sectional drawing along the BB line | wire of FIG. 5, and FIG. 5 is an enlarged view of the C part of FIG.

Thus, the aggregate screening apparatus of the present invention, as shown in Figures 1 to 3, is mounted on the upper portion of the base (1) itself is rotated through the drive unit 21 is composed of one or more network cylinders (2a) (2) and a conveyor (3) comprising a front rotary shaft (32) and a support frame (31) on which belts (33) are wound, in which aggregate is introduced into the input section behind the mesh cylinder (2); It is characterized in that it comprises an aggregate diffusion portion which is provided in front of the (3) to be introduced into the aggregate flowing from the conveyor into the mesh cylinder (2).

In addition, the mesh cylindrical body 2 is mounted on the top of the base 1 to be inclined downward so that the injected aggregate can be discharged forward through gravity.

In addition, the aggregate diffusion portion is fixed to the front of the conveyor 3 via the front connecting rod 311 connected to the support frame 31 and is connected to the front rotary shaft 32 receives a driving force to the vertical rotation shaft 42 Drive body 4 including a connecting drive means 41 for rotating the rotational and horizontally provided at the lower end of the vertical axis of rotation (42) receives the aggregate introduced from the conveyor (3) and the cylindrical cylinder (2) Diffusion rotator (5) for diffusing into the inside, and the cover plate (6) is connected to the support frame and is vertically erected through the vertical connection 312 in the rear of the diffusion rotator (5).

In addition, the driving unit 21 for rotating the mesh cylindrical body 2 is known, a sprocket provided around the mesh cylindrical body, a drive motor connected to the sprocket by a chain to rotate the sprocket, and the mesh cylindrical body. It includes a plurality of rollers provided at the front and rear of the lower part of (2) to enable rotation of the mesh cylinder.

The configuration is described in more detail as follows.

As shown in FIG. 3, the diffusion rotor 5 is composed of a circular plate 51 and a rotary protrusion blade 52 provided on the upper surface of the circular plate 51 at radial equal intervals.

The connection drive means 41 is provided in parallel with the front rotation shaft 32 and the linkage shaft 412 to which the rotational force of the front rotation shaft 32 is transmitted through the normal power transmission unit 411, and the linkage. It is composed of a pair of interlocking gears 413 mounted between the shaft 412 and the vertical rotation shaft 42 to change the horizontal rotation of the linkage shaft 411 to the vertical rotation of the vertical rotation shaft 42.

In particular, the power transmission unit 411 is composed of a conventional power transmission elements, which is connected via a sprocket and a chain or connected through a pulley and a belt.

In addition, the pair of gears 413 may have a pair of worm gears and worm wheels that may have a sudden deceleration effect to prevent sudden rotation of the vertical rotation shaft 42.

That is, the pair of gears 413 is composed of a worm gear mounted on the linkage shaft 411 and a worm wheel mounted on the vertical rotation shaft 42 and engaged with the worm gear.

Therefore, when describing the operation relationship of the aggregate screening apparatus of the embodiment as described above as shown in Figure 1 to Figure 3, first, by operating the normal drive unit 21 provided on the outside of the network cylinder (2) Rotate the mesh cylinder.

In addition, the aggregate is introduced by operating the conveyor (3) is located in the forward portion of the network cylindrical body (2).

When the conveyor 3 is operated as described above, the front rotating shaft 32 constituting the conveyor rotates as described above, and the aggregate provided at the front of the conveyor 3 through the operation of the front rotating shaft 32. The diffuser is activated.

That is, as the interlocking shaft 412 of the driving body 4 constituting the aggregate diffusion portion is connected to the front rotary shaft 32, the interlocking shaft 412 rotates and the rotational force of the interlocking shaft 412 is a pair of gears 413. It is transmitted to the vertical axis of rotation 42 through.

Therefore, the diffusion rotary body 5 mounted horizontally on the vertical rotation shaft 312 is interlocked.

Therefore, the diffusion rotor 5 is located at the front lower side of the conveyor 3 to be rotated, and the aggregate injected into the front lower side of the conveyor 3 is continuously fed to the upper surface of the diffusion rotor 5. By doing so, the injected aggregate is to be diffused into the entire net cylinder 2 through the rotation of the diffusion rotor (6).

In other words, by supplying radially diffused aggregates into the mesh cylinder through the aggregate diffuser to prevent the aggregates from being stacked unevenly under the input portion, as well as preventing damage to the net near the input portion, This can prevent intensive clogging of the net near the input.

In the process of spreading the aggregates as described above, the aggregates are prevented from being diffused backward by the cover plate 6 standing behind the diffusion rotating body 6 so that the aggregates are rearward of the mesh cylindrical body 2. Emissions are also prevented.

In addition, by configuring the pair of gears 413 as worm gears and worm wheels to obtain the maximum reduction ratio, the diffusion rotor 5 can be prevented from rotating at high speed. That is, when the diffusion rotary body 5 is rotated at high speed, the diffusion input speed of the aggregate is increased, and the net is damaged. The aggregate, which is a means for transmitting the power, by using the worm gear and the worm wheel is operated by the aggregate during operation. This is to prevent damage to the net.

In addition, the upper surface of the circular plate 51 constituting the diffusion rotor (5) is provided with a plurality of rotary protrusions 52, so that the injection radius of the aggregate can be expanded through the rotation of the rotary protrusions (52). It will be able to prevent the phenomenon that aggregate aggregates.

On the other hand, as shown in Figure 1, the inside of the mesh cylindrical body 2, the support is provided with an external support 221 is rotated through the connection with the drive motor 222 and the outer surface of the mesh cylindrical body (2) One or more brush shafts 22 are provided with a plurality of brushes 223 that are inserted into and detached from the mesh constituting the opening and closing the blocked network.

As shown in FIG. 4, the mesh cylindrical body 2 is connected to the telescopic cylinder 2a provided therein and is connected to the radial connecting table 23 at intervals around the cylindrical cylinder 2a so as to be interlocked and rotated. It consists of an outer network cylinder (2a) having a network size relatively smaller than the network size of the inner network cylinder (2).

Therefore, after the primary screening the aggregate through the inner telescopic cylinder (2), the aggregate that passed through the network of the internal telescopic cylinder (2a) is also possible to secondary sorting through the external telescopic cylinder (2a).

And, the lower portion of the outer telescopic cylinder (2a) is provided with a discharge conveyor 8 including both side inclined guide plate 81 to discharge the discharge aggregate to the rear. In particular, the discharge conveyor 8 is equipped with a commonly known belt conveyor or screw conveyor.

As shown in Figure 1 and 5, the outer side of the mesh cylindrical body 2, the support is provided with an external support 75 is rotated through the connection with the drive motor 76, the outer surface of the mesh cylindrical ( One or more brush shafts 74 are provided with a plurality of brushes 741 that are inserted into and detached from the mesh constituting 2) and open the blocked network.

In addition, the outside of the mesh cylindrical body (2), it is provided with a support (72) of the outside, provided in parallel with the mesh cylindrical body (2) is rotated through the connection with the drive motor 73 and a plurality of cams ( An operating shaft 711 having 712 is provided at equal intervals, and is provided on the inner side of the operating shaft 711 and corresponding to the cams 712 so as to be interlocked with the rotation of the cams 712. At least one striking device 71 composed of a striking part fixed shaft 713 having striking parts 714 striking the outside of the one is provided.

In addition, the striking portion 714 is rotatably inserted into the fixed shaft 713 and is repeatedly rotated downward through the rotary striking of the cam 711 on the outside to repeatedly rotate the inner striking portion 716 upward. A striking table 715 including a cam operating table 717 and a lower portion of the inner striking table 716 and an upper portion of the support 72 are provided to repeatedly lower the inner striking part 716 downward. And a spring 718 to enable it.

Therefore, by repeatedly hitting the outside of the outer mesh cylindrical body 2 through the striking device 71, it is possible to continuously discharge the aggregate blocking the mesh from the mesh.

Therefore, the operation of the striking device 71 will be described in detail. When the operating shaft 711 is rotated by rotating the motor, the cam 712 mounted on the operating shaft 711 is rotated, and the striking part provided inside. Hit 714 repeatedly. That is, the cam 712 repeatedly strikes the cam operating table 717 of the striking table 715 constituting the striking part 714 from the top to the bottom.

Then, the lower side of the inner striking table 716 connected to the cam operating table 717 is maintained in the upper state, and when the cam 712 is separated from the cam operating table 717 is the inner striking table 716 Due to the restoring force of the spring 718 is to hit the surface of the outer mesh cylinder (7).

As the operation shaft 711 and the cam 712 are rotated continuously, the striking operation of the striking part 714 is repeatedly performed, thereby minimizing clogging of the network during the operation of the sorting device.

On the other hand, Figure 6 shows an aggregate screening apparatus of another embodiment of the present invention, first, the other configuration other than the network cylinder (2) is assumed to be the same as the configuration of the embodiment described above.

Therefore, according to another embodiment of the present invention, the mesh cylindrical body 2 is horizontally mounted on the upper part of the base 1, and each telescopic cylinder 2a constituting the horizontally mounted mesh cylindrical body 2 is provided. The inner surface of the) is characterized in that it is provided with one or more spiral screw plate 24 to force the aggregate forward. And the input part of the internal network cylinder 2a which comprises the said network cylinder 2 shows the state provided with the diffusion rotary body 5 which radially injects the aggregate aggregated.

Therefore, even if the mesh cylindrical body 2 is mounted horizontally, the spiral screw plate 24 formed on the inner surface of each network cylinder 2a constituting the mesh cylindrical body 2 is rotated, so that Aggregate introduced into the input is to be screened while moving to the front of the mesh cylindrical (2).

And it is possible to adjust the number of inclination and the inclination angle of the screw screw plate 24 corresponding to the diameter of the telescopic cylinder (2a) and the processing capacity of the aggregate.

Therefore, the appropriate screwing speed of the aggregate through the appropriate mounting of the screw screw 24 is to maximize the screening effect of the aggregate.

As described above, the present invention prevents the aggregate aggregated into the lower portion of the net rotating body inlet from being unevenly stacked, thereby preventing damage to the net near the input part, and of course, the net near the input part is concentrated. By preventing the phenomenon is effective in preventing the selection effect is lowered.

In addition, by preventing the clogging of the network constituting the network rotating body there is an effect that can prevent the poor sorting of aggregates during operation of the device.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible.

1 is a perspective view showing a sorting device of the present invention.

2 is a cross-sectional view taken along the line A-A of FIG.

Figure 3 is an internal perspective view showing an enlarged aggregate diffusion portion according to the present invention.

4 is a cross-sectional view taken along the line B-B in FIG.

5 is an enlarged view of a portion C of FIG. 1;

Figure 6 is a cross-sectional view showing a sorting apparatus of another embodiment of the present invention.

Explanation of symbols for main parts of the drawings

1: Base

2: network cylinder, 2a: network cylinder

    21: drive unit

    22: brush axis

         221: external support, 222: drive motor, 223: brush

    23: connecting rod

    24: spiral screw plate

3: conveyor

    31: support frame

         311: Front connecting rod

         312 vertical connection

    32: forward rotation axis

    33: belt

4: driving body

    41: connection drive means

         411: power transmission unit 412: drive shaft, 413: gear

    42: vertical axis of rotation

5: diffusion rotating body

    51: round plate

    52: rotary protrusion

6: cover plate

71: hitting device

     711: working shaft, 712: cam, 713: fixed shaft,

     714: striking unit, 715: striking table, 716: inner striking table,

     717: cam operating member, 718: spring

72: support

73: drive motor

74: brush axis

     741: Brush

75: support

76: drive motor

8: discharge conveyor

    81: side slope guide plate

Claims (10)

A mesh cylindrical body (2) mounted on the base (1) and rotating itself through the driving unit (21) and composed of one or more telescopic cylinders (2a); A conveyor (3) for introducing aggregate into the input portion (22) behind the mesh cylindrical body (2) and including a support frame (31) and a front rotating shaft (32) wound around the belt (33); And A driving body 4 connected to the support frame 31 and provided at the front of the conveyor 3 and connected to the front rotation shaft 32 and including a connection driving means 41 for rotating the vertical rotation shaft 42. A cover plate which is horizontally mounted at a lower end of the vertical rotation shaft 42 to diffuse and aggregate the aggregate, and a cover plate which is connected to the support frame 31 and provided at the rear of the diffusion rotor 5. An aggregate diffusion portion consisting of (6); Sorting apparatus comprising a. The network cylindrical body (2) according to claim 1, Separating apparatus characterized in that the front is inclined downwardly mounted on the upper portion of the base (1) so that the injected aggregate can be discharged forward through gravity. The network cylindrical body (2) according to claim 1, Separating device is characterized in that the horizontal surface is mounted on the upper portion of the base (1) is provided with one or more spiral screw plate (24) on the inner surface to transfer the injected aggregate forward. The diffusion rotor 5 according to any one of claims 1 to 3, Separating device characterized in that it consists of a circular plate 51 and a rotary projection blade 52 provided at radial equal intervals on the upper surface of the circular plate (51). The method of claim 4, wherein the drive means 41, It is provided in parallel with the front rotary shaft 32, the interlocking shaft 412, and the interlocking shaft 411 and the vertical rotating shaft 42 to which the rotational force of the front rotating shaft 32 is transmitted through the normal power transmission unit 411. And a pair of gears 413 interlocked between each other to change the horizontal rotation of the linkage shaft 411 to the vertical rotation of the vertical rotation shaft 42. The method of claim 5, wherein the pair of gears 413, Separation device characterized in that consisting of the worm gear mounted to the interlocking shaft (411) and the worm wheel is mounted to the vertical rotating shaft (42) to engage with the worm gear. The inside of the said network cylinder 2 is a method as described in any one of Claims 1-3, It is supported by an external support 221 is rotated through the connection with the drive motor 222 and is inserted into the mesh constituting the mesh cylindrical body 2 on the outer surface is provided with a plurality of brushes 223 for opening the blocked network. Separating device, characterized in that it is provided with one or more brush shafts 22. The outer side of the said net cylinder 2 is a structure as described in any one of Claims 1-3, It is supported by the outer support 72, is provided in parallel with the mesh cylindrical body 2 is rotated through the connection with the drive motor 73, the operation shaft 711 is provided with a plurality of cams 712 at equal intervals And a striking portion fixed to the inclined working shaft and provided with the striking portions 714 provided in correspondence with the cams 712 to interlock with the rotation of the cams 712 to strike the outside of the mesh cylinder. Separating device characterized in that it is further provided with at least one striking device (71) consisting of a shaft (713). The method of claim 8, wherein the hitting portion 714, The cam shaft 713 is rotatably inserted into the fixed shaft 713 and the outer side includes a cam operating table 717 repeatedly rotating downward to rotate the inner striking part 716 upward. Strike table 715, and provided between the lower portion of the inner striking table 716 and the upper portion of the support 72 is composed of a spring 718 to lower the inner striking portion 716 to the lower to enable the striking Sorting device characterized in that. The outer side of the said net cylinder 2 is a structure as described in any one of Claims 1-3, It is supported by an external support (75) is rotated through the connection with the drive motor 76, the outer surface is provided with a plurality of brushes 741 is inserted into and removed from the network constituting the network cylindrical body to open the blocked network. Separating device, characterized in that one or more brush shafts 74 are further provided.