JPH0416273A - Apparatus for sorting cullet by color - Google Patents

Abstract

PURPOSE:To accurately discriminate a color by a method wherein cullet to be treated is supplied to a color discriminating belt conveyor while the particle size thereof is arranged and the center part of all of the cullet is grasped by a color discriminating sensor. CONSTITUTION:Cullet is arranged in its size by a rotary type dimension sorting apparatus l to be successively supplied to color discriminating belt conveyors 16, 25, 33, 42. Slits are formed to the center parts in the lateral direction of the endless annular belts 19, 28, 36, 45, used in the color discriminating belt conveyors 16, 25, 33, 42 over the entire peripheries thereof, and color discriminating sensors 21, 29, 37, 46 are arranged so that emitted lights pass through the slits are provided to the midway parts near to the front end parts in the advance direction of the color discriminating belt conveyors 16, 25, 33, 42. Therefore, the center part of the fed cullet is necessarily grasped by the color discriminating sensors 21, 29, 37, 46. By this method, a color can accurately be discriminated.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to a cullet color sorting device. be.

``Prior Art'' When cullet (product glass waste) is to be reused, it is necessary to sort it by color, but in the recovery stage, various colors are mixed. Conventionally, a device as shown in FIG. 4 has been used as a device for sorting cullet, which is a mixture of various materials, according to each color.

In FIG. 4, A is a belt conveyor for color identification;
- a pair of endless annular belts B and a pulley C that rotates the belt,
C (one side is omitted in the figure). D is a color identification sensor, which uses a phototube with a structure that identifies colors based on the amount of light.

The color identification sensor D is disposed in front of the color identification belt conveyor A, and is configured to detect the cullet E immediately after it slides down from its front end. Note that the separation device and the like are omitted in the figure.

However, such a conventional device is a belt conveyor A for color identification.
The cullets being conveyed above are irregular in size, and the color identification sensor D is located in front of the color identification belt conveyor A and is designed to detect the force of 1/7 of the falling state. It is practically impossible for the color discrimination sensor D to capture the center of all the cullets E.

Therefore, the color identification sensor D could not accurately identify colors.

"Problems to be Solved by the Invention" The present invention has been made in view of the above points, and comprises a color identification belt conveyor using an endless annular belt having a slit extending all around the width at the center of the width direction. , a color identification sensor whose emitted light passes through a slit in the endless annular belt is disposed at a midway point near the front end of the color identification belt conveyor in the traveling direction; and further, a cullet to be processed by the color identification belt conveyor. The purpose of the present invention is to provide a cullet color sorting device that allows a color identification sensor to always capture the center of all cullet by supplying grains of the same size. .

``Means for Solving the Problems'' The gist of the present invention is to provide a rotary size sorting device that sieves cullet introduced into a cullet input hopper into cullet of each size, and a device that accommodates the sieved cullet of each size. a cullet supply hopper that supplies the cullet to the cullet alignment lane described later; a cullet alignment lane that aligns the cullet supplied from the cullet supply hopper in a line;
a conveying belt conveyor for conveying the cullets sequentially sent out from the cullet alignment lane onto a first color identifying belt conveyor described later; and a first color conveyor for identifying the color of the cullet received from the conveying belt conveyor. A first separating device consisting of a slide and a separation chute that go up and down at predetermined timing, a second color identification belt conveyor for identifying the color of cullet supplied via the slide of the first separating device, and the second color. A second separation device having the same structure as the first separation device, which is disposed in front of the identification belt conveyor in the traveling direction, and a third color identification device that identifies the color of the cullet falling from the separation chute of the second separation device. disposed in front of the third color identification belt conveyor and the third color identification belt conveyor in the traveling direction;
a third separation device having the same structure as the first separation device; a fourth color identification belt conveyor for identifying the color of the cullet supplied via the slide of the second separation device; and the fourth color identification belt conveyor. a fourth separating device having the same structure as the first separating device, which is disposed forward in the traveling direction, and each of the first to fourth color identification belt conveyors is used as an endless annular belt with a width A color identification sensor is installed near the front end of the color identification belt conveyor in the direction of movement, using a heald with a slit extending all around the center of the direction, and disposed so that the emitted light passes through the slit. There is a cullet color sorting device disposed in the middle of the cullet.

"Example" Examples of the present invention will be described below.

Fig. 1 is a layout diagram schematically showing a cullet color sorting device according to the present invention, Fig. 2 is a perspective view of the present invention with some parts omitted, and Fig. 3 is a color identification belt conveyor. It is a partially enlarged perspective view.

In the figure, reference numeral 1 denotes a rotary size-based sorting device, which separates cullet of irregular grain size introduced into the cullet input hopper 2 according to each size. Further, the rotary size-based sorting bag f1 has a cylindrical shape and has sieve portions 3, 4, 5.6 formed such that the openings thereof become larger sequentially along the axial direction. In addition, the sieve part 3 near the cullet input hopper 2
is the smallest one.

Further, the rotary size sorting device 1 is rotated at a predetermined speed by a rotation drive device (not shown).

7 is a discharge port for cullet whose grains are larger than expected. 8 is a cullet supply hopper, 8a is a discharge port for small diameter cullets that cannot be sorted, and 8b is a cullet supply port.

Reference numeral 9 denotes a supply port opening/closing device provided at each of the cullet supply ports 8b, 8b, 8b.

Numeral 10 is a cullet alignment lane, which is used to align the cullet discharged from the cullet supply ports 8b, 8b, 8b in a line.

Further, each of the cullet alignment lanes 10 has one end facing the cullet supply ports 8b, 8b, 8b, and the other end facing one end of a conveyor belt to be described later.

Reference numeral 11 denotes a conveyor belt conveyor, which is composed of a driving pulley 12, a driven pulley 13, and an endless annular belt 14 that is wound around these pulleys.

The transport belt conveyor 11 moves at a low speed, receives the cullet sent out from the cullet alignment lane 10, and transports it to the belt conveyor for first color lk to be described later.

15 is a rotational drive device for the drive pulley 12.

16 is a belt conveyor for color identification. The color identification belt conveyor 16 is for separating glass and ceramics. In addition, the first color identification helmet conveyor 16
consists of a driving pulley 17, a driven pulley 18, and an endless annular heald 19 hooked onto these and rotated, and the traveling speed is about 10 times that of the conveying heald converter hair 11.

Further, the endless annular belt 19 has a slit 20 formed at the center in the width direction extending all around the circumference.

Furthermore, a color identification sensor 21 whose emitted light passes through a slit 20 of the endless annular belt 19 is located in the middle of the first color identification hair conversion hair 16 near the front end in the traveling direction.
has been set up.

Reference numeral 22 denotes a first separation device, which is provided between the first color identification belt conveyor 16 and the second color identification belt conveyor described later.

The third separation device 22 includes a slide 23 that moves up and down at a predetermined timing based on a signal from the color identification sensor 21;
It consists of a separation chute 24 provided at the bottom of the slide 23.

When the color identification sensor 21 determines that the conveyed object is ceramics, the first separation device 22 moves the slider 2
3 rises, slides down from the front end of the first color identification belt conveyor 16, and drops it into the separation chute 24. On the other hand, when the conveyed object is a cullet, the slide 23 remains in the same position so that the cullet slides on its upper surface and falls onto the next color identification belt conveyor. be.

Incidentally, the slide 23 is raised and lowered using a solenoid or the like.

Reference numeral 25 denotes a second color discrimination helmet, which distinguishes between transparent colorless and spring-colored cullet and green and brown cullet.

Further, the second color identification belt conveyor 25 includes the second color identification belt conveyor 25.
It has the same structure as the color identification belt conveyor 16. Therefore, detailed explanation will be omitted.

Note that 26 is a driving pulley, 27 is a driven pulley, 28 is an endless annular belt, and 29 is a color identification sensor.

A second separation device 30 has the same structure as the first separation device 22. Therefore, detailed explanation will be omitted.

In addition, 31 is a slide, and 32 is a separation chute.

33 is a belt container for third color identification disposed below the separation chute 32 of the second separation device 30, and from among the cullets that have fallen from the separation soyute 32, brown cullet 7 and green cullet are detected. It is used to identify the

Further, since the third color identification heel conveyor 33 has the same structure as the first color identification heel conveyor 1G, detailed explanation will be omitted.

Note that 34 is a driving pulley, 35 is a driven pulley, 36 is an endless annular belt, and 37 is a color identification sensor.

On the 3rd, there is a third separation device, and the third separation bag! Since it has the same structure as No. 22, detailed explanation will be omitted.

In addition, 39 is a slide, 40 is a separation chute into which green cullet falls, and 41 is a separation chute into which brown cullet falls.

Reference numeral 42 denotes a fourth color identification helmet disposed at the front lower part of the slide 31 of the second separation device 30;
Among the cullet that slides down from 1, transparent colorless cullet and clear water-colored cullet are distinguished.

Furthermore, since the fourth color identification belt conveyor 42 has the same structure as the first color identification belt conveyor 16, detailed description thereof will be omitted.

Note that 43 is a driving pulley, 44 is a driven pulley, 45 is an endless annular belt, and 46 is a color identification sensor.

Reference numeral 47 denotes a fourth separation device, which has the same structure as the first separation device 22, so detailed explanation will be omitted.

In addition, 48 is a slide, 49 is a separation chute into which clear water-colored cullet falls, and 50 is a separation chute into which transparent colorless cullet falls.

Next, the operation of the above device will be explained.

When cullet containing a mixture of various substances is charged into the cullet input hopper 2, the cullet is sieved according to each size by the sieve section of the rotary size sorting device 1. Cullets that are too large are discharged from the discharge lower, and cullets that are too small to be sorted are discharged from the discharge port 8a of the cullet supply pumper 8.
are discharged from each.

The cullet screened as described above is supplied from the cullet supply port 8b of the cullet supply hopper 8 onto the cullet alignment lane IO.
They are aligned in a line on 0.

Next, the cullets on the cullet alignment lane 10 are sent out one after another onto the conveyor belt 11, and the cullets placed on the conveyor belt 11 are further transferred onto the first color identification belt conveyor 16. will be moved to

Incidentally, the advancing speed of the first color identification helmet converting hair 16 is as follows:
Since the speed is about 10 times that of the conveyor belt conveyor 11, the cullet transferred from the conveyor belt conveyor 11 is
It is placed on the first color identification hair 16 at a considerable distance.

When the cullet on the first color identification belt conveyor 16 reaches the position of the color identification sensor 21, the color is identified by the color identification sensor 21.

If the conveyed object is ceramics, the slide 23 of the first separation device 22 is raised, and the ceramics are dropped into the separation chute 24.

On the other hand, when the conveyed object is a cullet, the slide 23 remains in the same position, and the cullet is slid onto it and placed on the second color identification belt conveyor 25.

The second color identification heat conversion hair 25 distinguishes transparent colorless and clear water color cullet from green and brown cullet, and cooperates with the second separation device 30 to separate green and brown cullet for third color identification. Drop it onto the belt conveyor 33,
Further, the transparent colorless and clear water color cullets are guided onto the fourth color identification heat conversion hair 42.

The cullets dropped onto the third color identification belt conveyor 33 are further passed through a third separating device 38, where green cullets are dropped into a separation chute 4°, and brown cullets are caused to fall into a separation shade 41. .

On the other hand, the cullets on the photocondensed hair 42 for fourth color identification are caused to fall through a fourth separating device 47, with clear water-colored cullets falling into a separating chute 49 and transparent and colorless cullets falling into a separating chute 50. be.

As described above, the cullet, which is a mixture of various materials, is finally sorted according to each color.

However, the most distinctive feature of the present invention is that the sizes are made uniform by a rotary size sorting device, and the sizes are sequentially supplied to the color identification belt conveyor 16.25° 33.45°. Color identification belt conveyor 16, 2
5, 33.45 is the endless annular bell used there) 19.
2B, 36° 45, with a slit formed all around the center in the width direction, and the color identification sensor 2 is arranged so that the emitted light passes through the slit.
1, 29, 37. 46 is the color identification belt conveyor 16
, 25, 33, 45 in the middle of the front end in the direction of movement, so that the color identification sensor 2129, 37, 46 can always capture the center of each cullet being transported.

"Effects of the Invention" Since the present invention has the above-described configuration and operation, the color identification sensor can always detect the center of each cullet being transported. Therefore, colors can be identified much more accurately than conventional devices.

[Brief explanation of drawings]

Fig. 1 is a layout diagram schematically showing a cullet color sorting device according to the present invention, Fig. 2 is a perspective view of the present invention with some parts omitted, and Fig. 3 is a color identification belt conveyor. FIG. 4 is a partially enlarged perspective view of a conventional color identification belt conveyor. DESCRIPTION OF SYMBOLS 1... Rotary size sorting device, 2... Cullet input hopper, 3.4, 5.6... Sieve part, 8... Cullet supply hopper 8b... Cullet supply port, 10...
・Cullet alignment lane, 11... Belt conveyor for conveyance, 16... Belt conveyor for first color identification, 17...
- Drive pulley, 18... Driven pulley, 19... Endless annular heald, 20... Slit, 21... Color identification sensor 22... First separation device, 23... Slide, 2
4...Separation chute, 25...Heart conversion hair for second color identification, 29...Color identification sensor 30...Second separation device, 33...Heart conversion hair for third color identification, 3
7...Color identification sensor 3rd...Third separation device, 4
2... Fourth color identification belt conveyor, 46... Color identification sensor 47... Fourth separation device.

Claims (1)

[Claims] A rotary size sorting device that sieves the cullet introduced into the cullet input hopper into cullet of each size, a cullet supply hopper that accommodates the sieved cullet of each size and supplies it to the cullet alignment lane described later, and the cullet supply A cullet alignment lane for arranging the cullets supplied from the hopper in a line, a conveyor belt for conveying the cullets sequentially sent out from the cullet alignment lane onto a first color identification belt conveyor described later, and the conveyor belt. A first color identification belt conveyor that identifies the color of cullet received from the conveyor, and a second color identification belt conveyor that is disposed between the first color identification belt conveyor and a second color identification belt conveyor described later, and is raised and lowered at a predetermined timing. A first separation device consisting of a slide and a separation chute, a second color identification belt conveyor for identifying the color of cullet supplied via the slide of the first separation device, and progress of the second color identification belt conveyor. a second separating device disposed in front of the first separating device and having the same structure as the first separating device; a second color identification belt conveyor for identifying the color of the cullet falling from the separation chute of the second separating device; A third separation device having the same structure as the first separation device, which is disposed in front of the third color identification belt conveyor in the traveling direction, and a third separation device that identifies the color of the cullet supplied through the slide of the second separation device. It consists of a fourth color discrimination belt conveyor, and a fourth separation device disposed in front of the fourth color discrimination belt conveyor in the traveling direction and having the same structure as the first separation device, and further includes a fourth separation device having the same structure as the first separation device, and A color identification method in which each of the four color identification belt conveyors is an endless annular belt having a slit extending all around the width at the center thereof, and the emitted light beam is arranged so as to pass through the slit. A cullet color sorting device comprising a sensor disposed in the middle of the color discrimination belt conveyor near the front end in the direction of movement.