KR20070055358A - Classifier - Google Patents

Abstract

It does not reduce the recovery rate of heavy specific gravity, and prevents citrate specific gravity from mixing in heavy specific gravity.

The sedimentation velocity is provided by providing an upward flow generating tube 8 for generating an upward flow in the water tank 2 and a suction pipe 9 for sucking upward of the medium-heavy gravity specific material B floating below the water surface by this upward flow. The floating medium diameter specific gravity B is suspended below the surface of the water in an upward flow to be sucked out of the suction pipe 9 to prevent it from entering the specific gravity A while settling on the bottom of the water tank 2, Even if the heavy specific gravity A enters into the suction pipe 9 by the upward flow, it is not sucked upward from the suction pipe 9 but settles out of it, and it does not lower the recovery rate of the heavy specific gravity A, but does not reduce the specific gravity specific gravity. The water (B) can be prevented from mixing in the heavy gravity substance (A).

Upflow, suction tube, specific gravity, conveyor, sorting, size sorting, sedimentation, recovery

Description

Screening unit {CLASSIFIER}

1 is a process chart showing a process in which a mixture introduced into a sorting apparatus of a first embodiment is separated from building waste materials,

2 is a longitudinal sectional view showing a sorting device of a first embodiment;

3 is a cross-sectional view taken along the line III-III of FIG. 2,

4 is a longitudinal sectional view showing the second embodiment;

5 is a longitudinal sectional view showing the third embodiment;

6 is a longitudinal sectional view showing a fourth embodiment;

7 is a longitudinal sectional view showing the fifth embodiment;

8 is a longitudinal sectional view showing the sixth embodiment;

9 is a plan view of FIG. 8,

10 is a partially omitted longitudinal cross-sectional view showing the first modification of the sixth embodiment,

11 is a partially omitted longitudinal cross-sectional view illustrating a second modification of the sixth embodiment;

12 is a longitudinal sectional view showing the seventh embodiment;

13 is a longitudinal sectional view showing the eighth embodiment;

14 is a partial perspective view of an example of a suction tube.

<Description of the code>

A, A ', A' ': Heavy specific gravity B: Chongqing specific gravity

C: light specific gravity D: mixture

DESCRIPTION OF SYMBOLS 1 Wet sorting apparatus 2 Water tank 2a Supply stage 2b Discharge stage 3 Basket 3a Supply stage 3b Discharge stage 4 Partition plate 5 Suit 6 Inclined screen 7 Vibration generating means 8, 8 ₁ , 8 ₂ ‥: Upflow generating tube 8a: Opening of upflow generating tube 9, 9 ₁ , 9 ₂ ‥: Suction tube

9a: opening of suction pipe 10: conveyor

11, 11a: discharge screw 11b: outlet

12 pump 13 filter

14 storage portion 15 discharge screw

15a: opening 15b: outlet

16: Duc 17: Flexible Cover

18 nozzle 21 21 crusher 22 sieve 23 charity 24 crusher 25 sieve

The present invention relates to a wet sorting device for sorting a mixture by specific gravity in a water bath.

As a sorting apparatus for a mixture using specific gravity, a wet sorting apparatus that floats and precipitates a mixture by specific gravity in a water tank is used in various fields.

This wet sorting apparatus is used in the field of separating heavy gravity heavy matters from foreign materials such as gravel and iron strips as foreign matters, for example, when obtaining wood chips as a raw material for papermaking. In order to effectively collect the wood chips, a lifting conveyor is installed in the tank, and the water in the tank is sucked from the rear part of the conveyor and supplied to the lower part of the vertical pipe of the tank in which the heavy gravity material is settled. To generate wood chips of medium-weight specific gravity that settle in the vertical barrel, and to lift them up to the conveyor.

Moreover, in the waste processing field, the aggregate which is a heavy specific gravity of 2.5 or more specific gravity is collected from concrete which is a construction waste material, and is recycled. The recovered aggregate is mixed with plastic pieces and wood pieces. The plastic pieces in the mixture contain light specific gravity materials having a specific gravity less than 1, such as polypropylene resins and polyethylene resins, and medium diameter specific gravity materials having a specific gravity greater than 1, such as vinyl chloride resins. In addition, damp wood has a specific gravity greater than 1 and can be mixed into it as a medium-weight heavy matter. When the aggregate is selected from the mixture in which the medium-weight specific gravity is mixed by using a wet sorting apparatus, the sedimentary medium-weight specific gravity is mixed into the aggregate, which causes a problem in that the precision of selection of the aggregate is deteriorated.

Furthermore, clay shooting ranges recover coal pellets scattered in the soil field, and it is desired to precisely sort pellets from the mixture of the soil and pellets together as a heavy specific gravity and soil as a heavy gravity specific gravity.

In the above waste treatment field or clay shooting range, when the heavy gravity material is selected from the mixture by using a wet sorting device, in order to prevent the middle gravity material having a specific gravity greater than 1 from being mixed in the heavy gravity material, the sedimentary heavy gravity material It is possible to consider adopting a method of pushing back to the upstream and pushing it up to the conveyor, where the specific gravity of being pushed back to the upstream may be lifted up on the conveyor. Therefore, there is a problem that the recovery rate of the heavy gravity product is lowered.

Accordingly, an object of the present invention is to prevent the medium-weight specific gravity from being mixed into the heavy specific gravity without reducing the recovery of the heavy specific gravity.

In order to solve the above problems, the present invention is to remove and remove the medium-weight specific gravity which floated in the upward flow by the suction pipe, and to remove the heavy specific gravity entered into the suction pipe by its own weight to return to the tank. .

In this case, since the heavy specific gravity returns to the tank without being sucked, the heavy specific gravity settled in the tank may be recovered in the same manner as in the prior art.

In the constitution of the present invention, in the sorting apparatus for introducing a mixture to be sorted into a water tank and sorting the heavy gravity material in the mixture settled to the bottom of the tank by the specific gravity difference, an upward flow which generates an upward flow in the water tank. The generating pipe and the suction pipe which suck the floating material floating in water by the upward flow upward from a downward opening are provided, and the suction force of the suction pipe is set so that it may settle in self weight even if the said heavy gravity material enters the suction pipe.

Since the suction force of the suction pipe is determined by the circulation cross-sectional area of the suction pipe, the suction flow rate, the ability of the suction pump, and the like, they are appropriately set by experiment, actual operation, and the like so that the heavy gravity material may settle down even if it enters the suction pipe.

For example, when the suction flow rate of the suction pipe is slowed down compared to the flow rate of the upstream flow, the mixture containing the heavy specific gravity rises by the upward flow, and even if the mixture is sucked into the suction pipe, the flow rate in the suction pipe is slow, so that the specific gravity in the mixture is self-weighting. It sinks below the suction pipe. That is, since the suction flow rate is slower than the flow rate of the upward flow, the heavy gravity material lifted by the strong upward flow is not sucked into the weak suction flow but is settled below the suction pipe by its own weight to precisely sort.

As means for slowing down the suction flow rate than the flow rate of the upward flow, for example, the opening area of the upward flow generating tube can be considered to be smaller than the circulation cross-sectional area of the inlet portion of the suction pipe that sucks upward from the opening of the suction tube. When the opening area (distribution cross-sectional area) is changed in this way, since the upward flow is generally generated from the opening of the upward flow generating tube, the mixture containing the heavy specific gravity may rise with the upward flow and enter the suction pipe. Since the suction flow rate is slower than the ascending flow rate during the suction, the heavy specific gravity is not sucked further into the suction tube and is settled below the suction tube by its own weight. This flow cross sectional area difference is effective when the same flow rate flows through the upward flow generating tube and the suction tube.

The length of the inlet portion of the suction pipe (see L in FIG. 2) is appropriately set in consideration of the flow velocity and the like by experiments so that the heavy gravity substance entering the inlet portion is smoothly settled by its own weight.

The opening of the upward flow generating tube may be any position in the tank as long as the opening generates the upward flow in the water tank. However, a position for smoothly floating the mixture introduced into the water tank by the upward flow by experiment, actual operation or the like is appropriately set.

The positional relationship between the opening of the upward flow generating tube and the opening of the suction tube is set such that the two openings face each other at an appropriate distance and angle by experiment, actual operation, etc. so as to smoothly suck the floating matters in the water under the upward flow. In this case, it is preferable to set it as the positional relationship in which all the mixtures except heavy specific gravity and only a part of heavy specific gravity are attracted.

In these configurations, the inside of the water tank may be partitioned into a plurality of rows by, for example, a vertical partition plate along the flow direction of the mixture, and the suction pipe may be provided in each of the partitioned rows.

In this case, since the upward flow is rectified by the partition plate, the medium-heavy gravity specific material can be stably suspended.

At this time, the size of the mixture introduced into the water tank is previously sized by a sieve, and these size-divided mixtures are separately added to each of the partitioned rows, so that the sorting accuracy with a predetermined specific gravity can be increased. That is, when the mixtures are the same size, the buoyancy force received by the mixture by the upflow is almost the same, and the medium-heavy gravity specific gravity easily rises due to the difference in the self-loading sedimentation force due to the specific gravity difference, and the heavy specific gravity easily precipitates.

On the other hand, the smaller the size, the smaller the buoyancy received, and the sedimentation force due to its own weight is greatly lowered. Therefore, when the size classification is not performed, the small sized heavy gravity material is attracted to the suction pipe together with the mixture of larger size and smaller specific gravity. It may be discharged to the outside.

Therefore, when size classification is performed, the strength of the upward flow in each column is changed to separate the heavy specific gravity and the medium diameter specific gravity for each size into the sedimentation side and the rising side only by the difference in specific gravity, and the influence of the difference in size It is possible to increase the sorting accuracy by reducing the number.

On the other hand, the upward flow may be generated in one upward flow generating tube, but the upward flow generating tube may be provided for each of the partitioned columns, or the upward flow generating tube may be provided for two or more rows. In the latter case, the openings of one upward flow generator tube come into two or more rows.

The suction pipe may be installed in plural numbers in a direction toward the flow direction of the mixture. In this way, the suction force of the suction tube is gradually increased (strengthened) toward the flow direction of the mixture, that is, the suction force of the suction tube is lowered (captured) from each suction tube by increasing the suction force of the suction tube on the downstream side than the upstream side of the flow of the mixture. The specific gravity can be changed, so that the specific gravity can be selected and captured. The number of suction tubes is appropriately set according to the number of specific gravity differences to be captured.

At this time, an upward flow generating tube is provided for each of the suction pipes, and the upward flow by each rising flow generating tube is set to be counted in order (to increase the speed of the rising flow in order) in the flow direction of the mixture. According to the specific gravity of the thing, smooth floating and suction can be performed.

For example, if two upflow generating pipes are installed, the medium (or heavy) heavy materials such as plastic having a specific gravity greater than 1 are sucked into the suction pipe at the front side (upstream of the flow of the mixture). Aspirates relatively heavy specific gravity such as aggregate among unabsorbed heavy specific gravity, and it is aspirated by heavy gravity heavy material with very high specific gravity and metals such as iron, copper and lead which are not attracted to the front and rear suction pipes It can be selected into three kinds of medium specific gravity having a relatively small specific gravity of the aggregate and the like, and medium diameter specific gravity sucked by the suction tube of the front side.

Moreover, since the floating material which is not attracted by the front suction pipe can be sucked by the rear suction pipe without changing the suction force of each suction pipe, the said sorting precision can be improved.

Furthermore, by providing upward flow generating tubes for each of the suction pipes, the mixture can be smoothly floated and introduced into each suction pipe, and the sorting accuracy can be further improved.

Also in these cases, the positional relationship between the opening of the upflow generating tube and the opening of the suction tube does not suck the required specific gravity as much as possible, and it is possible to smoothly suck the floating material of the required specific gravity suspended in the water by the upstream flow. The two openings are set to face each other at an appropriate distance and angle by operation or the like.

When each of the openings of the upward flow generating tube and the suction tube is formed to have a long hole shape (not only an elliptic shape, but also a rectangular shape) that is transverse to the flow direction of the mixture, the upward flow is in the tank. The narrow width results in a clear flow, and the suction flow also becomes narrow in the flow direction of the mixture, so that the suction action is assured.

The length of the hole is appropriately set in accordance with the transverse length with respect to the flow direction of the mixture and the width of the water tank. In addition, the width of the long hole is appropriately set in consideration of the degree of formation and the degree of suction.

In these configurations, an inclined screen whose lower end is opened as a discharge end between the upward flow generating tube and the suction tube in the water tank is inclined downward toward the flow direction of the mixture, and the mixture is provided on the upper side of the inclined screen. By inputting, the specific gravity material from the discharge end of the lower side can be settled to the bottom of the tank.

In this case, since the mixture settled in the collective state on the inclined screen rises as it is stirred by the upward flow, the medium-weight specific gravity is separated smoothly, and the heavy specific gravity falls on the screen as it is to the bottom of the tank. Sink. In other words, the separation of the medium-heavy gravity heavyweight and the heavy gravity heavyweight is facilitated, and the upward flow may be caused to hit the mixture settled in the collective state, so that the amount of the upward flow (water quantity) can be reduced (less upward flow). To efficiently float the mixture).

At this time, if the opening of the upward flow generating tube is provided below the inclined screen at a predetermined position in the inclined direction, for example, at the discharge end, the middle-heavy gravity heavy material is generated only by generating the upward flow in a part of the water tank. It can float below the surface of the water and reduce the amount of upstream water. In this case, the upward flow generating tube may be opened at another position below the inclined screen.

By providing a means for imparting vibration to the inclined screen, the medium-heavy gravity specific material settling onto the screen can be reliably suspended in an upward flow, selectively sucked into the suction pipe, and the sorting accuracy can be further improved. It can also prevent screen clogging.

By installing the reservoir portion of the mixture introduced at the upper end side of the inclined screen, the mixture weights the heavy specific gravity downward and the middle diameter specific gravity upward by the self-weight difference while reaching this storage portion, and then to the upper side of the gradient screen. Since it moves, the middle diameter specific gravity material which is unevenly distributed on the upper side can be floated smoothly by an upward flow, and it can make it easy to be attracted to a suction pipe.

At this time, if the storage portion is continuous to the inclined screen, the storage portion also vibrates as the inclined screen vibrates, so that the mixture that reaches the storage portion causes the heavy specific gravity to the lower side and the middle diameter specific gravity to the upper side by the vibration. The ubiquitous action is promoted.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described with reference to drawings. 1 to 3 show a first embodiment. This sorting apparatus 1 is used for the collection | recovery equipment of the aggregate contained in the concrete which is a construction waste material, and removes the wood piece or plastic piece mixed with aggregate.

As shown in FIG. 1, the concrete is crushed in the crusher 21, and after the large foreign matter is removed by hand sorting, it is caught by the sieve 22 to remove the micro foreign matter having a size of about 2 mm or less, and exceeding 40 mm. The large shreds are returned to the shredder 21 and shred again. The crushed material having a size of 40 mm or less is removed from iron by the charity 23, and then rubbed with each other in the crusher 24 to remove cement mortar adhering to the aggregate, and the sieve 25 is reduced to five types. Lose.

In this embodiment, it is estimated to be less than 7 mm, 7-13 mm, 13-20 mm, 20-28 mm, 28-40 mm, and is put in the wet sorting apparatus 1. The processed material put into this wet sorting apparatus 1 is the mixture (D) in which the wood piece or the plastic piece was mixed in aggregate.

As shown in Figs. 2 and 3, the wet sorting device 1 moves up and down in a square basket 3 as viewed in a horizontally open top opening in a rectangular water tank 2 in a horizontally long plane. The basket 3 is hung as much as possible, and is partitioned into five rows in the transverse direction (left and right direction in FIG. 3) by the vertical partition plate 4, and in each of these rows is deduced in five kinds of sizes from the sieve 25. The mixture D is intended to be introduced from the chute 5.

On the other hand, the partition position of each partition plate 4 is variable, and the width | variety of each column can be adjusted according to the throughput in each size of a mixture.

In addition, the bottom of the basket 3 is provided with an inclined screen 6 inclined downward from the supply end 3a into which the mixture D is introduced, to the discharge end 3b on the other end side, and the inclined screen 6 has a basket. Vibration is imparted by the vibration generating device 7 via (3). This vibration generating means 7 vibrates the basket 3 by moving the basket 3 up and down by changing the contact position with the basket 3 by the vibration transmission plate 7a circular motion (refer the arrow of FIG. 2).

Each row of the basket 3 partitioned by the partition plate 4 includes an upwardly open upward flow generating tube 8 which generates upward flow from below during the inclination of the inclined screen 6, and a submerged flow path underwater. The suction pipe 9 which is opened downward to suck the floating water suspended in the water is provided. The upward flow generating tube 8 and the suction tube 9 face each other in an oblique direction, and the distance between the two openings 8a and 8b is set to a distance at which the upward flow is not weakened. In addition, the lower end side of the inclined screen 6 is open at the discharge end 3b of the basket 3, and a conveyor 10 for lifting up the floating object on the water surface is installed near the outer surface of the basket 3, and at the same time, the discharge end 3b. At the bottom of the water tank 2 of the side), the discharge screw 11 which discharges a sediment is provided.

Among the mixtures (D) introduced from the chute (5) into each row of the basket (3), the specific gravity (A) such as aggregate is quickly settled on the inclined screen (6) to discharge the inclined screen (6) on the discharge end ( After moving downward to 3b) side, the lower end side is settled and collect | recovered by the discharge screw 11 which rotates by sinking to the bottom of the water tank 2 from the open end 3b. Some of the heavy specific gravity (A) is suspended in the water by the upward flow from the upward flow generating tube (8) during the downward movement on the inclined screen (6), the upward flow obliquely upward toward the suction pipe (9) Cannot settle and settles on the inclined screen 6.

In addition, even if the heavy specific gravity A flows and is sucked into the suction pipe 9, the suction pipe 9 opens downward and inclines upward from the opening 9a, so that the sedimentation force due to its own weight is buoyant due to suction (suction force). More than) and settles on the downward inclined screen 6 again.

On the other hand, the inclination angle upward of the suction pipe 9 can be adjusted, and the boundary of the specific gravity of whether the suction pipe 9 is attracted or not can be adjusted. As the angle of inclination upward of the suction pipe 9 is set to a gentle inclination, the suction pipe 9 is sucked up to a larger specific gravity.

In addition, the flow rate of the upward flow and the flow rate in the suction pipe 9 are set larger as the size of the mixture is larger.

Moreover, the upflow from the upflow generating tube 8 and the suction flow of the suction pipe 9 are formed by one pump (see FIG. 5) or by different pumps, respectively. At that time, even if the suction force (suction flow rate) of the suction pipe 9 is settled even if the heavy gravity material A enters the suction pipe 9, the circulation cross-sectional area of the suction pipe 9, the capacity of the pump, and the like are appropriately set. In addition, the flow cross sectional area of the upward flow generating tube 8 is set as appropriate.

The medium-weight specific gravity (B) having a specific gravity greater than 1 among the wood pieces or plastic pieces included in the injected mixture (D) is gently settled and moved downward on the inclined screen (6). It floats in water by the upward flow from 8), is attracted by the suction pipe 9, and is discharged | emitted to the outside. In addition, the light specific gravity (C) having a specific gravity less than 1 floats on the surface of the water and moves toward the discharge end 3b, and is lifted up on the conveyor 10 to be discharged to the outside.

On the other hand, since the vibration is applied to the inclined screen 6, the middle diameter specific gravity B naturally becomes the upper side due to the vibration even if it is the lower side of the heavy specific gravity A having a large specific gravity, so that it can be reliably floated by the upward flow. Can be. In addition, the eye of the inclined screen 6 is not blocked.

4 shows a second embodiment. This sorting apparatus also sorts aggregate from the mixture (D) mainly composed of aggregate, and inclined screen (6) at the bottom of the horizontally long basket (3) suspended in the horizontally long tank (2) as in the first embodiment. ) Is provided, and an upflow generating tube (8) for generating an upward flow from below during the inclination of the inclined screen (6), and a suction pipe (9) for sucking floating matter floating under the water surface in the upward flow. .

The basket 3 is not partitioned, and the mixture introduced from the chute 5 to the feed end 3a is not classified by size, and the heavy specific gravity A is settled on the inclined screen 6. After moving downward, it is settled to the bottom of the water tank 2 from the discharge end 3b, and it collect | recovers and collect | recovers by the discharge screw 11. In addition, the medium-weight specific gravity B is settled down on the inclined screen 6 and moved downward, and floating in the middle of the surface under the surface by the upflow from the upward flow generating tube 8, being sucked by the suction pipe 9 to the outside. It is discharged to, the light specific gravity (C) is floated on the water surface to move toward the discharge end (3b) side and lifted on the conveyor 10 is discharged to the outside.

In addition, even when the heavy specific gravity A is sucked into the suction pipe 9 through the flow, the settling force due to its own weight is higher than the buoyancy force (suction force) due to the suction, and again settles on the downwardly inclined screen 6.

5 shows a third embodiment. This sorting device (1) is free of the basket (3), and has a plurality of upward flow generating tubes along the bottom inclined downward from the supply end (2a) side of the horizontally long water tank (2) to the discharge end (2b) side ( 8) is arranged to cover almost the entire front of the floor. Under the water surface, the same suction pipe 9 as in the second embodiment is opened downward, so that water in the water tank 2 is sucked into the suction pipe 9 by the pump 12, and the sucked water passes through the filter 13 The medium diameter specific gravity B is removed and then circulated, and discharged to generate an upward flow from each upward flow generating tube 8 into the water tank 2 again. Moreover, the conveyor 10 which raises the floating object on the water surface is provided near the water surface of the discharge end 2b side, and the discharge screw 11 is provided in the bottom of the discharge end 2b side.

In the present embodiment, in the mixture D introduced from the chute 5 to the supply end 2a of the water tank 2, the sediment-heavy heavy material A is inclined downward toward the discharge end 2b. The middle-heavy specific gravity B, which is selectively collected and recovered from the discharge screw 11 by moving downward at the bottom, is suspended in water by the upward flow from each upward flow generating tube 8, and Aspirated and discharged to the outside. In addition, the light specific gravity (C) that floats on the water surface is lifted up on the conveyor 10 is discharged to the outside. Moreover, even if the heavy specific gravity A is drawn into the suction pipe 9 through the flow, the sinking force due to its own weight exceeds the buoyancy force (suction force) due to suction, and then sinks on the bottom surface of the water tank 2 again. It moves toward the discharge screw 11 by inclination.

FIG. 6 shows a fourth embodiment, and this sorting device 1 is provided with a plurality of suction pipes 9 in sequence in the flow direction of the mixture D in a plan view of the water tank 2, and at the same time, each suction pipe. (9 ₁ , 9 ₂ , ...) are provided with upward flow generating tube (8 ₁ , 8 ₂ , ...), respectively, the suction force and the upward flow generating tube (8) of each suction pipe (9 ₁ , 9 ₂ , ...) ), The upward force is sequentially increased toward the flow direction.

In this embodiment, the flow cross sectional area of each suction pipe 9 ₁ , 9 ₂ , ... is the same, and the flow cross sectional area (opening area) of each upflow generating pipe 8 ₁ , 8 ₂ ,. Therefore, the suction force and the lift force were changed by changing the suction flow rate and the rise (discharge) flow rate.

In the present embodiment, the heavy-heavy gravity specific gravity (B) suspended in the water by the upward flow from the upward flow generating tube (8 ₁ ) is sucked out of the suction pipe (9 ₁ ), and the heavy specific gravity such as aggregate is relatively small. (A ') is suspended in water by the strong upflow from the _second upflow generating tube (8 ₂ ), and is sucked out of the second suction pipe (9 ₂ ) of strong suction force, and among them, the specific gravity (A') The heavier heavy specific gravity A '' is suspended in the water by the strong upward flow from the third upward flow generating tube 8 ₃ and discharged by the third suction force 9 ₃ of the strong suction force. At this time, even if the heavy specific gravity (A, A ', A'') is sucked into the suction pipes 9 ₁ , 9 ₂ , ... through the flow, it remains in accordance with the suction force of the suction pipes 9 ₁ , 9 ₂ , ... The suction force by suction or self weight is higher than the buoyancy force (suction force) by suction, and it is settled again on the downward inclination screen 6, and is settled again to the bottom discharge side 2b of the water tank 2 again.

As a result of the three stages of suction screening, the heavy gravity material A is sorted by specific gravity (A ', A' ') and at the same time, the steel, copper, and lead are discharged from the discharge end 2b on the lower side of the water tank 2. Only the heavy specific gravity A having a very high specific gravity of the back metal is settled into the discharge screw 11 and sorted.

In this embodiment, the basket 3, the inclined screen 6, the vibration generating means 7, etc. can be employ | adopted suitably. Moreover, the number of the suction pipe 9 and the upflow generating tube 8 is set suitably according to the selection | selection number of the mixture (D). Furthermore, when the inclined screen 6 is provided as shown in the dashed line in Fig. 4, the screening action is assured because the mixture D moves thereon as shown in FIG.

7 shows a fifth embodiment. In this sorting apparatus 1, the water tank 2 is made to be long deep, and the mixture D is thrown in from the chute 5 inserted in the water of moderate depth. Below the chute 5, a plurality of upward flow generating tubes 8 are provided so as to cover almost all cross sections of the water tank 2, and above the chute 5, a suction pipe 9 opened downward is provided. As in the third embodiment, the water in the water tank 2 is sucked into the suction pipe 9 by the pump 12, and the sucked water passes through the filter 13 to remove the medium-weight specific gravity B, and then circulates. It is used, and is discharged to generate an upward flow from each upward flow generating tube 8 into the water tank 2 again. In addition, a conveyor 10 is installed near the water to lift up the floating objects on the water surface, and a discharge screw 11 is installed at the bottom.

In the present embodiment, among the mixtures (D) introduced into the water from the chute (5), the heavy specific gravity (A) that is settled to the bottom of the water tank (2) is selectively recovered by the discharge screw (11), and the medium diameter specific gravity (B). Is suspended in the water by the upward flow from each upward flow generating tube 8 and sucked into the suction tube 9 and discharged to the outside. Light specific gravity (C) floating on the water surface is lifted on the conveyor 10 is discharged to the outside. In addition, even if the heavy specific gravity A is sucked into the suction pipe 9 through the flow, the settling force due to its own weight is higher than the buoyancy force (suction force) due to suction and settles downward again.

8 and 9 show a sixth embodiment. In this sorting apparatus 1, the horizontally long basket 3 suspended in the horizontally long water tank 2 is divided into 5 rows by the partition board 4 similarly to 1st Embodiment, and each of these 5 rows of five sizes are each size. The mixture (D) extracted from the chute 5 is introduced from the chute 5.

A bottom reservoir 14 is provided on the supply end 3a side of the basket 3 into which the mixture D is introduced, and the bottom of the reservoir 14 is similar to that of the first embodiment. The inclined screen 6 inclined downward toward the discharge end 3b is connected (continuously), and the bottom of the reservoir 14 and the inclined screen by the vibration generating device 7 attached to the basket 3 are connected. Vibration is imparted to (6).

The bottom of the reservoir 14 is slightly inclined downward to the inclined screen 6 side, and the side wall of the water tank 2 and the basket 3 and the partition plate 4 in each row are penetrated from the surface of the water to the downward inclined end side. The discharge screw 15 is provided, and the light specific gravity C floating on the water surface of each row is discharged to the outside from the opening 15a drilled in each row. On the rear side of the discharge screw 15, a weir 16 is provided to block the light specific gravity C floating on the water surface.

On the other hand, the vibration generating device 7 is attached to the side wall of the basket 3 above the discharge screw 15, the side wall portion of the tank (2) through which the discharge screw 15 penetrates the basket (3). It is connected to the peripheral side wall with a flexible cover 17 to absorb vibrations transmitted through the side wall and the discharge screw 15.

In addition, during the inclination of the inclined screen 6, each of the rows of the basket 3 includes an upward flow generating tube 8 which generates upward flow from below, and a suction pipe 9 which sucks the underwater floating material in the upward flow. Each opening is provided so as to face up and down so as to cover the substantially entire width direction of the inclined screen 6. Each upward flow generating tube 8 and each suction tube 9 are divided and arranged in each column, and each of the openings 8a and 9a in each column has a rectangular cross-sectional shape, and each suction tube 9 is The cross-sectional area of the opening 9a and its inlet portion is formed larger than the area of the opening 8a of each upward flow generating tube 8.

On the other hand, at the bottom of the water tank 2 on the discharge end 3b side, a discharge screw 11 for discharging the sediment is provided in the same manner as in the first embodiment.

In the present embodiment, the intermediate specific gravity A is lowered by the vibration imparted to the bottom of the storage portion 14 by the size-divided mixtures D introduced from the chute 5 to the storage portions 14 of the respective rows. , The middle diameter specific gravity B is ubiquitous on the upper side.

And while maintaining the state, it passes to the upper side of the inclined screen 6 through the lower side of the weir 16, and the middle diameter specific gravity B which is ubiquitous on the inclined screen 6 also has an upward flow generating tube. It floats in water by the upward flow from (8), is attracted to each suction pipe 9, and is discharged | emitted to the outside.

While moving on the inclined screen 6 on the lower side, the specific gravity A is submerged on the inclined screen 6 even when entering the suction pipe 9 in an upward flow, and discharged on the lower end side of the inclined screen 6. It is settled in the discharge screw 11 of the bottom of the water tank 2 from the stage 3b, and it collect | recovers and collect | recovers from the discharge port 11a. The flow rate of the upward flow and the flow rate in the suction pipe 9 are set to, for example, 0.7 m per second for the smallest heat and 1.8 m per second for the largest heat.

Since the suction speed is set according to the size of the mixture D in this way, even if the heavy specific gravity A is sucked by the respective suction pipes 9, it is settled on the lower screen 6 again above the predetermined specific gravity.

On the other hand, the light specific gravity C in the mixture of each size-sorted row enters each opening 15a of the discharge screw 15 which floats on the water surface and rotates, and is discharged outward from the discharge port 15b at once.

10 shows a first modification of the sixth embodiment. This first modification is stronger than the upward flow generating tube 8 on the discharge end 3b side of the basket 3 than the upward flow generating tube 8 and the suction tube 9 provided during the inclination of the inclined screen 6. A second upward flow generating tube 8 ₂ for generating an upward flow and a second suction tube 9 ₂ having a stronger suction force than the suction tube 9 ₁ are provided at the lower and upper sides of the inclined screen 6 with openings 8a and 9a. It is installed to face each other.

In this first modification, the medium-weight specific gravity B suspended in the water by the upward flow from the upward flow generating tube 8 ₁ is sucked out of the suction tube 9 ₁ and at the same time, the medium has a relatively low specific gravity such as aggregate. The specific gravity A 'is suspended in water by the strong upward flow from the second upward flow generating tube 8 ₂ , and is sucked out of the second suction tube 9 ₂ having a strong suction force. At this time, when the heavy specific gravity (A, A ') is sucked into the suction pipe (9 ₁ , 9 ₂ ) by the flow, in the front suction pipe (9 ₁ ), both of the heavy specific gravity (A, A') due to its own weight The sinking force is higher than the buoyancy due to suction (suction force), and it is further settled down on the inclined screen 6 below, and in the suction tube 9 ₂ at the rear, the heavy gravity material A such as iron, copper, and lead is self-weighted. The settling force by is greater than the buoyancy due to suction, and is settled again on the downward inclined screen 6, and the heavy specific gravity A 'having a relatively small specific gravity such as aggregate is attracted as it is and is drawn out.

Therefore, two stages of suction screening are performed, and the heavy gravity material A is sorted by specific gravity (A and A '), and the iron, copper, and lead are discharged from the discharge end 3b on the lower side of the inclined screen 6. Only the heavy specific gravity A having a very high specific gravity of the back metal is settled into the discharge screw 11 and sorted.

11 shows a second modification of the sixth embodiment. In this second modification, the second discharge screw 11a is provided in front of the discharge screw 11 provided at the bottom of the discharge end side of the water tank 2, and is forward from the discharge end side of the water tank 2. The nozzle 18 which generate | occur | produces the horizontal flow toward this is provided.

Therefore, the heavy specific gravity A 'having a relatively small specific gravity, such as aggregate, among the heavy specific gravity A that is settled from the discharge end 3b on the lower end side of the inclined screen 6 is formed by the horizontal flow from the nozzle 18. Under the influence, it is settled in the front second discharge screw 11a, and only the heavy specific gravity A having a large specific gravity of metal such as iron, copper, and lead is settled in the discharge screw 11 as it is and is selected.

10 and 11, the number of the upflow generating tube 8 and the suction tube 9 is arbitrary.

12 and 13 show seventh and eighth embodiments, which are the first and second modified examples of the fifth embodiment shown in FIG. 7, and the embodiment of FIG. 12 shows the suction pipe 9. Two (9 ₁ , 9 ₂ ) are provided, and in the embodiment of FIG. 13, two (8 ₁ , 8 ₂ ) of the upward flow generating tube (8) are also provided. The suction force of the two suction pipes 9 ₁ , 9 ₂ weakens the suction pipe 9 ₁ on the upstream side than the suction pipe 9 ₂ on the downstream side, and the two upward flow generating pipes 8 ₁ , 8 ₂ By making the upstream upstream generation tube 8 ₁ weaker than the downstream upstream generation tube 8 ₂ , the heavy specific gravity A and A 'can be sorted in the same manner as in the embodiment of FIG. 10. . At this time, even if the heavy specific gravity (A, A ') is sucked into the suction pipes (9 ₁ , 9 ₂ ) through the flow, it is sucked as it is or according to the suction force of the suction pipes (9 ₁ , 9 ₂ ), It sinks downward again above the buoyancy due to suction (suction force).

Including each said embodiment, the shape of the inlet part of the suction pipe 9 can be made into the aspect shown in FIG. 14, etc., and the inlet shape of the upflow generating tube 8 can also be made the same. Also in this embodiment, the number of the upflow generating tube 8 and the suction tube 9 is arbitrary.

In each said embodiment, the heavy specific gravity A may be settled from the eye of the inclined screen 6, and the member which does not exist in each embodiment can be employ | adopted suitably for embodiment without the member. For example, the storage part 14 can be employ | adopted suitably for each embodiment of FIG. 2, FIG. 4, FIG.

Although each embodiment was a case of the sorting of the concrete aggregate of a building waste material, each embodiment can be employ | adopted also in the case of separating and removing gravel etc. from the above-mentioned papermaking wood chips, the sorting of pellets in a clay shooting range, The effect that sorting precision is high can be acquired. In those cases, the number of the upflow generating tube 8 and the suction tube 9, the presence or absence of the inclined screen 6, etc. are appropriately set according to the object sorted material. For example, in the case of pelleting or the like, since there is only one object to be sorted, the number of the upward flow generating tube 8 and the suction tube 9 is sufficient as one.

In the present invention, since the heavy specific gravity is not attracted and soaks in the bottom of the water tank, the recovery rate of the heavy specific gravity is improved.

Claims (24)

In the sorting apparatus 1 which mix | blends the mixture D to be sorted in the water tank 2, and sorts the heavy gravity material A in the said mixture D which settles to the bottom of a water tank by the specific gravity difference, An upflow generating tube 8 for generating an upward flow in the water tank 2, and a suction pipe 9 for sucking a floating object floating in the water by the upward flow upward from a downward opening 9a, are provided. A suction device according to (9), wherein the specific gravity material (A) is set so as to settle down in its own weight even if it enters into the suction pipe (9). 2. The sorting device according to claim 1, wherein the suction flow rate of the suction pipe (9) is slower than the flow rate of the upward flow so that the heavy gravity material (A) is settled even if it enters the suction pipe (9). The opening area of the upward flow generating tube 8 is narrower than the flow cross-sectional area of the inlet portion of the suction pipe 9 which sucks upward from the opening 9a of the suction pipe 9, and thereby raises the opening area. Separation device characterized in that the suction flow rate of the suction pipe (9) is slower than the flow rate of the flow. The inside of the said water tank 2 is divided into several rows by the vertical partition plate 4, The said suction pipe 9 is provided in each of these partitioned rows, respectively. Sorting apparatus made of. The sorting apparatus according to claim 4, wherein the mixtures (D) introduced into the water tank (2) are size-sorted, and these size-divided mixtures (D) are separately introduced into each of the partitioned rows. The suction pipe 9 according to any one of claims 1 to 3, wherein a plurality of suction pipes 9 are provided in sequence in the flow direction of the mixture D, and suction force of each of the suction pipes 9 ₁ , 9 ₂ . Separating device sequentially characterized in that toward the flow direction. 5. The suction pipe (9) according to claim 4, wherein a plurality of suction pipes (9) are provided in turn in the flow direction of the mixture (D), and the suction force of the suction pipes (9 ₁ , 9 _{2 ...} ) is sequentially increased toward the flow direction. Separating device, characterized in that. 6. The suction pipe (9) according to claim 5, wherein a plurality of said suction pipes (9) are provided in turn in the flow direction of said mixture (D), and the suction force of each of said suction pipes (9 ₁ , 9 _{2 ...} ) is sequentially increased toward said flow direction. Separating device, characterized in that. 5. The sorting apparatus according to claim 4, wherein an upward flow generating tube (8) is provided for each of the suction tubes (9). The sorting apparatus according to claim 5, wherein an upward flow generating tube (8) is provided for each of the suction tubes (9). The sorting apparatus according to claim 6, wherein an upward flow generating tube (8) is provided for each of the suction tubes (9). The sorting apparatus according to any one of claims 9 to 11, wherein the upward flow of each upward flow generating tube (8) is sequentially counted toward the flow direction of the mixture (D). The method according to any one of claims 1 to 3, 5 and 7 to 11, wherein each of the openings (8a, 9a) of the upward flow generating tube (8) and the suction tube (9) is A sorting device characterized by having a long hole shape in the transverse direction with respect to the flow direction of the mixture (D). 5. The method according to claim 4, wherein each of the openings (8a, 9a) of the upward flow generating tube (8) and the suction tube (9) has a long hole shape transverse to the flow direction of the mixture (D). Sorting device. 7. The elongated generating tube 8 and the openings 8a, 9a of the suction pipe 9 are each formed in a long hole shape transverse to the flow direction of the mixture D. Sorting device. The method according to any one of claims 1 to 3, 5, and 7 to 11, 14 to 15, wherein the upward flow generating tube (8) in the water tank (2) and An inclined screen 6 whose lower end is opened as a discharge end between the suction pipes 8 is inclined downward toward the flow direction of the mixture D, and the mixture D is provided on the upper side of the inclined screen 6. ), And the heavy gravity material (A) from the discharge end of the lower end side to be settled to the bottom of the tank. 5. The inclined screen (6) according to claim 4, wherein a lower end side is opened as a discharge end between the upward flow generating tube (8) and the suction tube (9) in the water tank (2) toward the flow direction of the mixture (D). It is installed to be inclined downward, and the mixture (D) is introduced into the upper end side of the inclined screen (6) so that the heavy gravity material (A) is settled to the bottom of the tank from the discharge end of the lower end side. The sorting device characterized by the above-mentioned. 7. The inclined screen 6 according to claim 6, wherein a lower end side is opened as a discharge end between the upward flow generating tube 8 and the suction tube 9 in the water tank 2 toward the flow direction of the mixture D. It is installed to be inclined downward, and the mixture (D) is introduced into the upper end side of the inclined screen (6) so that the heavy gravity material (A) is settled to the bottom of the tank from the discharge end of the lower end side. The sorting device characterized by the above-mentioned. 13. The inclined screen 6 according to claim 12, wherein a lower end side is opened as a discharge end between the upward flow generating tube 8 and the suction tube 9 in the water tank 2 toward the flow direction of the mixture D. It is installed to be inclined downward, and the mixture (D) is introduced into the upper end side of the inclined screen (6) so that the heavy gravity material (A) is settled to the bottom of the tank from the discharge end of the lower end side. The sorting device characterized by the above-mentioned. 14. The inclined screen 6 according to claim 13, wherein a lower end side is opened as a discharge end between the upward flow generating tube 8 and the suction tube 9 in the water tank 2 toward the flow direction of the mixture D. It is installed to be inclined downward, and the mixture (D) is introduced into the upper end side of the inclined screen (6) so that the heavy gravity material (A) is settled to the bottom of the tank from the discharge end of the lower end side. The sorting device characterized by the above-mentioned. The sorting device according to any one of claims 17 to 20, wherein a means for applying vibration to the inclined screen (6) is provided. 17. The sorting apparatus according to claim 16, wherein means for imparting vibration to the inclined screen (6) is provided. 22. The sorting apparatus according to claim 21, wherein a storage portion (14) of the introduced mixture (D) is continuously provided on an upper end side of the inclined screen (6). 23. The sorting apparatus according to claim 22, wherein a storage portion (14) of the injected mixture (D) is continuously provided on an upper end side of the inclined screen (6).

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