KR100821940B1 - Sieve barrel duct device of the aggregation sorting system using the construction waste and controlling method for the same - Google Patents

Abstract

A sieve barrel duct apparatus of an aggregate sorting system using the construction waste and a control method thereof are provided to restrain sorting holes of sieve barrels from being stopped up by wet soil or waste, by equally jetting the wind to the sorting holes without using the expensive burner by installing plural partitions and an airflow guide device in the end of a duct, and then controlling the airflow guide device. In a sieve barrel duct apparatus of an aggregate sorting system using construction waste(2), a first sieve barrel(3) has plural sorting holes(1) having a predetermined diameter, contains the construction waste, and sorts out the construction waste by rotating the construction waste forward. A second sieve barrel(5) is provided with plural sorting holes(4) having a predetermined diameter and connected with the first sieve barrel, to discharge the construction waste by turning the construction waste oppositely to the rotational direction of the first sieve barrel. A duct device unit(6) is connected to the upper sides of the first and second sieve barrels through each inner passage to blow the wind to the entire sorting holes of the first and second sieve barrels equally. A blower unit(7) is installed at one side of the duct device unit to blow the wind into the inner passage of the duct device unit. A first conveyor(8) is installed at the lower part of the first and second sieve barrels to transfer soil or wastes of predetermined grain size falling through the sorting holes, to the next process. A second conveyor(9) is mounted at an outlet of the second sieve barrel to transfer soil or wastes of predetermined grain size that do not fall through the sorting holes, to the next process.

Description

Sieve barrel duct device of the aggregation sorting system using the construction waste and controlling method for the same

BRIEF DESCRIPTION OF THE DRAWINGS Explanatory drawing explaining the trunk | drum of a conventional lung bone sorting system.

Figure 2 is an explanatory diagram illustrating a duct system of the waste aggregate aggregate system of the present invention.

3 is an explanatory diagram for explaining the internal structure of the duct apparatus of the present invention.

4 is a flowchart of the present invention.

*** Explanation of symbols for important parts of drawing ***

1: sorter 2: construction waste

3: first trunk 4: 4: sieve

5: second body 6: duct device

7: blower unit 8: first conveyor

9: 2nd conveyor 10: 1st partition wall part

11: first duct structure part 12: second partition wall part

13: second duct structure 14: air volume control member
15: pivot

The present invention relates to a duct device of the aggregate screening system using construction waste, and in particular, by installing a plurality of partitions and air volume guide device in the inner structure of the distal end of the duct coupled to the inside of the body body by adjusting the air flow guide device The present invention relates to a canister duct device of an aggregate selection system using construction waste that allows wind to be uniformly distributed to sieve sorters.

In general, in the case of landfilling of construction waste, not only resources are wasted but also various environmental pollution problems have been recently developed and utilized to recycle and recycle construction waste.

In particular, among such construction waste sorting and treatment systems, various kinds of construction wastes are shredded, washed and sorted and recycled, or a system for selectively producing recycled aggregates using water is widely used.

Then, referring to FIG. 1 of the above-described waste sorting system in the waste sorting system, the sorting holes (70, 71) consisting of a plurality of perforated holes are provided therein, respectively, and accommodates construction waste (72) for forward rotation. A plurality of cylinders (73, 74) for separating and discharging the building waste (72) according to the particle size through the sorting holes (70, 71) as the reverse rotation is performed;

The heating burner 75 is installed near the outer periphery of the cylinders 73 and 74 and heats the sorting holes 70 and 71 so that the sorting holes 70 and 71 are not blocked by wet soil or garbage. ;

A first conveyor (76) installed at a lower portion of the cylinders (73, 74) to transfer the soil or wastes (72) having a predetermined particle size dropped through the selection holes (70, 74) to a predetermined next process;

 The second conveyor 77 is installed at the outlet side of the cylinders 73 and 74 to transfer the soil or wastes 72 having a predetermined granularity that cannot be dropped through the sorting holes 70 and 74 to a predetermined next process. It is configured to include.

Then, referring to the operation of the barrel device as described above, first, when the building waste 72 is put into the barrel 73 in order to sort the building waste 72, the barrel 73 is rotated forward. At this time, when the barrel 73 is rotated, the construction waste 72 having a predetermined size or less, for example, soil or rubbish, is discharged through the sorting hole 70 provided in the barrel 73. It is dropped to the upper surface of the first conveyor 76 located below. Then, the first conveyor 76 transfers the soil or wastes 72 having a predetermined granularity dropped through the sorting hole 70 to a predetermined next process. On the other hand, the relatively large soil or waste (72) that did not pass through the screening hole 70 of the barrel 73 is transferred to the next barrel 74, wherein the barrel 74 and the barrel 73 Will reverse. Therefore, when the barrel 74 is rotated as described above, the construction waste 72 having a predetermined size or less, for example, soil or rubbish, is stored in the barrel 74 through the sorting hole 71 provided in the interior of the barrel 74. Drop on the upper surface of the first conveyor (76) located below the bottom. Then, the first conveyor 76 transfers the soil or wastes 72 having a predetermined particle size dropped through the sorting hole 71 to a predetermined next process, while the sorting hole of the barrel 74 Relatively large soil or wastes that do not pass through 71 are discharged to the second conveyor 77. Then, since the second conveyor 77 is installed at the outlet side of the cylinder 74, the next process of determining the soil or wastes 72 having a predetermined granularity that cannot fall through the sorting holes 70 and 74 is determined. Transfer to.

Here, the heating burner 75 installed near the outer periphery of the cylinders 73 and 74 during the sorting process heats the selection holes 70 and 71 of the cylinders 73 and 74 to heat the selective holes ( Continue drying to prevent them from being blocked by wet soil or trash.

However, the conventional pulmonary bone sieve screening system of the conventional sieve bone system, so that the sorting holes (70, 71) of the cylinders (73, 74) to continue to apply heat to the sorting hole with a heating burner so as not to be blocked by wet soil or garbage Because of this, the fuel consumption of the heating burner is high, thus significantly increasing the operating cost of the waste bone sorting system. Also, since the heating burner is located only at one side of the bottom of the barrel, the heat is uniformly applied to the sorting holes. There was a problem that the sorters were frequently blocked by wet soil or garbage, so that the system was stopped and the manager had to go directly into the barrel and drill through the blocked sorters.

Therefore, the present invention has been invented to solve the above problems, wind through the ducts of the air flow guide device and the partition structure without using an expensive burner device so that the screening holes of the barrel is not blocked by wet soil or garbage. The purpose of the present invention is to provide a duct system for the aggregate screening system using the aggregate waste, which uniformly dissipates, thereby significantly improving the operational efficiency of the barrel.

Another object of the present invention is to control the air flow guide device to dry the moisture present around the sieve of the sieve because the wind is uniformly transmitted to the sieves installed throughout the inside of the sieve through the partition duct Since the number of repairs can be significantly reduced, the present invention provides a duct system for the aggregate selection system using construction waste, which maximizes the maintainability of the barrel.

The present invention for achieving the above object is provided with a plurality of perforated holes having a predetermined diameter therein, and the first body through the building waste to pick up the waste by the forward rotation to sort the waste;

A second barrel connected to the first barrel and having a plurality of drilled holes having a plurality of predetermined diameters therein to rotate the received construction waste in a direction opposite to the rotational direction of the first barrel;

A duct device unit connected to an upper passage of the first barrel and the second barrel, respectively, and configured to uniformly apply wind to all the sorting holes of the first barrel and the second barrel;

A blower unit installed at one side of the duct unit to apply wind to an inner passage of the duct unit;

A first conveyor installed at a lower portion of the first cylinder and the second cylinder to transfer soil or waste having a predetermined particle size dropped through each sorting hole to a predetermined next process;

 Cylinder duct device of the aggregate screening system using the building waste comprising a second conveyor is installed on the outlet side of the second cylinder to transfer the soil or waste having a certain granularity that can not fall through the sorting hole to a predetermined next process To provide.

Another feature of the present invention is to accommodate the construction waste to the first barrel and the second barrel device to sort through the reverse rotation process, and then the building waste receiving step of discharging the construction waste of a predetermined size;

A blowing driving step of driving a blower during the construction waste receiving step to flow wind into the first and second cylinders through a duct device;

It provides a control method of the barrel duct apparatus of the aggregate screening system using the construction waste comprising the air flow control step of controlling the air flow applied to each cylinder after the blowing driving step through the air flow control member.

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

The present invention comprises a sorting hole (1) having a plurality of perforated holes having a predetermined diameter therein, as shown in Figure 2 and receiving the building waste (2) to rotate forward to sort the waste (2) 1 barrel 3;

The construction wastes 2 accommodated with the sorting holes 4 associated with the first barrel 3 and having a plurality of predetermined diameters formed therein are opposed to the rotational direction of the first barrel 3. A second cylinder 5 which rotates in a direction and is discharged;

The upper passages of the first barrel 3 and the second barrel 5 are respectively connected to internal passages and are uniform in all sorting holes 1 and 4 of the first barrel 3 and the second barrel 5. And duct device 6 for applying the wind respectively;

A blower unit 7 installed at one side of the duct unit 6 to apply wind to the inner passage of the duct unit 6;

Installed in the lower part of the first cylinder (3) and the second cylinder (5) to transfer the soil or wastes (2) having a predetermined particle size dropped through each of the sorting holes (1, 4) to a predetermined next process A first conveyor 8;

 The second conveyor (9) is installed at the outlet side of the second cylinder (5) to transfer the soil or wastes (2) having a predetermined granularity that cannot fall through the sorting holes (1,4) to a predetermined next process. It is configured to include.

In addition, the duct apparatus 6 includes, as shown in FIG. 3, selection holes 1 installed on passages connected to the interior of the first barrel 3 and installed at respective positions of the first barrel 3. A first duct structure portion (11) having a plurality of first partition wall portions (10) formed to direct the wind direction toward each sorting hole (1) so that the wind is uniformly applied;

The wind direction is installed on the passage connected to the inside of the second barrel (5), the wind direction toward each sorting hole (4) so that the wind is uniformly applied to the sorting holes (4) installed at each position of the second barrel (5). A second duct structure portion 13, in which a plurality of second partition wall portions 12 which are directed to face each other are formed;

Wind flowing in a position where the first duct structure 11 and the second duct structure 13 intersect, the wind is installed in the form of a rectangular door and applied to the first partition wall portion 10 or the second partition wall portion 12 side. It is configured to include a flow rate adjusting member 14 for controlling the amount of variable.

Meanwhile, the first partition wall part 10 of the first duct structure part 11 and the second partition wall part 12 of the second duct structure part 13 guide the wind uniformly to the respective selection holes 1 and 4. A plurality of wind turbines are installed in different directions in accordance with the direction of the wind.

Next, a control method applied to the above apparatus will be described.

The method of the present invention in the initial state (S1) as shown in FIG.

The construction waste storage step (S2) proceeds to accept the construction waste in the first barrel and second cylinder device and sort through the reverse rotation process, and then discharge the construction waste of a certain size. In addition, the building waste accommodation step (S2) of the blowing driving step (S3) proceeds to drive the blower to flow the wind into the interior of the first and second cylinder through the duct device. In addition, after the blowing operation step (S3) and proceeds to the air volume control step (S4) to control the amount of air applied for each cylinder through the air volume control member.

Here, in the blowing driving step (S3), the wind is emitted to the entire selection holes of the first and second barrels by the structure of the first partition wall of the first duct structure and the second partition wall of the second duct structure. It further comprises a driving duct structure step.

In other words, first, when the building waste 2 is put into the first barrel 3 to sort out the building waste 2, the first barrel 3 is rotated forward. In this case, when the first barrel 3 is rotated forward, the construction waste 2 having a predetermined size or less, for example, the earth and sand, is first through the sorting hole 1 provided in the interior of the first barrel 3. It falls to the upper surface of the 1st conveyor 8 located in the lower part of the cylinder 3. Then, the first conveyor 8 transfers the soil or wastes 2 having a predetermined granularity dropped through the sorting hole 1 to a predetermined next process. On the other hand, the relatively large soil or waste (2) that did not pass through the sorting hole (1) of the first barrel (3) is transferred to the second barrel (5), where the second barrel (5) Is reversely rotated as opposed to the first barrel (3). Therefore, when the second cylinder 5 is reversely rotated as described above, the construction waste 2 having a predetermined size or less, for example, soil or garbage, is disposed through the sorting hole 4 provided in the interior of the second cylinder 5. Fall on the upper surface of the first conveyor 8 located below the second barrel 5. Then, the first conveyor 8 transfers the soil or wastes 2 having a predetermined particle size dropped through the sorting hole 4 to a predetermined next process, while the sorting hole of the second barrel 5 Relatively large soil or wastes (2) that did not pass (4) are discharged to the second conveyor (9). Then, since the second conveyor 9 is installed at the outlet side of the second cylinder 5, the soil or wastes 2 having a predetermined granularity that cannot fall through the sorting holes 1 and 4 are defined. Transfer to the next process.

Here, the soil or wastes 2 which are accommodated in the first barrel 3 and the second barrel 5 during the screening process are usually wetted, so that the sorting holes 1, 4 of the barrel 3, 5 are wetted. There is a tendency to block the holes of these, where, when the screening process by the barrel (3,5) is in progress at the same time the blower unit (7) of the present invention is also activated to produce a strong wind duct apparatus (6) Into). Then, the wind applied to the duct device part 6 passes through the first duct structure part 11 of the duct device part 6 toward the first cylinder 3 and the second duct of the duct device part 6. Through the structure 13, it is guided to the second barrel 5.

However, the wind applied from the blower unit 7 and the first partition wall portion 10 provided in the first duct structure 11 and the second duct structure 13 in a plurality of different installation directions, respectively; The second partition wall portions 12 are uniformly guided and blown into the respective sorting holes 1 and 4. Therefore, since the wind is uniformly supplied to each of the sorting holes 1 and 4 as described above, the wetted soil or wastes 2 accommodated in the first barrel 3 and the second barrel 5 are quickly ducted. Since it is dried by the wind blown from the apparatus part 6, clogging of the selection holes 1 and 4 is considerably reduced.

On the other hand, when adjusting the air volume control member 14 installed in the rear portion of the duct device portion 6 during the above process, the first partition wall portion 10 or the second duct structure portion of the first duct structure portion 11 ( The amount of wind applied to the second partition wall part 12 of 13) can be varied. That is, as shown in Figure 3 by adjusting the control lever (not shown) installed on one side of the pivot shaft 15 is fixed one end of the air volume control member 14, for example, the air volume control member installed in the form of a rectangular door ( If the body of 14) is moved to the first duct structure 11 through the pivot axis 15 and is blocked (in this case, when the airflow control member completely blocks the first duct structure), the first duct structure 11 There is no way for the wind to enter. On the other hand, when the first duct structure 11 is completely blocked by the air flow control member 14 as described above, the passage through which wind is applied to the second duct structure 13 side is secured to the maximum and installed at the rear end. Since the wind applied from the blower unit 7 is not applied to the first duct structure portion 11, it is applied to the second partition wall portion 12 side of the second duct structure portion 13 to the maximum.
Of course, when the air volume control member 14 is not completely blocked toward the first duct structure portion 11, the wind applied from the blower unit 7 is equal to the passage width formed in the first duct structure portion 11. At the same time as the structure 11 is applied to all the remaining wind is applied to the second duct structure 13 is completely open.
Similarly, if the airflow control member 14 blocks the second duct structure 13, the same function as described above is performed according to the degree of blocking.

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Therefore, by controlling the air volume control member 14, it is possible to variably control the amount of wind applied to the first body cylinder 3 and the second body cylinder (5).

As described above, the present invention installs a plurality of partitions and airflow guide devices in the inner structure of the distal end of the duct coupled to the inside of the barrel body, and then regulates the airflow guide device to uniformly radiate the wind to the screening holes of the barrel. By using the airflow guide system and the partition duct without using an expensive burner device, the sieves of the cylinders emit wind to prevent the soil from being clogged by wet soil or trash, thereby significantly improving the operational efficiency of the cylinders. Have

According to the present invention, since the wind is uniformly transmitted to the sorting holes installed throughout the interior of the barrel through a duct having a partition structure by adjusting the airflow guide device, the moisture present around the sorting hole of the barrel is easily dried and repaired. The number of times can be significantly reduced, thereby maximizing the maintainability of the body.

Claims (5)

A first barrel having sorting holes formed with a plurality of perforated holes having a predetermined diameter thereinto, and receiving the building wastes to rotate forward to sort the wastes; A second barrel connected to the first barrel and having a plurality of drilled holes having a plurality of predetermined diameters therein to rotate the received construction waste in a direction opposite to the rotational direction of the first barrel; A duct device unit connected to an upper passage of the first barrel and the second barrel, respectively, and configured to uniformly apply wind to all the sorting holes of the first barrel and the second barrel; A blower unit installed at one side of the duct unit to apply wind to an inner passage of the duct unit; A first conveyor installed at a lower portion of the first cylinder and the second cylinder to transfer soil or waste having a predetermined particle size dropped through each sorting hole to a predetermined next process; Aggregate selection system using the construction waste, characterized in that it comprises a second conveyor is installed on the outlet side of the second barrel to transfer the soil or waste having a certain granularity that can not fall through the sorting hole to a predetermined next process Body duct system. According to claim 1, The duct device is installed on the passage connected to the inside of the first barrel to the wind direction toward each of the sorting holes so that the wind is uniformly applied to the sorting holes installed in each position of the first barrel. A first duct structure having a plurality of first partition walls to guide; A plurality of second partition wall parts are provided on a passage connected to the inside of the second cylinder to guide the wind direction toward each of the selective holes so that the wind is uniformly applied to the selective holes installed at each position of the second cylinder. A second duct structure portion; The first duct structure and the second duct structure is installed in a predetermined shape flowing through the pivot axis at the position where the intersection intersects the first duct structure according to the degree of blocking the passage area of the first duct structure and the second duct structure portion via the pivot axis. The duct apparatus of the aggregate screening system using the construction waste, characterized in that it further comprises a flow rate control member for controlling the amount of wind applied to the partition wall portion or the second partition wall portion. The method of claim 1, wherein the first partition wall portion of the first duct structure portion and the second partition wall portion of the second duct structure portion align the direction of the wind in accordance with the direction in which the wind can be uniformly guided to the respective sorting holes. Body duct device of the aggregate screening system using the construction waste, characterized in that a plurality of different installation each. A building waste receiving step of receiving the building waste into the first barrel and the second barrel device and selecting the waste through a forward and reverse rotation process, and then discharging the building waste of a predetermined size or more; A blowing driving step of driving a blower during the construction waste receiving step to flow wind into the first and second cylinders through a duct device; The air volume applied to each cylinder after the blowing operation step is to block the passage area of the first duct structure and the second duct structure via the pivot axis of the air volume control member installed at the position where the first duct structure portion and the second duct structure portion cross each other. And a flow rate adjusting step of variably controlling the amount of wind applied to the first partition wall portion or the second partition wall portion according to the degree. 5. The wind of claim 4, wherein, in the blowing operation, the wind applied by the first partition wall part of the first duct structure part and the second partition wall part of the second duct structure part is applied to the entire selection holes of the first and second barrels. The control method of the barrel duct apparatus of the aggregate selection system using the construction waste, characterized in that it further comprises a duct structure step of driving to diverge.

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