KR100459316B1 - apparatus for sorting aggregate - Google Patents

Abstract

The present invention relates to an aggregate selector, in each screen of the main stage consisting of a four-stage screen, divided into two parts in the aggregate advancing direction to set the size of the mesh of each part or to form only a portion in the aggregate advancing direction In this way, the aggregates are divided into two parts in the direction of aggregate progress, forming a passage between the parts having different sizes of the net, so that the aggregate of six size ranges can be selected with four screens, without increasing the total volume of the aggregate selector. The screening size range of can be further subdivided.

Description

Aggregate sorter {apparatus for sorting aggregate}

The present invention relates to an aggregate sorter, and more particularly, to an aggregate sorter for sorting mixed aggregates by particle size during ascon production in an ascon plant.

Ascon is a name for shortening asphalt concrete, and it is called by various terms such as asphalt, asphalt mixture, asphalt concrete, hot mix hot-spapping bitumen pavement mixture (KSF2349) and HMA (hot mix asphalt). General asphalt concrete mixture is mixed with asphalt and coarse aggregate (gravel: Aggregate), fine aggregate (sand: sand) or pavement filler (wheeler, stone powder: mineral filler) or mixed at room temperature. It is divided into various types according to the purpose of use, use, function, and construction method.

The mixed aggregate of coarse aggregate and fine aggregate among the materials of the ascon contains a lot of moisture, so that it is heated and dried while mixing evenly to facilitate the sorting before being transferred from the drying process to the sorting process, which is a post-treatment process. do.

As described above, ascon is used in various ways to have various strengths according to its use. For example, ascon is roughly divided into granulated ascon, dense ascon and fine grained ascon. Assembled asphalt is used for the base and middle layers of the road, and dense ascon or fine grained asphalt is used for the surface of the road. Here, the dense ascon is used for the paving of a lot of traffic of a large vehicle, and the fine-grained ascon is used for the paving of roads and sidewalks with a relatively small traffic of a large vehicle.

Therefore, in order to manufacture these various kinds of ascone, in the sorting step, the mixed aggregate that has undergone the drying step is sorted by particle size. Performing this treatment is an aggregate sorter.

This aggregate sorter, as shown in Figure 6, is installed in the cover 1, the main body 10 provided with a multi-stage screen for screening the aggregate inclined down a predetermined angle in the direction of the aggregate with respect to the ground up and down It is installed to vibrate. In the upper surface of the cover 1, the aggregate inlet 3 is formed at the rear edge of the main body 10 in the aggregate advancing direction. In order for the aggregate which flows in from the aggregate inlet 3 and is placed on the screen of the main body 10 to be sorted by the screen, the main body 10 does not normally flow down the aggregate on the screen, but on the screen when vibrating up and down. The inclination angle is set so that the aggregates flow down. For example, the inclination angle of the main body 10 is set to 5 degrees to 15 degrees.

FIG. 6 illustrates an aggregate selector having a structure in which the main body 10 is inclined below a predetermined angle in the aggregate traveling direction with respect to the ground and vibrates up and down, but the main body 10 is horizontally installed to vibrate at an angle of 45 °. It will be appreciated that aggregate selectors of structure also fall within the scope of the present invention.

The main body 10 is provided in the cover 1 by the elastic body 20 so that vibration is possible. The lower end of the elastic body 20 is fixed to the bottom surface of the cover 1, and the side of the main body 10 is fixed on the elastic body 20, so that the main body 10 can vibrate up and down within the cover. . The excitation body 30 is fixed to the side surface of the main body 10, and the motor 40 is connected to the excitation body 30 by a belt or the like. The motor 40 is fixed to the outer surface of the cover 1, and when the rotational force of the motor 40 is transmitted to the vibrator 30, the vibrator 30 vibrates the body 10, the elastic body 20 The main body 10 supported by) oscillates up and down. Therefore, the aggregate on the screen of the main body 10 is selected.

Since the configuration of the cover 1, the main body 10, the elastic body 20, the motor 30 and the excitation body 40 is a known technique, only the above description and the schematic drawing of FIG. You will know enough about the relationship.

7 shows the configuration of the main body 10 in detail. The main body 10 is composed of four screens 11 to 14. The first screen 11 located at the top of the main body 10 has the largest size of the mesh, and the second, third and fourth screens 12, 13, 14 located in order below the first screen 11 in order. ) The size of each of them decreases downwards.

The size of each mesh of the screens 11-14 is the same within the screen of each stage, as shown in FIG. 8.

Therefore, the aggregate passing through the first screen 11 is reselected at the second screen 12, the aggregate passing through the second screen 12 is reselected at the third screen 13, and the third screen ( Aggregate passing through 13) is reselected on the fourth screen (14).

Chutes for guiding the aggregates selected from the screens 11 to 14 to the hopper 60 at the front ends of the screens 11 to 14 in the forward direction of the aggregate and the lower portion of the fourth screen 14 ( 50) is installed. The chute 50 includes first to fifth guide parts 51 to 55. Each of the first to fourth guide parts 51 to 54 guides aggregates of the first to fourth screens 11 to 14 to guide the aggregates that do not pass through the first to fourth screens 11 to 14, respectively. It is installed to extend to the end of the front side of the furnace, the fifth guide portion 55 is installed in the lower portion of the fourth screen 14 to guide the aggregate passed through the fourth screen (14).

The first to fourth storage portions 61 to 64 of the hopper 60 are connected to the second to fifth guide portions 52 to 55 of the chute 50, respectively.

Aggregate, which does not pass through the first screen 11 and is guided to the first guide part 51, is composed of aggregates larger than or equal to the mesh size of the first screen 11. That is, the aggregate guided to the first guide portion 51 has various sizes, and therefore, is not suitable for use as the aggregate for ascon.

Next, after passing through the first screen 11, the aggregate that is not passed through the second screen 12 and is guided to the second guide part 52 and stored in the first storage part 61 is stored in the second screen 12. Since it consists only of aggregates larger than the mesh size and smaller than the mesh size of the first screen 11, it is used in ascons requiring aggregates in this size range.

Next, after passing through the second screen 12, the aggregate that is not passed through the third screen 13 and is guided to the third guide part 53 and stored in the second storage part 62 is stored in the third screen 13. Since it consists only of aggregates larger than the mesh size and smaller than the mesh size of the second screen 12, it is used for ascons requiring aggregates in this size range.

Next, after passing through the third screen 13, the aggregate which is not passed through the fourth screen 14 and is guided to the fourth guide portion 54 and stored in the third storage portion 63 is stored in the fourth screen 14. Since it consists only of aggregates larger than the mesh size and smaller than the mesh size of the third screen 13, it is used for ascons requiring aggregates in this size range.

Next, the aggregate which is guided to the fifth guide portion 55 through the fourth screen 14 and stored in the fourth storage portion 64 is composed of aggregates smaller than the mesh size of the fourth screen 14. Used for ascones that require aggregates.

Since the conventional aggregate sorter has the same mesh size in each screen of one stage of the main body 10, when the main body is composed of four stages of screening, the aggregate can be selected only in four size ranges.

In recent years, as the use of ascon is more diversified, aggregates also need to be screened with more granular size ranges. However, the conventional aggregate sorter has to increase the number of screens of the main body in order to further refine the screening size range of the aggregate. However, when the number of screens of the main body is increased, the aggregate volume of the aggregate selector increases.

Therefore, the present invention has been made to solve the above problems, the first screen of the uppermost end of the main body consisting of four screens are divided into two parts in the aggregate progress direction is set to the size of the mesh of each part, The second screen of the lower end of the first screen is formed only in a portion in the aggregate advancing direction, and the third screen of the lower end of the second screen is divided into two parts corresponding to the first screen in the aggregate advancing direction so that the mesh of each part is Are set differently, and the fourth screen below the third screen is divided into two parts in the direction of aggregate progression, and the size of the mesh of each part is set differently, but the passage is between the different sizes of the mesh. It is an object to provide an aggregate selector formed.

1 is a view schematically showing the configuration of an aggregate sorter according to an embodiment of the present invention,

2 is a view schematically showing the main body and chute of the aggregate sorter of FIG.

3 is a view along the line III-III of FIG.

4 is a view along the line IV-IV of FIG. 2;

FIG. 5 is a view along the line VV of FIG. 2;

Figure 6 is a view schematically showing the configuration of the aggregate sorter of the prior art,

7 schematically shows only the body and chute of the aggregate sorter of FIG. 1, and

FIG. 8 is a view along the line VII-VII of FIG. 7.

In order to achieve the above object, the present invention is provided with a main body having four-stage screens, the size of which is reduced toward the lower end of the mesh, to be installed in the cover so as to be inclined or horizontally down to a predetermined angle in the direction of the aggregate with respect to the ground. Or an aggregate separator capable of vibrating at an angle of 45 °, and a chute for guiding aggregates selected from the screens into a hopper at the front end portions of the screens and in the lower portion of the fourth screen to the hopper, respectively. The first screen of the uppermost end of the main body is divided into two parts in the direction of aggregate progression and is formed of a first part of the front side and a second part of the opposite side in the direction of aggregate progression, but the mesh size of the first part is It is set larger than the mesh size of the two parts, and the second screen below the first screen corresponds to the first part of the first screen. It is formed only in the portion and the mesh size is set to be the same as the mesh size of the second portion of the first screen, the third screen under the second screen is divided into two parts corresponding to the first screen in the direction of aggregate progression A first portion on the front side and a second portion on the opposite side, wherein the mesh size of the first portion is set to be larger than that of the second portion and smaller than that of the second screen; The fourth screen is divided into two parts in the aggregate traveling direction and is formed of the first part on the front side and the second part on the opposite side in the aggregate traveling direction, and a through-hole is formed between the first and second parts. The mesh size of the first portion of the fourth screen is greater than the mesh size of the second portion of the third screen and smaller than the mesh size of the first portion of the third screen, and the mesh size of the second portion of the fourth screen is third screen Smaller than the mesh size of the second portion of the aperture, wherein the aperture is formed in front of the position corresponding to the boundary between the first and second portions of the third screen, and at the rear end of the first portion of the fourth screen. The aggregate screen is formed of an aggregate selector provided with a partition connected obliquely to the rear bottom surface of the first portion of the third screen and extending downwardly with respect to the first portion of the fourth screen.

Hereinafter, an embodiment according to the present invention will be described with reference to FIGS. 1 to 5.

The aggregate selector of this embodiment shown in FIG. 1 is almost the same as that of the conventional aggregate sorter shown in FIG. Therefore, in this embodiment, detailed description of the same parts as in the prior art will be omitted. The aggregate selector of this embodiment is different from the conventional aggregate selector in the internal configuration of the main body 10, the chute 50, and the hopper 60, and this different configuration will be described in detail as follows.

The configuration of the main body 10 of the aggregate sorter according to this embodiment is shown in detail in FIGS. 2 to 5.

The first screen 11 at the top of the main body 10 is divided into two parts in the aggregate travel direction. The first part 11a is formed in the front side in the aggregate advancing direction in the 1st screen 11, and the 2nd part 11b is formed in the opposite side to the 1st part 11a. The mesh size of the first portion 11a is set larger than the mesh size of the second portion 11b.

Here, in order for the aggregate on the screen to be properly filtered while passing through the second portion 11b and the first portion 11a, the length of the first portion 11a in the aggregate advancing direction is adjusted to the aggregate advancing direction of the screen. It is preferably formed to be about 2/5 part of the total length.

In addition, the second screen 12 below the first screen 11 is formed only at a portion corresponding to the first portion 11a of the first screen 11. The mesh size of the second screen 12 is set equal to the mesh size of the second portion 11b of the first screen 11.

In the sorting operation, in order to prevent the aggregate passing through the second portion 11b of the first screen 11 from being placed on the second screen 12, the first portion 11a at the rear end of the second screen 12. It is also possible to provide a partition 17 that is vertically connected to the rear end bottom of the). Although the partition 17 is not provided between the first screen 11 at the rear end of the second screen 12, the second screen 12 after passing through the second portion 11b of the screen 11. The aggregates laid on the top are again filtered on the second screen 12 whose mesh size is equal to the second part 11b of the first screen 11 and thus does not have a significant effect on the sorting operation.

In addition, the third screen 13 below the second screen 12 is divided into two parts corresponding to the first screen 11. The mesh size of the first portion 13a on the front side in the aggregate advancing direction in the third screen 13 is greater than the mesh size of the second portion 13b on the opposite side and larger than the mesh size of the second screen 12. It is set small.

In addition, the fourth screen 14 at the lower end of the third screen 13 is divided into two parts in the aggregate traveling direction. In the fourth screen 14, the first portion 14a is formed on the front side in the aggregate traveling direction, and the second portion 14b is formed on the opposite side thereof. A through hole 14c is formed between the first portion 14a and the second portion 14b.

The mesh size of the first portion 14a of the fourth screen 14 is greater than the mesh size of the second portion 13b of the third screen 13 and the mesh of the first portion 13a of the third screen 13. It is set smaller than the size. The mesh size of the second portion 14b of the fourth screen 14 is set smaller than that of the second portion 13b of the third screen 13.

In addition, the aggregate that has passed through the second portion 13b of the third screen 13 does not directly enter the through hole 14c of the fourth screen 14, but instead opens the second portion 14b of the fourth screen 14. In order to be introduced into the through hole 14c after the roughening, the through hole 14c must be formed in front of the position corresponding to the boundary between the first and second portions 13a and 13b of the third screen 13. That is, the leading end of the second portion 14b is positioned beyond the leading end of the second portion 13b of the third screen 13 and the rear end of the first portion 14a is the first portion of the third screen 13. It should be located below the rear end of (13a).

In addition, in order to prevent the aggregate passing through the second portion 13b of the third screen 13 from being placed on the first portion 14a of the fourth screen 14, the first of the fourth screen 14 At the rear end of the portion 14a, a partition 19 is provided, the upper end of which is obliquely connected to the bottom of the rear end of the first part 13a of the third screen 13 and the lower end extending vertically downward with respect to the first part 14a. Should be.

As described above, the chute 50 includes first to fifth guide parts 51 to 55. The first to fourth guide parts 51 to 54 may include the first part 11a of the first screen 11, the second screen 12, and the first part 13a and the fourth of the third screen 13. Each of the first to fourth screens 11 to 14 extends at an end portion of the front side in the direction in which the aggregate proceeds to guide the aggregate that has not passed through the first portion 14a of the screen 14, respectively. .

In addition, the fifth guide part 55 is installed in the lower part of the fourth screen 14 to guide the aggregate that has passed through the fourth screen 14, and the first and second portions of the fourth screen 14 ( 14a, 14b) and through hole 14c. That is, the fifth guide portion 55 corresponds to the front guide portion 55a corresponding to the first portion 14a, the intermediate guide portion 55b corresponding to the through hole 14c, and the second portion 14b. It consists of the rear guide part 55c.

Further, the first to fourth storage portions 61 to 64 of the hopper 60 are connected to the second to fifth guide portions 52 to 55 of the chute 50, respectively, and the fourth storage portion 64 is provided. Is subdivided corresponding to the subdivided fifth guide portion 55. That is, the fourth storage unit 64 is provided in the front storage unit 64a corresponding to the front guide unit 55a, the intermediate storage unit 64b corresponding to the intermediate guide unit 55b, and the rear guide unit 55c. Corresponding rear reservoir 64c.

When mixing the aggregate stored in the hopper 60 to the asphalt, the aggregate must be smoothly mixed with the asphalt to be warm. Therefore, in the hopper 60, a separate heating means such as a dryer had to be further installed to keep the aggregate warm. However, if the heat insulating material 70 is attached to the inner circumferential surface of the hopper 60 as a whole, since the aggregate heated in the previous aggregate drying process can be maintained in the hopper 60 without cooling, the hopper 60 is separated separately. There is no need to install the heating means.

Hereinafter, the operating relationship in which the aggregate is selected according to the present embodiment will be described.

Aggregate that has not passed through the second portion 11b and the first portion 11a of the first screen 11 is guided to the first guide portion 51 and discarded.

In addition, the aggregate that does not pass through the second screen 12 after passing through the first portion 11a of the first screen 11 is guided to the second guide portion 52 and stored in the first storage portion 61. do. The aggregate stored in the first reservoir 61 is aggregate in the first size range.

The aggregate and the second screen 12 that do not pass through the second portion 13b and the first portion 13a of the third screen 13 after passing through the second portion 11b of the first screen 11. Aggregate that has not passed through the second portion 13b and the first portion 13a of the third screen 13 after passing through the () is guided to the third guide portion 53 and stored in the second storage portion 62. do. The aggregate stored in the second reservoir 62 is aggregate in a second size range.

In addition, the aggregate that does not pass through the first portion 14a of the fourth screen 14 after passing through the first portion 13a of the third screen 13 is guided to the fourth guide portion 54 to be connected to the third portion. It is stored in the storage unit 63. The aggregate stored in the third reservoir 63 is aggregate in a third size range.

In addition, the aggregate that has passed through the first portion 14a of the fourth screen 14 is guided to the front guide portion 55a of the fifth guide portion 55 so that the front storage portion 64a of the fourth storage portion 64 is provided. ) The aggregate stored in the front reservoir 64a of the fourth reservoir 64 is aggregate in the fourth size range.

And, after passing through the second portion 13b of the third screen 13, the aggregate that fails to pass through the second portion 14b of the fourth screen 14 is the fifth guide portion 55 through the through hole 14c. Is guided to the intermediate guide portion 55b of the second storage portion 64b and stored in the intermediate storage portion 64b of the fourth storage portion 64. The aggregate stored in the intermediate reservoir 64b of the fourth reservoir 64 is aggregate in the fifth size range.

In addition, the aggregate that has passed through the second portion 14b of the fourth screen 14 is guided to the rear guide portion 55c of the fifth guide portion 55, and the rear storage portion 64c of the fourth storage portion 64. ) The aggregate stored in the rear reservoir 64c of the fourth reservoir 64 is aggregate in the sixth size range.

According to the aggregate selector configured as described above, in each screen of the main stage consisting of a four-stage screen, divided into two parts in the aggregate advancing direction to set the size of the mesh of each part or to form only a part in the aggregate advancing direction or In this way, the aggregates are divided into two parts in the direction of aggregate progress, forming a passage between the parts having different sizes of the net, so that the aggregate of six size ranges can be selected with four screens, without increasing the total volume of the aggregate selector. It has the effect of making it possible to further refine the screening size range of.

Claims (3)

The main body 10 having the four-stage screens 11 to 14, which decreases as the size of the mesh is lowered toward the lower end, is installed in the cover 1 so as to be inclined or horizontally below a predetermined angle in the direction of the aggregate with respect to the ground. It is installed to vibrate up and down or 45 ° angle, In order to guide the aggregates selected from the screens 11 to 14 to the hopper 60 at the front end portions of the screens 11 to 14 in the forward direction of the aggregate and the lower portion of the fourth screen 14. In the aggregate sorting machine in which the chute 50 is installed, The first screen 11 at the uppermost end of the main body 10 is divided into two parts in the aggregate travel direction and is formed of the first part 11a on the front side and the second part 11b on the opposite side in the aggregate travel direction. The mesh size of the first portion 11a is set larger than that of the second portion 11b, The second screen 12 below the first screen 11 is formed only in a portion corresponding to the first portion 11a of the first screen 11 so that the mesh size is the second of the first screen 11. Is set equal to the mesh size of the portion 11b, The third screen 13 at the lower end of the second screen 12 is divided into two parts corresponding to the first screen 11 so that the first part 13a at the front side and the opposite side at the forward direction of the aggregate are formed. It is formed of two parts (13b), the mesh size of the first portion (13a) is set larger than the mesh size of the second portion (13b) and smaller than the mesh size of the second screen 12, The fourth screen 14 at the lower end of the third screen 13 is divided into two parts in the aggregate travel direction, so that the first portion 14a on the front side and the second portion 14b on the opposite side in the aggregate travel direction. Is formed in the through hole 14c between the first portion 14a and the second portion 14b, The mesh size of the first portion 14a of the fourth screen 14 is greater than the mesh size of the second portion 13b of the third screen 13 and that of the first portion 13a of the third screen 13. Smaller than the mesh size, the mesh size of the second portion 14b of the fourth screen 14 is smaller than the mesh size of the second portion 13b of the third screen 13, and the through hole 14c Is formed in front of the position corresponding to the boundary between the first and second portions 13a, 13b of the third screen 13, At the rear end of the first portion 14a of the fourth screen 14, the upper end is obliquely connected to the bottom of the rear end of the first portion 13a of the third screen 13, and the lower end is perpendicular to the first portion 14a. Aggregate sorter, characterized in that the partition 19 is extended downward. The method of claim 1, The chute 50 is composed of first to fifth guide parts (51 to 55), The first to fourth guide parts 51 to 54 may include a first portion 11a, a second screen 12, a first portion 13a and a third portion of the first screen 11. 4 are respectively installed so as to extend to the ends of the front side in the direction of aggregate travel of each of the first to fourth screens 11 to 14 to guide the aggregates that have not passed through the first portions 14a of the screens 14, respectively. , The fifth guide part 55 is installed in the lower portion of the fourth screen 14 to guide the aggregate that has passed through the fourth screen 14, but the first portion 14b of the fourth screen 14, the through hole ( 14. An aggregate selector, characterized in that it is subdivided corresponding to 14c) and second portion (14b) and consists of a front guide portion (55a), an intermediate guide portion (55b) and a rear guide portion (55c). The method of claim 1, The first to fourth storage portions 61 to 64 of the hopper 60 are connected to the second to fifth guide portions 52 to 55 of the chute 50, respectively. The fourth storage unit 64 is subdivided to correspond to the subdivided fifth guide unit 55, and includes a front storage unit 64a, an intermediate storage unit 64b, and a rear storage unit 64c. Aggregate sorter, characterized in that the heat insulating material 70 is attached to the inner circumferential surface of the hopper (60) as a whole.