KR101154854B1 - A vibrating screen appratus - Google Patents

Abstract

PURPOSE: A sorting device for aggregate is provided to prevent blockage phenomenon, to improve aggregate-sorting efficiency by separating impurities like waste vinyl from aggregate by using ventilation to each screen. CONSTITUTION: A sorting device for aggregate comprises: a housing(100) in which a vibrator is mounted; a deck(200) consists of a plurality units(210) mounted inside the housing, between each of which has smaller gradient toward one direction, and is formed to form steps; a screen part(300) consists of a plurality of screen(310) mounted on the top of the units, consists of an overlapped part in order to form constant gap upwardly and downwardly between the screens; a plurality of hitting protrusion is projected from the overlapped part to one screen; and an elastic unit(400) mounted between the housing and the deck.

Description

Aggregate Screening Equipment {A Vibrating Screen Appratus}

The present invention relates to an aggregate sorting device for separating foreign matter from the aggregate, which will be described in more detail, by blocking the screen by hitting the screen using the vibration of the vibration device, by the blowing nozzle between the overlap between the screen The blower can separate the waste vinyl from the aggregate, and by installing elastic spheres with different lengths according to the slope between the housing and the deck and between the deck and the screen, the vibration is spread on the screen in multiple directions and also the vibration is caused by the slope. It relates to an aggregate screening device that can increase the efficiency of the aggregate screening by varying the width of.

In general, when producing aggregate using natural stone of the existing quarries as raw materials, it is used to separate the aggregate from the foreign matter by crushing the rock with a crusher, such as crusher and cone crusher, and passing the aggregate sorting device (screen device).

Such a conventional aggregate sorting device can separate the aggregate for each particle size through the screen inclined at a certain angle, but the slope is constant, aggregate is deposited in the upper direction of the screen to form a thick layer of aggregate layer, thin in the downward direction As the aggregate layer of the layer is formed, in particular, the aggregate is deposited in the upper direction, and foreign matter such as soil and sand is deposited on the mesh of the upper screen, so that the blockage phenomenon (mesh clogging phenomenon) occurs frequently. .

In order to solve this problem, various technologies have been proposed to increase the aggregate sorting efficiency by preventing the blockage phenomenon in the upward screen by decreasing the angle of the screen toward the downward direction.

However, even when using the aggregate screening device configured to decrease the angle of the screen toward the downward direction, the flow rate of the aggregate in the downward direction is small, the frequency of screen occlusion can not be reduced, and thus, there is a problem that the aggregate screening efficiency decreases. .

In addition, even in the case of foreign matters having a relatively small specific gravity such as waste vinyl and twigs mixed with aggregates and having large particles by the above-described technology, as in Patent Registration No. 863605, a blower is formed at the end of the screen so that foreign matters such as soil and sand are screened. By blowing air to the aggregate separated through the paper, a technique for separating foreign matters having a relatively small specific gravity such as waste vinyl and twigs and having large particles has been proposed.

However, even in this technology, the aggregate flowing on the screen has a relatively small specific gravity such as waste vinyl and twigs, and foreign particles with large particles are mixed, thus preventing foreign matters such as soil and sand deposited on the aggregate surface from being separated through the screen. There is a problem of lowering the aggregate selection efficiency.

The present invention has been made to solve the above problems, while varying the inclination of the screen, in particular to prevent the blockage phenomenon in the downward screen, by separating the foreign matter such as waste vinyl from the aggregate through the air blowing in each screen aggregate It is to provide an aggregate sorting device that can increase the sorting efficiency.

Aggregate sorting apparatus of the present invention as a means for achieving the above object is a housing equipped with a vibration device; A deck having a plurality of units mounted inside the housing, wherein each of the units has an inclination in one direction and a step configured to form a step; Comprising a plurality of screens mounted on the unit, the overlap portion is formed so that a predetermined gap between the screen is formed up and down, the overlap portion is a screen portion protruding a plurality of hitting projections on one screen; It is characterized by consisting of an elastic sphere mounted between the housing and the deck.

The overlapping part has a striking protrusion protruding from the upper screen, and a body portion is hinged to the lower screen to face the striking protrusion, and a striking addition is formed at the end of the body portion so that the impact of the striking lower screen due to the striking of the striking weight. It can be configured to be applied.

In addition, one or more blow nozzles may be provided between the unit and the screen to be blown at the overlapped portion, so that foreign matters such as waste vinyl and twigs may be filtered through the blower in each screen.

In addition, an elastic sphere is further mounted between the unit and the screen.

On the other hand, the elastic sphere may be composed of a fastening shaft on the spring portion and the spring portion, the lower end, in this case, the elastic sphere is configured to increase the length of the spring portion as the inclination of each of the unit is small, the unit is small inclination It is reasonable to impart greater vibration to the screen mounted on it in Esau.

In addition, in the present invention, the plate-shaped auxiliary elastic sphere bent in a "c" shape is further configured between the unit and the elastic sphere, it is reasonable that the vibration of the screen is configured to be added.

Meanwhile, the unit may include a pair of girder frames connecting the outer frame and the outer frame, and a pair of side frames mounted on the outer frame. In addition, the girder frame may be configured to hit the lower portion of the screen by vibrating a second striking projection.

Aggregate sorting apparatus of the present invention has the advantage that can be prevented from clogging the screen by giving a blow using the vibration of the vibration device to the screen to increase the efficiency of the aggregate screening.

In addition, the aggregate sorting apparatus of the present invention has the advantage of increasing the aggregate selection efficiency by separating foreign matters such as waste vinyl from the aggregate by the blow nozzle blowing between the overlap between the screen.

In addition, the aggregate sorting apparatus of the present invention has an advantage that the vibration from the housing can be spread to the screen in a multi-directional direction by mounting the elastic sphere between the housing and the deck and between the deck and the screen to increase the aggregate selection efficiency.

In addition, the aggregate sorting apparatus of the present invention has the effect of increasing the aggregate selection efficiency by providing a greater vibration in the screen having a lower inclination by differently configuring the elasticity of the elastic sphere according to the inclination of the screen.

1 is a schematic perspective view showing a state of use of the aggregate sorting apparatus of the present invention.
Figure 2 is an exploded perspective view of the aggregate sorting apparatus of the present invention.
Figures 3a and 3b is a side cross-sectional view showing an embodiment of part A in FIG.
Figure 4 is a side cross-sectional view showing the action of the blowing nozzle which is one configuration of the present invention.
5 is a front view showing a mounting state of each configuration of the aggregate sorting apparatus of the present invention.
Fig. 6 is a side sectional view showing the aggregate sorting apparatus of the present invention. Fig. 1 is a perspective view showing a prior art.

Hereinafter, the configuration and operation of the present invention will be described in more detail with reference to the accompanying drawings. In describing the present invention, the term or word used in the present specification and claims is based on the principle that the inventor can appropriately define the concept of the term in order to best describe the invention of his or her own. It should be interpreted as meanings and concepts corresponding to the technical idea of

Hereinafter, with reference to the drawings will be described a preferred embodiment of the present invention.

1 is a schematic perspective view showing a state of use of the aggregate screening apparatus of the present invention, Figure 2 is an exploded perspective view of the aggregate screening apparatus of the present invention, Figure 3a and Figure 3b is a side cross-sectional view showing an embodiment of a portion A in Figure 2 Figure 4 is a side cross-sectional view showing the action of the blow nozzle which is one configuration of the present invention, Figure 5 is a front view showing the mounting state of each configuration of the aggregate sorting apparatus of the present invention, Figure 6 is an aggregate sorting apparatus of the present invention It is a side cross-sectional view which shows.

As shown in FIG. 1, the aggregate screening apparatus of the present invention includes a housing 100, a deck 200 composed of a plurality of units 210, a screen portion 300 composed of a plurality of screens 310, and an elastic sphere ( 400).

As shown in FIG. 1, the housing 100 is composed of a pair (only one is shown in the drawing), and the deck 200 and the screen unit 300 are mounted therein, and the housing 100 is vibrated. Device 110 is configured to impart vibrations to housing 100. The vibrator 110 may be configured in various ways, when using an eccentric vibrator, an imbalance torque is generated in the screen unit 300. In addition, one end of the housing 100 is configured with the inlet frame 120 is configured to input the aggregate mixed with various foreign matter, the other end is configured with the outlet frame 130 is the final selected aggregate to the outside Let out. Here, the foreign matter is a concept including a foreign material separated from the aggregate by the screen 310, such as earth and sand adhered to the aggregate and waste vinyl, twigs and the like separated from the aggregate by the blow nozzle 500 to be described below.

Although not shown in the drawing, the housing 100 has a plurality of hoppers capable of receiving foreign matters such as earth and sand separated from the aggregate through the screen unit 300.

As shown in FIGS. 1 and 2, a deck 200 configured by assembling a plurality of units 210 is mounted inside the housing 100. The plurality of units 210 constituting the deck 200 is configured to form a step while decreasing the inclination in one direction, as shown in FIG. 2 and the like upward (direction in which the inlet frame 120 is configured in FIG. 1). In the downward direction, the inclination of each unit 210a, 210b, 210c becomes smaller. The different inclination is configured to maximize the sorting efficiency of the aggregates by varying the speed of the aggregates flowing through the screens 310a, 310b, 310c mounted on the upper portions of the units 210a, 210b, and 210c. In addition, the step of forming a step between each unit (210a, 210b, 210c) is also applied to the overlap (J) between the screen (310a, 310b, 310c) mounted on the upper portion of each unit (210a, 210b, 210c), By forming a predetermined play below, the striking protrusion 320 is configured in the overlapped portion J, thereby generating a vibration in the striking protrusion 320 based on the vibration of the screen 310 so that the striking protrusion 320 is screened. It is intended to prevent the mesh formed on the screen 310 is blocked by hitting (310).

The deck 200 formed by the assembly of the unit 210 is mounted on the housing 100 to transmit the vibration of the housing 100 to the screen unit 300 by mounting the upper screen unit 300. It is to function.

Each unit 210a, b, and c constituting the deck 200 includes a plurality of girder frames 212 connecting the pair of outer frames 211 and the outer frames 211 as shown in FIG. 5. And a pair of side frames 213 mounted on the outer frame 211, the side frame 213 is configured on the girder frame 212 and the girder in FIG. 5. Vibration from the housing 100 passes through the side frame 213 by mounting the auxiliary elastic sphere 430 to be described below, which is configured on the frame 212 and is between the girder frame 212 and the side frame 213. Amplified by the auxiliary elastic sphere 430, such an amplitude is to be transmitted to the girder frame 212,

The frames 211, 212, 213 can be fastened by welding, bolting, or the like by a known method, and a description thereof will be omitted.

In addition, the side frame 213 is to guide the aggregates introduced into the screen 300 by the bent end (213-1) is configured in the direction of the housing 100, respectively, as shown in Figure 5, the side frame The lower portion of the 213 is configured to be elastically bent portion (213-2) of the bent shape by protruding so that the vibration transmitted to the side frame 213 is easily transmitted to the auxiliary elastic sphere 430 and to the auxiliary elastic sphere Tighten by welding, bolting, etc.

In particular, in the present invention, the second striking protrusion 212-1 is configured to protrude from the girder frame 212, and the second striking protrusion 212-1 is the second striking protrusion based on the vibration of the screen 310. 212-1 strikes the screen 310 from the bottom to prevent blockage of the mesh formed on the screen 310. The second striking protrusion 212-1 protrudes to form a predetermined distance from the upper screen 310 so as to strike the screen 310 when the vibration of the screen 310 is greater than the predetermined distance. The second striking protrusion 212-1 may be made of various materials, more preferably, made of an elastic material such as rubber to prevent fatigue destruction on the screen 310 by continuous hitting. Valid

On the other hand, in the present invention by mounting the elastic sphere 400 between the housing 100 and the deck 200 and between the deck 200 and the screen 300 generated by the vibration device 110 of the housing 100 Vibration is caused by the first elastic sphere 410 between the housing 100 and the deck 200 to cause lateral vibration, and the second elastic sphere between the deck 200 and the screen 300 ( 420 causes longitudinal vibration to eventually transmit multi-directional vibration to the screen 300.

The elastic sphere 400 (410, 420) may be configured in various ways, but in the present invention as shown in Figure 5 as an embodiment of the spring portion 411, 421 and the spring portion 411, 421 The upper and lower fastening shafts 412 and 422 are configured to be mounted by welding and bolting by the upper and lower fastening shafts 412 and 422 of the spring parts 411 and 421. 411 and 421 to generate the elasticity and the restoring force to the vibration to transmit the vibration without weakening the amplitude. Although not shown in the drawings, the fastening shafts 412 and 422 are respectively equipped with spring portions 411 and 421 at the outer circumference thereof in the state of being inserted in the form of a receiving tube and an insertion tube at the center thereof. Each fastening shaft 412, 422 must be flanged to deliver a force to the 411, 421.

The first elastic sphere 410 is a configuration that is mounted between the housing 100 and the deck 200 to be described in more detail, one end of the coupling shaft 412 is attached to the housing 100, Figure 5 As shown in the deck 200, the coupling shaft 412 of the other end is attached to the side frame 213. Since the attachment of the fastening shaft 412 may use a variety of known techniques, the description thereof will be omitted. The vibration generated from the housing 100 based on the first elastic sphere 410 is transmitted to the deck 200, the vibration of the spring portion 411 by the elasticity and the restoring force, in particular the amplitude of the vibration is almost as it is transmitted This also causes vibration in the transverse direction.

In particular, the first elastic sphere 410 is configured to increase the length of the spring portion 411 as the inclination of each of the unit (210a, 210b, 210c) as shown in FIG. In other words, the spring portion 411 of the first elastic sphere 410 formed in the unit 210a in the upward direction is longer than the spring portion 411 of the first elastic sphere 410 formed in the intermediate unit 210b. The spring portion 411 of the first elastic sphere 410 is small, the spring portion 411 of the first elastic sphere 410 formed in the intermediate unit 210b is formed in the unit 210c in the downward direction. It is configured to have a smaller length. As shown in FIG. 2, the length of each spring portion 411 is configured such that d1 <d2 <d3. In the case of the screens 310a, 310b, and 310c mounted on the upper portions of the units 210a, 210b, and 210c, the inclination becomes smaller according to the inclination of the units 210a, 210b, and 210c. Based on the difference in the inclination of the screens 310a, 310b, 310c, the screen 310a in the upward direction speeds up the aggregate flow rate and at the same time reduces the vibration of the screen 310a to enable the rapid sorting of aggregates. In the screen 310b, the aggregate flow rate is appropriate, the vibration is also moderate, and in the downward screen 310c, the oscillation is increased while the flow rate is slowed to maximize the aggregate sorting efficiency at the outlet.

The second elastic sphere 420 is mounted between the deck 200 and the screen 300 to be described in more detail, as shown in Figure 5 the girder frame 212 constituting the unit 210 It is to be mounted between the auxiliary elastic sphere 430 mounted on the top of the screen 310. As shown in FIG. 5, the auxiliary elastic ball 430 is configured to have a plate shape bent in a "c" shape to correspond to a configuration for assisting the elasticity and the restoring force of the second elastic ball 420. That is, the vibration transmitted to the deck 200 like the second elastic sphere 420 is more easily transmitted to the screen unit 300, that is, the amplitude is not reduced. That is, one end of the fastening shaft 422 is attached to the upper surface of the auxiliary elastic ball 430, the other end of the fastening shaft 422 is attached to the screen (310). Since the attachment of the fastening shaft 422 can also use various known techniques, the description thereof will be omitted. The vibration generated from the housing 100 is transmitted to the screen unit 300 based on the second elastic sphere 420, but the amplitude of the vibration is almost transmitted as it is due to the elasticity and the restoring force of the spring portion 411. Will cause vibration in the longitudinal direction.

In this case, the second elastic sphere 420 is configured to increase the length of the spring portion 421 as the inclination of each of the units 210a, 210b, and 210c decreases. That is, as shown in FIG. 6, the length of each spring portion 421 is configured such that D1 < D2 < D3. In this case as well, the screen 310a in the upward direction based on the difference in the inclination of the screens 310a, 310b, and 310c speeds up the aggregate flow rate and at the same time reduces the vibration of the screen 310a to enable the rapid sorting of aggregates. In the middle screen (310b), the aggregate flow rate is appropriate, the vibration is also moderate, the screen 300c in the downward direction to maximize the aggregate sorting efficiency at the outlet by increasing the vibration while slowing the flow rate.

As described above, the screen unit 300 includes a plurality of screens 310 mounted on the deck 200 by the auxiliary elastic balls 430 and the second elastic balls 420. A fastening hole 311 facing the fastening shaft 422 is formed in the 310, and the fastening shaft 422 is inserted into the fastening hole 311 to be fastened by bolting or the like. As shown in Figure 4 by the mesh formed on each screen 310 by the screen unit 300 is to drop the foreign matter (S1), such as earth and sand adhered to the aggregate downward to screen the aggregate.

The screen unit 300 is composed of a plurality of screens 310, the upper screen 310a, the middle unit 210b which is mounted on the upper unit 210a by showing three parts in FIG. An example is shown which consists of an intermediate screen 310b mounted on the top of the bottom panel) and a downward screen 310c mounted on the top of the downward screen 310c.

As mentioned above, in the upward screen 310a, the intermediate aggregate and the large aggregate having a high inclination and the small vibration have high flow rate and flow to the intermediate screen 310b at high speed, so that only the fine aggregate is the upward screen ( The foreign material (S1) such as soil and sand is filtered in 310a), so that the residence time of the large aggregate and the intermediate aggregate is reduced by the large inclination and the small vibration in the upward screen 310a, thereby preventing the mesh from being blocked.

Since the intermediate screen 310b forms an intermediate inclination and forms an intermediate vibration, only large aggregate moves to the downward screen 310b, and thus foreign matters such as earth and sand adhered to the aggregate while only the intermediate aggregate stays on the intermediate screen 310b. (S1) is to pass through the mesh.

Since the downward screen 310c has a small inclination and the largest vibration occurs, the large aggregate receives sufficient residence time and vibration, and foreign matters S1 such as earth and sand adhered to the aggregate pass through the mesh and are sorted at the bottom.

The upper screen 310a, the middle screen 310b, and the lower screen 310c may be used in different sizes of the mesh.

In particular, the overlap portion (J) is configured to form a predetermined gap between the screen 310, the upper and lower in the present invention, as shown in Figure 3a and 3b, the intermediate screen (below the end of the upper screen 310a) The starting end of the 310b is positioned, and the starting end of the downward screen 310c is positioned below the end of the intermediate screen 310b. By hitting the screen 310 by the projection 320 is to shake off the foreign matter (S1), such as earth and sand that can adhere to the mesh formed on the screen 310 in the downward direction. That is, when the strike protrusion 320 becomes greater than a predetermined amplitude based on the vibration transmitted to the screen 310, the hitting of the screen 310 occurs, and the screen 310 can be prevented from being blocked due to such a hit. will be.

Meanwhile, in the present invention, two embodiments are presented in relation to the hitting protrusion. In FIG. 3A, the hitting protrusion 320 is formed at the lower portion of the upward screen 310a in the overlapping portion J, thereby causing vibration of a predetermined amplitude or more. When the blow projection 320 formed on the upper screen 310a automatically hits the intermediate screen 310b to shake off the foreign matter (S1) such as earth and sand adhered to the mesh of the intermediate screen 310b in the downward direction will be. In the present invention, since the residence time of the aggregate will increase in the intermediate screen 310b due to the difference in the slope between the upward screen 310a and the intermediate screen 310b as mentioned above, the foreign matter based on the aggregate residence time. In order to prevent the foreign matter deposited on the mesh by increasing the sorting efficiency of the foreign matter by having a long screening time of the hitting projection 320 interlocked based on the vibration of the upward screen (310a) to prevent the middle screen To hit the 310b to prevent the clogging of the mesh. Although this action is not shown in the drawings, the same description is omitted in the intermediate screen 310b and the downward screen 310c.

The hitting protrusion 320 also protrudes to form a predetermined distance from the lower screen 310 so as to strike the lower screen 310 when the vibration occurs in the upper screen 310 larger than the predetermined distance. In addition, the hitting protrusion 320 may be made of various materials. More preferably, the hitting protrusion 320 may be made of an elastic material such as a rubber material so as to prevent fatigue destruction on the screen 310 by continuous hitting.

In another embodiment, in FIG. 3B, the striking protrusion 320a is formed at the lower portion of the upper screen 310a in the overlapping portion J, and the striking protrusion 320a is disposed on the upper portion of the intermediate screen 310b to face the striking protrusion 320a. The body portion 332a is hinged to the hinge 331a, and the hitting weight 333a is formed at the end of the body portion 332a, which will be described in more detail. 331a is formed so that the body portion 332a is positioned in the direction of the center portion of the intermediate screen 310b, and the impact weight 333a is formed at the end of the body portion 332a, and the impact protrusion 320a is It is configured to protrude to the lower portion of the upward screen 310a to face one point of the body portion 332a. When the vibration is generated in the upward screen 310a and the intermediate screen 310b by this configuration, the vibration is generated in the striking protrusion 320a which is integrally connected with the upward screen 310a, and the intermediate screen 310b is Hinge linkage occurs up and down on the body portion 332a due to vibration, and the inertia force is applied to the L2 part in FIG. The impact weight 333a strikes the intermediate screen 310b with a large amplitude, and the foreign material S1 such as earth and sand adhered to the mesh of the intermediate screen 310b is shaken downward by such a strike. To this end, the distance L2 to the impact weight 333a is larger than the distance L1 to the hinge coupling 331a around the point facing the impact protrusion 320a in the body 332a. The inertial force (centrifugal force) is to be able to give a strong blow to the middle screen (310b), in addition to the striking weight (333a) by positioning the impact point in the direction of the center of the intermediate screen (310b) to the impact weight (333a) The impact of the blow is to widen the middle screen 310b. To this end, the body portion 332a is made of an elastic material so that the distance from the impact point to the impact weight 333a when the striking protrusion 320a strikes (controls) a point of the body portion 332a (L2) The upward lifting occurs in the body portion 332a corresponding to the restoring force, and the weight of the impact weight 333a is added to the bending portion 332a so that a strong impact is applied to the intermediate screen 310b. 3B, only the upward screen 310a and the intermediate screen 310b are illustrated in FIG. 3B, but the same configuration is formed in the overlapping portion J between the intermediate screen 310b and the downward screen 310c.

Meanwhile, in the present invention, as shown in FIG. 4, one or more air blowing nozzles 500 are configured between the unit 210 and the screen 310 to allow air to be blown out through the overlapping portion J. FIG.

That is, as shown in FIG. 4, a blowing nozzle 500 is provided between each unit 210a, b, and c and each screen 310a, b, and c, respectively. (310b) direction, the downward screen (310c) direction and the outlet frame 130 is to be allowed to blow out. As the blowing nozzle 500 is provided in the upward screen 310a, the aggregate is flowed to the intermediate screen 310b while the foreign matter S1 is separated by the inclination of the minimum, and the aggregate flows to the aggregate. Foreign matter such as soil and sand (S1) is deposited on the aggregate, as well as relatively light and large particles of foreign matter (S2), such as waste vinyl and twigs, are mixed and blown (blow) through the overlap (J) Relatively light and large particles (S2), such as vinyl and twigs, are separated from the aggregate to guide the downward screen 310c. In the case where relatively light and large particles of foreign matter (S2), such as waste vinyl and twigs, are mixed in the aggregate, separation of foreign matters (S1) such as soil and sand from the aggregate through the screen 310 is prevented, so that efficient aggregate selection is easy. In the present invention, by blowing the inside of the aggregate flows through the blowing nozzle 500, it is possible to separate the foreign matter (S2) such as waste vinyl and twigs from the aggregate, as well as the soil and other foreign matters on the aggregate surface. It is possible to increase the efficiency at which S1 is separated from the intermediate screen 310b. This action is the same action in the junction (J) between the intermediate screen (310b) and the downward screen (310c) bar description thereof will be omitted.

In addition, by the blowing nozzle 500 configured between the downward unit 210c and the downward screen 310c, the air is discharged to the outside of the outlet frame 130 so as to be finally sorted through the downward screen 310c. By blowing air to the aggregate, the waste vinyl, twigs such as foreign matter (S2) is to be introduced into a separate foreign matter treatment tank 600.

As such, the present invention includes a blowing nozzle 500 between each unit 210 and the screen 310 to blow the aggregate to the outside of the intermediate screen 310b, the downward screen 310c and the outlet frame 130. By continually separating the foreign matter (S2) such as waste vinyl and twigs from the aggregates in each screen 310 to the separate foreign matter treatment tank 600, through the separation, such as earth and sand in each screen 310 By easily separating the foreign matter (S1) from the aggregate will eventually increase the aggregate sorting efficiency.

Although not shown in the drawings, the blowing nozzle 500 configured between each unit 210 and the screen 310 may be configured to blow air at a time in one line, and optionally, the unit 210. ) And the screen 310 may be configured to allow ventilation.

On the other hand, if necessary, the deck 200 and the screen unit 300 may be configured to be laminated in a plurality of pairs in order to filter the aggregates in plural, thereby increasing the accuracy thereof.

100: housing 110: vibration device
120: inlet frame 130: outlet frame
200: Deck 210: Unit
300: screen portion 310: screen
400: elastic ball 500: blowing nozzle

Claims (8)

A housing equipped with a vibration device;
A deck having a plurality of units mounted inside the housing, wherein each of the units is configured such that an inclination is reduced in one direction and a step is formed;
Comprising a plurality of screens mounted on the unit, the overlap portion is formed so as to form a predetermined gap between the screen, the overlap portion has a screen portion protruding a plurality of projection projections on one screen;
Aggregate sorting device, characterized in that consisting of the elastic sphere mounted between the housing and the deck. The method of claim 1,
In the overlapping portion,
A striking projection protruding from the upper screen, the body portion is hinged to the lower screen to face the striking projection, aggregate aggregate selection device characterized in that the striking addition is configured at the end of the body portion. The method of claim 2,
The body portion aggregate selection apparatus, characterized in that the distance between the striking weight is greater than the distance between the hinge coupling around the point facing the striking projection. The method of claim 1,
At least one blowing nozzle is provided between the unit and the screen, the aggregate sorting device, characterized in that configured to be blown in the overlap. The method of claim 1,
Aggregate sorting device characterized in that the elastic sphere is further mounted between the screen and the unit. delete 6. The method of claim 5,
Aggregate sorting apparatus further comprises a plate-shaped auxiliary elastic sphere bent in a "c" shape between the unit and the elastic sphere. The method of claim 1,
The unit includes a pair of girder frames connecting the outer frame and the outer frame, and a pair of side frames mounted on the outer frame, wherein the plurality of second striking protrusions protrude from the girder frame. Aggregate sorting device.

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