KR101949922B1 - Functional hybrid soil separator - Google Patents

Abstract

The present invention relates to a functional hybrid soil separator. In the functional hybrid soil separator, a main frame having twin shaft driving units is coupled with a stand frame having an angle adjusting unit by a buffer unit, and variable amplitude adjusting units are included in the twin shaft driving units. The twin shaft driving units are coupled so that an eccentric shaft having a predetermined interval in the main frame is able to rotate by a bearing support body; the variable amplitude adjusting units are coupled to both sides of the eccentric shaft penetrating the bearing support body; a pulley and a belt are connected to an end part of one side of the eccentric shaft penetrating a variable amplitude adjusting unit of one side; and a driven pulley is coupled with an end part of the other side of the eccentric shaft penetrating a variable amplitude adjusting unit of the other side and is connected to a driving pulley of a driving motor through a driving belt. Therefore, the present invention is able to increase a soil selection ratio while minimizing working time consumed for the control of an unbalance rate by accurately adjusting the unbalance rate, and is able to extend a lifespan by preventing durability from being shortened.

Description

Functional Hybrid Soil Separator {FUNCTIONAL HYBRID SOIL SEPARATOR}

The present invention relates to a functional hybrid soil-separator-dedicated separator, and more particularly to an unbalance amount of an eccentric shaft provided in a twin-shaft driving unit in a main frame.

In general, sand is generally divided into quartz, black spruce, and greenstone depending on the composition of the mineral. It is divided into rocks and minerals with very small diameters. It is divided into mountains, lecturers, marines, .

The sand is selected using a dry or wet screening device. The wet screening device uses an electric flat screen or rotary cylinder to remove the stones from the crushed aggregate using water. It has no crushing function, It produces gravel and less than 5 mm of sand, and the sizes above are used for other purposes.

The dry screening apparatus usually produces 25 mm gravel or 40 mm sized mixed stone, and there is also the purpose of producing the stone.

On the other hand, a vibration discriminating device for aggregate of Japanese Patent Application Laid-Open No. 10-2013-0014206 (Mar. 03, 2013) (2013.02.07) has been proposed. In the proposed separator, the first and second flywheels are inclined downward The first and second eccentric cams can be fixedly mounted at different angles in a state in which the first and second eccentric cams having a substantially fan shape are built in each of the first and second flywheels, However, since the angle adjustment of the first and second eccentric cams is adjusted by using a hammer or a hammer and then fixed by a bolt, it is difficult to work and it is difficult to adjust the unbalance amount accurately.

In addition, when the exact unbalance amount can not be matched, there is a problem in that vibration of unequal amplitude occurs, resulting in lower durability and shortened life span.

Japanese Patent Application Laid-Open No. 10-2013-0014206 (Feb.

This invention makes it possible to precisely adjust the unbalance amount of the eccentric shaft, thereby improving the sorting performance of the sorter, thereby enhancing the safety and convenience of the operator, So that it is possible to prevent deterioration of durability.

The present invention is characterized in that a main frame 20 having a twin shaft driving unit 10 is coupled to a stand frame 50 having an angle adjusting unit 40 by a buffer 30, The twin shaft drive unit 10 includes an eccentric shaft 11 having a predetermined spacing in a main frame 20 and a bearing support 12 And the variable amplitude control unit 60 is coupled to both sides of the eccentric shaft 11 passing through the bearing support 12. The variable amplitude control unit 60, The pulley 13 and the belt 14 are connected to one end of the eccentric shaft 11 passing through the other side of the eccentric shaft 11 and the other end of the eccentric shaft 11 passing through the other side of the variable- (15) is coupled to the drive pulley (17) of the drive motor (16) and the drive belt And the variable amplitude control unit 60 includes an unbalance fixed weight unit 620 having a variable weight drive unit 610 fixedly coupled to the eccentric shaft 11 and an unbalanced fixed weight unit 620 fitted to the eccentric shaft 11, The unbalance fixing weight portion 620 includes a semi-circular fixed weight body 622 having a fixed shaft hole 621. The fixed weight body 622 is fixed to the fixed weight body 622 by a variable weight driving portion 610, The variable weight drive unit 610 is formed with the edge 623 protruding in the axial direction to form the variable weight insertion space 624 at the inner periphery of the rim 623 and the front surface of the fixed weight body 622, The worm shaft 614 having the worm gear 613 is rotatably supported by the bearing 615 and the bearing cap 616 in the drive guide body 612 having the shaft support hole 611 formed in the upper part of the rim 623 And the unbalanced The variable weight portion 630 has a boss 632 in which a shaft hole 631 is formed and a worm wheel 634 is formed on the outer peripheral edge portion of the disk-shaped variable weight body 633. The shaft hole 631, And a weightless portion 635 having a semicircular shape is formed between the upper portion and the worm wheel 634 on which the worm wheel 634 is formed.

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The edge 623 of the fixed weight body 622 is formed with an angular display portion 321-1 having a graduation at regular intervals on the end portion thereof and has a handle engagement portion And the boss 632 of the unbalance variable weight portion 630 is formed with a female screw portion 632-1 having a shape penetrating the outer peripheral edge portion toward the inner peripheral edge portion, 636 are coupled to each other.

The eccentric shaft 11 of the twin shaft driving unit 10 is characterized in that the hollow protector 19 is coupled by a protector support 19-1 provided outside the bearing support 12.

The stand frame 50 includes a horizontal frame 51 having a horizontal shape and one side of an inclined frame 52 having an inclined shape pivotally coupled to the hinge unit 53, And the angle regulating portion 40 is coupled to the other side of the inclined frame 52.

The angle regulator 40 is provided with a hydraulic regulator 410 and a support fixture 420. The hydraulic regulator 410 controls the hydraulic cylinder 411 in the horizontal frame 51 by means of a bracket BT And a cylinder rod 412 is rotatably coupled to the inclined frame 52 by means of a bracket BT and the support pin fixing hole 420 is formed such that the outer pin hole 421 is rotatably fitted at a predetermined interval The hollow upper support bracket 422 is rotatably coupled to the horizontal frame 51 by the bracket BT and the hollow upper support bracket 424 having the inner pin holes 423 formed at regular intervals is inserted into the bracket BT, And the hollow upper support 424 is fitted to the hollow lower support 422 and is fixed to the outer pin hole 421 and the inner pin hole 423 by a fixing pin 425 ).

The lower end of the twin coil spring 32 is coupled to the lower cushioning support frame 31 provided on the upper portion of the inclined frame 52 of the stand frame 50, And the lower portion of the upper buffer support frame 33 provided on the main frame 20 is coupled to the upper portion of the upper buffer support frame 32.

The pulley 13 and the belt 14 provided at one end of the eccentric shaft 11 are provided with a timing pulley and a timing belt.

The driven pulley 15 and the drive belt 18 provided at the other end of the eccentric shaft 11 are provided with a plurality of rows of V-belt pulleys and V-belts.

The present invention can provide an effect that the unbalance variable weight portion of the variable amplitude adjusting portion provided on the eccentric shaft of the twin shaft driving portion can be precisely controlled by the worm gear and the worm wheel.

In addition, by minimizing the working time required to adjust the unbalance amount, it is possible to obtain an effect that the working time required for sorting the soil is increased.

In addition, it is possible to obtain an effect of increasing the soil sorption rate.

In addition, since the vibration force generated in the soil sorption process is always maintained uniformly, it is possible to prevent shock vibrations in the driving process and to prevent the durability of the sorter from being shortened.

In addition, the safety and convenience of the operator can be improved by this.

This can reduce the time and cost required for the inspection, repair and exchange of the sorter.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front view showing a functional hybrid soil-separating apparatus according to the present invention; Fig.
FIG. 2 is a front view showing a stand frame in the functional hybrid soil-separating apparatus according to the present invention. FIG.
FIG. 3 is a cross-sectional view of a twin-shaft driving unit combined with a variable-amplitude control unit in the functional hybrid soil-separating apparatus according to the present invention.
FIG. 4 is a perspective view showing a variable amplitude controller in the functional hybrid soil-separator according to the present invention; FIG.
FIG. 5 is a perspective view showing a variable amplitude control unit in a functional hybrid soil-separating apparatus according to the present invention. FIG.
6A and 6B are front views showing the front and rear of the variable amplitude control unit in which the amplitude of the variable amplitude control unit is adjusted in the functional hybrid soil-only discriminator according to the present invention.

Embodiments of the present invention will now be described with reference to the accompanying drawings.

FIG. 1 is a front view showing a functional hybrid soil-specific separator according to the present invention, FIG. 2 is a front view showing a stand frame in the functional hybrid soil-only separator according to the present invention, and FIG. FIG. 4 is a perspective view showing a variable amplitude control unit in the functional hybrid soil-only separator according to the present invention, and FIG. 5 is a perspective view showing the variable-amplitude control unit in the functional hybrid soil- FIGS. 6A and 6B are diagrams illustrating a functional hybrid soil-only separator according to the present invention. FIG. 6A and FIG. 6B are views showing a functional hybrid soil- Fig.

The functional hybrid soil-only separator (A) according to the present invention can precisely adjust the unbalance amount so that the working time can be minimized while the soil sorption rate can be increased and the durability 1 to 5, a main frame 20 having a twin shaft driving unit 10 is fixed to a stand frame 30 having an angle adjusting unit 40 by a buffer 30, (50), and the twin shaft driver (10) is provided with a variable amplitude controller (60).

Here, the twin shaft driving unit 10 is rotatably coupled to the main frame 20 by an eccentric shaft 11 having a predetermined distance therebetween by a bearing support body 12.

A variable amplitude control unit 60 is coupled to both sides of the eccentric shaft 11 passing through the bearing support 12 and the eccentric shaft 11 passing through the variable amplitude control unit 60 And the pulley 13 and the belt 14 are connected to each other.

A driven pulley 15 is coupled to the other end of the eccentric shaft 11 passing through the other variable amplitude adjuster 60 and connected to the drive pulley 17 of the drive motor 16 by a drive belt 18 The drive pulley 17, the drive belt 18 and the driven pulley 15 according to the rotation of the drive motor 16 are interlocked and the eccentric shaft 11 is rotated to generate a vibration force.

The eccentric shaft 11 is engaged with a protector support 19-1 provided on the outside of the bearing support 12 so that the protrusion collides with the surface of the eccentric shaft 11 from the outside, So that it is prevented from being fixed.

It is preferable that the pulley 13 and the belt 14 provided at one end of the eccentric shaft 11 are provided with a timing pulley and a timing belt so that accurate rotation without slip can be transmitted, It is more preferable that the driven pulley 15 and the drive belt 18 provided at the other end of the belt 11 are provided with a plurality of rows of V-belt pulleys and a V-belt so that sufficient driving force can be transmitted.

The buffer 30 prevents the vibration of the main frame 20 from being transmitted to the stand frame 50 in the course of driving the separator. The buffer 30 is provided on the upper surface of the slope frame 52 of the stand frame 50 A lower portion of the twin coil spring 32 is coupled to the lower cushioning support frame 31 and the lower portion of the upper cushioning support frame 33 provided on the main frame 20 on the upper portion of the twin- As shown in Fig.

The angle adjuster 40 is provided to improve the workability by lowering or increasing the angle of the main frame 20 during the process of selecting the gravel by using a sorter, 410 and a support fixture 420 to maintain a controlled angle.

The hydraulic pressure regulator 410 is configured such that the hydraulic cylinder 411 is rotatably coupled to the horizontal frame 51 by the bracket BT and the cylinder rod 412 is connected to the inclined frame 52 by the bracket BT The cylinder rod 412 is moved into and out of the hydraulic cylinder 411 by the oil (pressure) supplied to the hydraulic cylinder 411 through a hydraulic pressure supply line or line not shown in the drawing, So that the inclination of the slider 52 can be adjusted.

The supporting bracket 420 is rotatably coupled to the horizontal frame 51 by means of a bracket BT and the inner pin hole 421 is rotatably coupled with the inner pin hole 423 A hollow upper support 424 formed at regular intervals is rotatably coupled to the inclined frame 52 by a bracket BT.

The hollow upper support 424 is fixed to the hollow lower support 422 by a fixing pin 425 fitted to the outer pin hole 421 and the inner pin hole 423, So that the height can be fixed when the height is adjusted. That is, the fixed state of the height can be maintained while the driving of the hydraulic pressure regulator 410 is stopped.

The stand frame 50 has a slope of the main frame 20 so that the main frame 20 can be stably supported at an upper portion thereof. The slope of the slope of the main frame 20 is inclined at an upper portion of the horizontal frame 51 having a horizontal shape And the angle adjusting unit 40 is coupled to the other side of the horizontal frame 51 and the inclined frame 52 .

The variable amplitude control unit 60 is provided with a variable weight drive unit 610 fixedly coupled to the eccentric shaft 11 for obtaining an optimal vibration force during the process of selecting the earth and sand using a sorter, And an unbalanced variable weight portion 630 which is fitted to the eccentric shaft 11 and whose weight is varied by the variable weight driver 610.

The unbalanced fixed weight portion 620 is formed in a semicircular fixed weight body 622 having a fixed shaft hole 621 and a rim 623 protruding in the axial direction so that the inner peripheral portion of the rim 623 and the fixed weight body 622, And a variable weight insertion space 624 is formed in the front surface of the body 622.

The variable weight drive unit 610 is provided for driving the drive guide body 612 having a shaft support hole 611 formed at the upper portion of the rim 623 for giving an accurate change in the weight, A worm shaft 614 having a worm gear 613 is rotatably coupled by a bearing 615 and a bearing cap 616. [

The unbalance variable weight portion 630 has a boss 632 in which a shaft hole 631 is formed and a worm wheel 634 is formed on the outer peripheral edge portion of the disk-shaped variable weight body 633, A weightless portion 635 having a semicircular shape is formed between the upper portion and the worm wheel 634 on which the worm wheel 631 and the worm wheel 634 are formed.

The edge 623 of the fixed weight body 622 is formed with an angle display portion 321-1 having a graduation at regular intervals in order to accurately rotate the unbalance variable weight portion 630 at the end portion thereof, 614 are formed at the ends of the wings 614 so as to rotate the worm shaft 614 by engaging the handles H with each other. At this time, the handle H is not engaged with the handle coupling portion 614-1 so that the handle can be separated from the handle and the unbalance of the weight can be prevented during the rotation.

The boss 632 of the unbalance variable weight portion 630 is formed with a female screw portion 632-1 having a shape penetrating the outer periphery toward the inner periphery so that the loosening prevention bolt 636 is engaged with the shaft hole 631 So that it is possible to prevent the position of the variable balance weight portion 630 from being changed during the rotation of the eccentric shaft 11.

In this sorting machine A, the driving force of the driving motor 16 is transmitted to the main frame 20 via the driving pulley 17, the eccentric shaft 11 rotatably provided on the main frame 20 by the driving belt 18 and the driven pulley 15 As the main frame 20 is vibrated by the generated vibrating force, the screen is vibrated together with the vibration of the main frame 20. As the screen is vibrated, Respectively. At this time, the generated vibration force can be prevented from being transmitted to the stand frame 50 by the twin coil spring 32 of the cushioning unit 30.

When the slope of the main frame 20 is adjusted in order to increase the sorting rate in this process, as shown in the right side of FIG. 2, the fixing pin 425 of the supporter fixing member 420 contacts the outer pin hole 421, The slant frame 52 is positioned at an arbitrary position by using the hydraulic pressure regulator 410 and then the removed pin 425 is inserted into the outer pin hole 421 and the inner pin hole 421, The inclination can be easily adjusted by being inserted into the pinhole 423.

In order to adjust the vibrating force of the selector, unlocking bolts 636 screwed to the boss 632 of the unbalance variable weight portion 630 are released to release the binding force with respect to the eccentric shaft 11 The handle H is engaged with the handle engaging portion 614-1 formed on the worm shaft 614 and then the handle H is rotated and the worm shaft 614 is rotated as shown by the one- The worm gear 613 is interlocked.

6B, the unbalanced variable weight portion 633 of the unbalanced variable weight portion 630 is fixed to the unbalanced fixed weight portion 620 by rotating the worm wheel 634 engaged by the rotation of the worm gear 613, When the eccentric shaft 11 is rotated, the vibration force can be increased or decreased by rotating the variable weight insertion space 624 in the counterclockwise direction. At this time, by making the arrow formed at the lower portion of the variable weight body 633 coincide with the angle display portion 623-1 formed by the scale formed on the rim 623 of the unbalanced fixed weight portion 620, fine adjustment is possible At the same time, since the variable weight body 633 at the other position is also rotated by the same amount, it is possible to prevent generation of a uniform vibration force.

Then, the variable-amplitude body 633 is constrained to the outer circumferential edge of the eccentric shaft 11 by tightening the loosening prevention bolt 636 that has been loosened.

10: Twin shaft driving part 11: Eccentric shaft
12: bearing support 13: pulley
14: belt 15: driven pulley
16: drive motor 17: drive pulley
18: drive belt 20: main frame
30: buffer portion 40: angle adjusting portion
50: Stand frame 60: Variable amplitude control unit
610: Variable weight driver 611: Shaft support hole
612: drive guide body 613: worm gear
614: Worm shaft 615: Bearing
616: Bearing cap 620: Unbalanced fixed weight part
621: Fixed shaft hole 622: Fixed weight body
623: rim 624: variable weight insertion space part
630: Unbalance variable weight portion 631: Shaft hole
632: Boss 633: Variable weight body
634: Worm wheel 635: Weightless part

Claims (9)

The main frame 20 having the twin shaft driving portion 10 is coupled to the stand frame 50 having the angle adjusting portion 40 by the buffer portion 30 and the twin shaft driving portion 10 is provided with the variable amplitude control (60), characterized in that the functional hybrid soil-only separator (A)
The twin-shaft driving unit 10 includes an eccentric shaft 11 having a predetermined spacing in the main frame 20 and rotatably coupled to the eccentric shaft 11 through the bearing support 12, And the pulley 13 and the belt 14 are connected to one end of the eccentric shaft 11 passing through the variable amplitude control part 60 on one side, And a driven pulley 15 is coupled to the other end of the eccentric shaft 11 passing through the variable amplitude adjuster 60 on the other side to drive the drive pulley 17 of the drive motor 16 ),
The variable amplitude control unit 60 includes an unbalance fixed weight unit 620 having a variable weight drive unit 610 fixedly coupled to the eccentric shaft 11 and an unbalanced fixed weight unit 620 fitted to the eccentric shaft 11, The unbalance fixing weight portion 620 is provided with a semicircular fixed weight body 622 having a fixed shaft hole 621 and an edge 623 A variable weight insertion space 624 is formed at an inner peripheral edge of the rim 623 and a front surface of the fixed weight body 622. The variable weight driving unit 610 has a rim 623 A worm shaft 614 having a worm gear 613 is rotatably coupled to a drive guide body 612 having a shaft support hole 611 formed at an upper portion of the drive shaft 611 by a bearing 615 and a bearing cap 616, The unbalance variable weight The worm wheel 633 has a boss 632 in which a shaft hole 631 is formed and a worm wheel 634 is formed on the outer periphery of the disk-shaped variable weight body 633, And a weightless portion (635) having a semicircular shape is formed between the worm wheel (634) and the worm wheel (634).
delete The method according to claim 1,
The edge 623 of the fixed weight body 622 is formed with an angular display portion 321-1 having a graduation at regular intervals on the end portion and a handle engagement portion 614 having a polygonal shape at the end portion of the worm axis 614 And the boss 632 of the unbalance variable weight portion 630 is formed with a female screw portion 632-1 having a shape penetrating the outer peripheral edge portion toward the inner peripheral edge, Wherein the functional hybrid soil-specific separator is combined with the functional hybrid soil-specific separator.
The method according to claim 1,
Characterized in that the eccentric shaft (11) of the twin shaft driving part (10) is coupled with a protective protector support (19-1) provided on the outside of the bearing support (12) .
The method according to claim 1,
The stand frame 50 includes a horizontal frame 51 having a horizontal shape and one side of a slant frame 52 having an inclined shape pivotally coupled to the hinge unit 53, And the angle regulating portion (40) is coupled to the other side of the inclined frame (52).
The method according to claim 1,
The angle regulating part 40 is provided with a hydraulic pressure regulator 410 and a supporting block fixture 420. The hydraulic pressure regulator 410 has a hydraulic cylinder 411 mounted on the horizontal frame 51, And a cylinder rod 412 is rotatably coupled to the inclined frame 52 by means of a bracket BT and the support pin fixture 420 is rotatably connected to the outer pin hole 421 by a hollow Type lower support 422 is rotatably coupled to the horizontal frame 51 by means of the bracket BT and a hollow upper support 424 with an inner pin hole 423 formed at a predetermined interval is supported by the bracket BT The hollow upper support 424 is fitted to the hollow lower support 422 to be fixed to the outer pin hole 421 and the fixing pin 425 to be fitted to the inner pin hole 423 The functional hybrid soil-only dedicated line Group.
The method according to claim 1,
The lower end of the twin coil spring 32 is coupled to the lower cushioning support frame 31 provided on the upper portion of the inclined frame 52 of the stand frame 50, And a lower portion of an upper buffer support frame (33) provided on the main frame (20) is coupled to an upper portion of the main frame (20).
The method according to claim 1,
Wherein the pulley (13) and the belt (14) provided at one end of the eccentric shaft (11) are provided with a timing pulley and a timing belt.
The method according to claim 1,
Wherein the driven pulley (15) and the drive belt (18) provided at the other end of the eccentric shaft (11) are provided with a plurality of rows of V belt pulleys and V belts.

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