RU154504U1 - Vibrating Screen - Google Patents

Abstract

1. A vibration screen comprising a box mounted on supports through elastic elements with one screening surface and a directional vibration exciter, the drive shaft of which is kinematically connected to the drive, the vibration exciter is mounted on the box with the possibility of fixed movement along an arc of a circle, and the drive is placed on a movable base with the possibility of fixed movement along a cylindrical guide, characterized in that the vibration exciter is made in the form of a paired symmetrical gear-planetary mechanism with unbalance, which is placed in a glass mounted in the exciter case with the possibility of rotation relative to the geometric axis of the central gears and subsequent fixation using a rotary-locking mechanism, the side walls of the box in their upper part are equipped with two curved guides in the form of plates with an arc groove , each supporting part of the exciter housing passes through the arc grooves of curved guides and is fixed on them with the help of a mounting unit, the guide is movably a base actuator motor is a convex cylindrical surface is formed by copying the profile of the arc of the groove in the side wall of the box, and a kinematic connection a drive motor with a drive shaft exciter is designed as a cardan transmission, wherein the eccentric weight is fixed to a common shaft satellitov.2. Vibrating screen according to claim 1, characterized in that the mounting unit of the vibration exciter is made in the form of two plates adjacent to them from two sides with three through holes. 3. Vibrating screen according to claim 1, characterized in that �

Description

The utility model relates to mining and processing equipment, namely, devices for separating bulk materials by size, and can be used in the mining, metallurgical and construction industries.

Known vibrating screen according to the patent for the invention of the Russian Federation (RU 2416467, B07B 1/40, 04/20/2011). It contains a box mounted on supports through elastic elements with screening surfaces and a directional vibration exciter in the form of a pair of inertial synchronized pair of vibrator gears with two unbalances cantilevered on each shaft. The vibration exciter is placed with the possibility of rotation (with fixation) on a frame rigidly connected to the box, and the vibration exciter body with its cylindrical protrusions in the area of the drive shaft enters the corresponding holes of the frame, and the fixation of the inclined position of the vibration exciter case is pivotally connected to it and has a bolted connection with one from the frame holes located along an arc of a circle centered on the geometric axis of the drive shaft. This allows you to simplify the reconfiguration and the time for its implementation when screening bulk materials with different physical properties. The disadvantage of this known device is the limited field of action of inertial forces and the inability to change the position of the line of action of the driving force of the vibration exciter at fixed points on the trajectory of its movement.

Known vibration multi-deck screen for sorting fine-grained materials according to the patent of the Russian Federation for a utility model (RU 130887 U1, B07B 1/40, 08/10/2013). It contains a box installed through the elastic elements with screening surfaces and a directional vibration exciter in the form of a block of two inertial vibrators. The vibration exciter drive is made in the form of two electric motors connected by elastic couplings with vibrator shafts synchronized through a gear transmission. The vibrator unit is mounted on the box with the possibility of movement and subsequent fixing along an arc of a circle with a center lying on an axis passing through the center of mass of the box, which makes it possible to change the angle of the direction of vibration, and this ensures the straightness of the vibrations of the box with the possibility of adjusting the screen to achieve improved technological parameters . The disadvantage of this known device, adopted as a prototype, is the inability to change the position of the line of action of the driving force of the vibration exciter at fixed points on the trajectory of its movement, which limits the functionality of the screen.

The objective of the utility model is to create a vibrating screen that allows you to change the direction of the line of action of the driving force of the vibration exciter, after fixing the vibration exciter on the curved guide box to increase screening efficiency and expand operational, technological and functional capabilities.

To solve the problem with the achievement of the specified technical result, the proposed vibrating screen comprises a box mounted on supports through elastic elements with at least one screening surface and a directional vibration exciter, the drive shaft of which is kinematically connected to the drive. The vibration exciter is mounted on the box with the possibility of fixed movement along an arc of a circle, and the drive is placed on a movable base with the possibility of fixed movement along a cylindrical guide. The vibration exciter is made in the form of a paired symmetrical gear-planetary mechanism with an unbalance. The gear-planetary mechanism is placed in a glass mounted in the exciter housing with the possibility of rotation about the geometric axis of the central gears and subsequent fixation using the rotary-locking mechanism. The side walls of the box in their upper part are equipped with two curved guides in the form of plates with an arc groove. Each supporting part of the exciter housing passes through the arc grooves of the curved guides and is fixed to them with the help of a mounting unit. The guide of the movable base of the drive motor is convex, made on a cylindrical surface copying the profile of the arc groove in the side wall of the box. The kinematic connection of the drive motor with the drive shaft of the vibration exciter is made in the form of a cardan transmission. The imbalance of the paired symmetrical gear-planetary mechanism is fixed on the common satellite shaft.

To increase the reliability of the design, the vibration exciter mounting assembly for fixing the exciter housing in each of the two curved guides mounted on the box is made in the form of two plates adjacent to them on two sides with three through holes - one central to cover the corresponding supporting part of the vibration exciter housing and two mounting holes and two screws passing through the holes of the pads and the arc groove of the curved guide screwed into the corresponding end of the exciter housing and esuschih nuts, locking plates and screws.

To increase the accuracy of adjusting the direction of vibration of the vibration exciter, its rotary-locking mechanism of the glass in the housing includes a lever rigidly connected at one end to the shaft of the glass and at the other end through a lever row located in the lever handle with one of the holes of a circular row made on a removable flange at the end of the non-drive bearing parts of the exciter housing.

To reduce the setup time for the required screening mode, the vibrating screen can be equipped with a mechanism for arcing the vibration exciter together with the drive of the latter, the mechanism of such movement is made in the form of an N-shaped rotary frame with a rotary drive in the form of a double-acting hydraulic cylinder, the frame is pivotally connected to the rotation drive, each of the sides the pivoting frame in its upper part is equipped with an orientably biased, removably fixed fork for engaging with the supporting part of the body of the vibration locomotive the wake-up device, and in its lower part it is pivotally connected to the support with the pivot axis, the pine geometric axis of the cylindrical guide, and one of the sides of the pivoting frame is connected with the movable base of the vibration exciter drive motor with the ability to move along the cylindrical guide in an unsecured state, for example, such communication is made by the movable base with two screw stops engaged with the sides of the fork.

The essence of the utility model is illustrated by drawings, where:

in FIG. 1 shows a front view of a vibrating screen with a partial section;

in FIG. 2 is a view A in FIG. one;

in FIG. 3 is a view B in FIG. 1, in partial section;

in FIG. 4 - vibration exciter of directional action of planetary-gear type, longitudinal section (kinematic diagram);

in FIG. 5 - remote element B in FIG. 3, part of a side view with a partial section (mounting unit for fixing the vibration exciter in a curved guide box and the connection of the rotary frame with the movable base of the electric drive of the vibration exciter);

in FIG. 6 is a part of section GG in FIG. 5;

in FIG. 7 and 8 - the trajectory of the center of mass of the vibration exciter unbalance depending on the size of the angle β of fixing the glass relative to the housing, respectively (transverse projections of the kinematic diagram of the vibration exciter);

in FIG. 9 and 10 are diagrams of setting the direction of the line of action of the excitation force of the vibration exciter at various positions of fixation of the exciter in the curved guide rails of the box (with the passage of the line of action of the excitation force through the center of mass of the box and outside it, respectively).

The utility model is a vibrating screen (Fig. 1 ... 4), containing box 1, for example with one screening surface 2 and mounted on the box vibration exciter 3 directional drive 4 (preferably electric).

The screening surface 2 is made in the form of a flat sieve with cells 2a, the shape and size of which depends on the fractional composition of the material to be screened. Box 1 may have several screening surfaces 2 (not shown in the drawing).

Box 1 is supported by four supports 5 through elastic elements 6, for example in the form of compression springs. The side walls 7 of the box 1 limit the working space of the screen in a longitudinal section and serve to attach functional units and mechanisms. In its upper part, the side walls of the box 7 are provided with two curved guides 8 in the form of plates with an arc groove 9 for interaction with the vibration exciter 3. The center O _{p of the} middle arc 9a of the groove 9 lies on the vertical 10, and the radius R of the arc 9a is greater than the distance L between the centers O _n and O _m (R> L).

The directional vibration exciter 3 (Figs. 4 and 7) is made in the form of a paired symmetrical gear-planetary mechanism with an unbalance 11 fixed on a common shaft 12 of satellites 13 having a diameter d of the pitch circle 14 half the diameter D of the pitch circle 15 of the central gears 16 internal gearing, i.e. d = 0.5D. In this case, the projection C ^{1 of the} center of mass C of the unbalance 11 is located on the pitch circle 14 of the satellites 13, the carrier 17 and 17a are equipped with counterweights 18. On the shaft 12 of the satellites 13, support wheels 20 that are in contact with the racetracks 19 are installed, which have a diameter equal to the diameter of the pitch circle 14 of the satellites 13, and their treadmills 19 have a diameter equal to the diameter of the pitch circle of the central gears 16. The planetary mechanism itself is placed in a glass 21 mounted in the housing 22 of the exciter 3 with possible rotation relative to the geometrical axis 23 of the central gears 16 and subsequent fixation by means of a rotary-locking mechanism 24. The carrier 17 is fixed on the drive shaft 25 of the vibration exciter 3, and the carrier 17a is supported on the shaft 26 of the cup 21, forming a rotational pair 27. The drive shaft 25 and the shaft 26 of the cup 21 forms rotational pairs 28 and 29 with the supporting parts 30 and 30a of the housing 22, respectively. The supporting parts 30 (30a) of the housing 22 are cylindrical, pass through the arc grooves 9 of the curved guides 8 of the box 1 and are fixed to them using the mounting unit 31 (Fig. 2 and 3).

To improve the accuracy of adjusting the direction of oscillation, the rotary-locking mechanism 24 of the cup 21 in the housing 22 of the vibration exciter 3 (Fig. 4) includes a lever 32, rigidly connected at one end to the shaft 26 of the cup 21, and the other end using a detachable connection 33 in the form of a circular row the holes 33a on the removable flange 30b at the end of the non-drive support portion 30a of the housing 22 and the spring-loaded rod 33b inserted into one of them located in the handle 34 of the lever 32. Modifications of the connection 33, for example, of a screw type (not shown) are possible.

The drive 4 includes an electric motor 4a and a cardan gear 46 (Figs. 2, 3 and 5). The electric motor 4a is mounted on a movable base 35 and kinematically coupled (using a cardan drive 46) to the drive shaft 25 of the vibration exciter 3. The movable base 35 is mounted with a fixed directional movement along a convex outer surface 36a (radius r <R) of a cylindrical guide 36 having paired supports 37. The fixation of such a movement is possible using bolted joints 38 and holes 39 and 40, respectively made in a movable base 35 and a cylindrical having a T-shaped cross section n directs 36.

To reduce the setup time, the vibrating screen can be equipped with an arc movement mechanism 41 of the vibration exciter 3 together with the drive 4 (Fig. 1, 2 and 3). This mechanism contains a rotary H-shaped frame 42 with a drive 43 for its rotation in the form of a double-acting hydraulic cylinder. The pivoting frame 42 has parallel lateral sides 44 and a jumper 45 perpendicular to it. Each of the sides 44 of the pivoting frame 42 is equipped in its upper part with a biased orientation (only in the plane of the frame 42, for example, due to a non-circular cross section) with the possibility of fixation (using screw 46 ) a fork 47 for interaction (with its own recess) with the supporting part 30 (30a) of the vibration exciter case 22 3. On the sides 47a, one of the forks 47 interacts with two cylindrical stops 35a (Figs. 5 and 6) screwed into the inner (limiting lateral displacement n) the lateral edge 35b of the movable base 35. From radial upward displacement of the movable base 35 is limited by two coaxially protruding protruding ends of the screws 35b screwed into the lateral edges 35b of the movable base 35 in its middle part. With their lower parts, the sides 44 of the rotary frame 42 are connected by cylindrical hinges 48 with supports 49. The geometric axes of the hinges 48 are aligned with the common geometric axis 50 (point O _p in FIG. 1) of the outer surface 36a of the cylindrical guide 36. Drive 43 by hinges 51 and 52 is connected to the cantilever element 53 on one of the sides 44 of the swing frame 42 (preferably on the drive side 4) and the support element 54 of the cylindrical guide 36, respectively.

To increase the reliability of the design, the mounting unit 31 (Fig. 5) for fixing the housing 22 of the exciter 3 in the arc groove 9 of each of the two curved guides 8 mounted on the box 1 is made in the form of two plates 55 with three through holes adjacent to the guides 8 on both sides of them - one central hole 55a to cover the corresponding support part 30 (30a) of the exciter housing 22 and two mounting holes 55b and two screws 56 passing through the holes 55b and the arc groove 9 screwed into the corresponding end 57 (57a) of the body whisker 22 of vibration exciter 3 and bearing nuts 58 (with locknuts 58a), retaining plates 55 and screws 56.

The supports 5 (5a), 37 and 49 are located on the screen frame 59 or directly on the building floor of the 60th place of its installation.

Installation and adjustment of mechanisms in working position

Before starting the operation of the vibrating screen with a box 1 and a sieve 2, the exciter 3 with the drive 4 by means of the arc movement mechanism 41 along the arc groove 9 and the cylindrical guide 36 is moved to the fixing position determined by the technological requirements, determined by the angle α (for example: α ₁ , α ₂ , α ₃ ...), which can vary within 0 ... α ₀ (Fig. 9, 10). After fixing the position of the vibration exciter 3 using the rotary-locking mechanism 24, the glass 21 is rotated through an angle β, which can be changed so that the driving force F can be directed in relation to the plane of the screening sieve either at an angle of 90 °, or in parallel, or at some design angle, for example: β ₁ , β ₂ , β ₃ , (Fig. 7, 8, 9, 10). The angle β can vary between 0 ° -360 °. The line of action of the exciting force corresponds to one of the positions L ₁ , L ₂ , L ₃ ..., (Fig. 7, 8, 9, 10). The position of the line of action of the exciting force is fixed by means of a detachable connection 33 of the holes 33a on the removable flange 30b of the housing 22 and the spring rod 33b inserted in the hole 33a, which is located in the handle 34 of the lever 32, (Fig. 4).

Two cases of adjustment are possible, depending on the necessity of passing the line of action of the exciting force through the center of mass O _{m of the} box 1 or outside it.

If it is necessary to ensure that the driving line F of the driving force F passes through the center of mass O _{m of the} box 1 (Fig. 9), the movable base 35 with the drive 4 moves along the cylindrical guide 36 (after disconnecting the base 35 from the guide 36, and the vibration exciter 3 from being fixed in curved guides 8), using the movement mechanism 41, at an angle α, measured from the extreme position, for example, the left one in the range α ₀ , and then turning the glass 21 at an angle β and fixing it using the rotary-locking mechanism 24.

If it is necessary to ensure the passage of the action line L of the driving force F outside the center of mass O _{m of the} box 1 (Fig. 9), using the moving mechanism 41, the vibration exciter 3 with the drive 4 freed from fixation is moved along the guide 36 to the required angle α and after the vibration exciter 3 and the drive are fixed 4 rotate with fixation of the beaker 21 with the help of the mechanism 24 by an angle β, which allows changing the passage of the action line A of the driving force F without crossing the center of mass O _{m of the} box 1 (including the parallel screening of goodness 2).

The operation of the vibrating screen is as follows.

The source material, such as crushed stone, enters the box 1 on the sieve 2. When the drive 4 is turned on, the vibration exciter 3 creates directional vibrations of the box 1 with the sieve 2, which toss the material over the sieve 2, transport it along the box and sort it on the sieve. The vibrational inertial forces of the directed oscillations are perceived by the bearings 5 of the screen and are suppressed by means of the elastic elements 6.

In a fixed position of the vibration exciter 3 mounted on the side walls 7, curved guides 8 and in a curved groove 9, relative to the vertical axis 10, when the actuator 4 is turned on under the action of an unbalanced mass of unbalance 11 of the vibration exciter 3 (Fig. 7), the center of mass C of which is directed oscillation along the line of action L ₁ (with the ratio D: d = 2 for the gear-planetary mechanism of the hypocycloid degenerates into a straight line segment C ₁ C ₂ ), a driving force arises, exciting the vibration of the box 1 with a given frequency and amplitude . The material in the box 1 on the screen 2 under the action of vibration, is divided into sub-sieve and over-sieve products, reaching the edge, poured into the corresponding funnels for subsequent transportation to the collection tanks (not shown in the drawing).

The imbalance 11 (Fig. 4) rigidly mounted on a common shaft 12, satellites 13, which with their pitch circle 14 (Figs. 7, 8) roll around the pitch circle 15 of the central gears 16, generates directional vibrations along the diameter of the central gears 16 along the line L ₁ , depending on the initial installation site of the engagement point C ₁ (C '), which, taking into account the properties of the starting material, increases the screening efficiency. The drive of rotation of the axis of the satellites 12 with an unbalance 11 is carried out by carriers 17 with counterweights 18. In order to prevent the gears 13 and 16 of the planetary gear transmission from being subjected to the load of the driving force of the unbalance 11, the vibration exciter is equipped with treadmills 19 along which the support wheels 20 are rolled and perceived the driving force of the unbalance 11. The gear-planetary mechanism of the vibration exciter, consisting of the unbalance 11, the shaft 12, the satellites 13, the central gears 16, drove 17 with a counterweight 18, the racetracks 19 and the support wheels 10 the cup 21, which is enclosed in the housing 22 of the vibration exciter 3. On the one hand (in Fig. 4, to the right) the cup, at the level of the geometric axis 23, a rotary-locking mechanism 24 of the cup is attached, and on the other hand, a drive shaft 25 connected to the carrier 17. When the drive shaft 15 is rotated from the drive 4, the satellites 13 and the support wheels 20 are run along the central wheels 16 and the treadmills 19, respectively. In this case, the center of mass of the unbalance 11 makes a movement along the diameter of the central gears.

Thus, the utility model allows you to change the direction of the line of action of the driving force of the vibration exciter through the installation and adjustment of mechanisms. The direction of the driving force with respect to the screening surface of the sieve can be set during adjustment: perpendicular, parallel or inclined. In relation to the center of gravity of the screen, the direction of the driving force allows you to implement both a mode that increases the speed of transportation and limits the speed of transportation of the sorted material, which ultimately aims to increase the efficiency of screening and expand operational, technological and functional capabilities.

Claims (4)

1. A vibration screen comprising a box mounted on supports through elastic elements with one screening surface and a directional vibration exciter, the drive shaft of which is kinematically connected to the drive, the vibration exciter is mounted on the box with the possibility of fixed movement along an arc of a circle, and the drive is placed on a movable base with the possibility of fixed movement along a cylindrical guide, characterized in that the vibration exciter is made in the form of a paired symmetrical gear-planetary mechanism with unbalance, which is placed in a glass mounted in the exciter case with the possibility of rotation relative to the geometric axis of the central gears and subsequent fixation using a rotary-locking mechanism, the side walls of the box in their upper part are equipped with two curved guides in the form of plates with an arc groove , each supporting part of the exciter housing passes through the arc grooves of curved guides and is fixed on them with the help of a mounting unit, the guide is movably a base actuator motor is a convex cylindrical surface is formed by copying the profile of the arc of the groove in the side wall of the box, and a kinematic connection a drive motor with a drive shaft exciter is designed as a cardan transmission, wherein the eccentric weight is fixed on a common shaft satellites. 2. Vibrating screen according to claim 1, characterized in that the mounting unit of the vibration exciter is made in the form of two plates adjacent to them from two sides with three through holes. 3. Vibrating screen according to claim 1, characterized in that the rotary-locking mechanism of the glass in the exciter housing includes a lever rigidly connected at one end to the shaft of the glass and at the other end to one of the holes of a circular row made on a removable flange at the end of the non-drive the supporting part of the exciter housing. 4. Vibrating screen according to claim 1, characterized in that it is equipped with a mechanism for the arc movement of the vibration exciter together with the drive.

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