SU917865A1 - Vibration-centrifugal sorting apparatus - Google Patents

Description

(Sk) VIBRATION CENTRIFUGAL SORTING

Claims (2)

I The invention relates to the field of sorting of solid materials, mainly to sorting seeds of agricultural crops, and can be used in the mill industry of the large mining industry. A separator is known, comprising a rotating cylindrical sieve and a drive mechanism consisting of driving, driven and tensioning sprockets connected by an endless chain, moreover, in order to increase the separator's performance by increasing the relative speed of the sorted material on the inner surface of the sieve, the driving and driven sprockets are made with eccentricity, and the asterisk is tensioned. Such an actuator allows the cylindrical screen to be rotated at a variable angular velocity and the magnitude of pressing the material to be sorted to the internal surface of the screen. the action of the variable centrifugal force arising from this rotation is also not constant. This makes it possible to increase the relative speed of movement of the mixture along the inner surface of the sieve, reducing to some extent the main disadvantage of conventional cylindrical |) solutions that rotate at a constant angular velocity, at which the increase in peripheral speed to a cylinder above the critical one leads to the formation of dense layers of the mixture on the surface, i.e. the mixture sticks, as it were, pressed by centrifugal force 1. 15 However, in the well-known separator, with a significant increase in the number of revolutions of the sieve, in order to increase its productivity, there comes a moment when the drops in one The 20th turn between higher and lower values of the angular velocity occurs so quickly, and consequently, the magnitude of the centrifugal force also changes so fast that the mixture is pressed against the grain s because of its inertness does not have time to begin relative movement along the sieve inner surface. That is, even in such a separator, its critical value of the peripheral sieve velocity takes place, but compared to conventional cylindrical sieves, it is higher and, consequently, somewhat more efficient is the performance of such separators. The closest solution to the technical essence is vibration-centrifugal sorting, containing a rotating sieve mounted on an axis, made in the form of a cylinder with rims, knitting needles and hubs, performing spatial oscillations with a pasHoli amplitude along its length, an unbalance vibrator made for adjusting the amplitude and the directions of oscillations in the form of an outer ring rigidly connected with the axis of the sieve, and an inner movable spherical ring in which the shaft of the vibrator disk is mounted. The unbalance vibrator is mounted on an axis with an offset from the center of gravity of the oscillating -parts of the sorting, which makes it possible to obtain different amplitudes of spatial oscillations along the length of the sieve. The rotation of the sieve and the drive of the vibrator are carried out by two electric motors 2. However, despite the fact that the rotational cylindrical sieve of spatial oscillations can intensify the separation process and, consequently, significantly improve the performance of such sorts, design complexity and high power consumption drive unit. This is due to the complexity in the manufacture of the vibrator to obtain the necessary amplitudes and directions of spatial oscillations, its inadequate operational reliability, as well as the fact that the rotational drive of the cylindrical sieve and the rotational motion of the unbalance disk of the vibrator come from causes significant power costs. The aim of the invention is to reduce energy consumption. The goal is achieved by sorting in a vibration-centrifugal 9 54 containing a cylindrical sieve mounted on a shaft, connected to the shaft with rims, knitting needles and hubs, a drive and pillars in which the ends of the shaft are placed with the help of Lena on the shaft eccentric, and The rims are made in the form of internal and external spherical rings interconnected by means of locking bolts. The inner ring is connected with knittings with hubs, and the outer one with a sieve. In addition, the hubs are axially mounted on a shaft for adjusting eccentricities. Figure 1 shows the structural scheme of vibration-centrifugal sorting (a sieve with rims, knitting needles and hubs for the sake of conspicuously rotated); in fig. 2 - view A of FIG. 1 (the outer ring of the rims is conditionally cut). The sorting contains eccentrically mounted on the shaft 1 of the hub 2 and 3, rigidly connected through the spokes 4 to the inner spherical rings 5 and 6, on which the outer flat rings 7 and 8 are attached to the cylindrical sieve 9 fixed to them and fitted with locking bolts 10 with nuts 11 The hubs 2 and 3 consist of two halves, rigidly fastened to the plates 12 and 13 with welded nuts I and 15, into which the gland bolts 16 and 17 are screwed. Thus formed the hubs 2 and 3 have grooves through which the shaft 1 passes, having these grooves rigidly mounted on and it has slides 18. The cylindrical screen is closed by a casing 19 having outlet pipes 20 for collecting the passage fraction and pipes 21 for collecting the tail fraction. The rotation of the sieve is driven from the electric motor 22 by means of a flexible roller 23 through a tensioning device 2k and a V-belt transmission 25. The ends of the shaft 1 are supported on sleeves 26 and 27 supported by elastic elements 28 housed in racks 29 and 30 that are fastened to the plate 31 A hopper 32 is attached to the support post 29 with adjustable h, aslon 33. The device operates as follows. The grain mixture to be operated from the hopper 32 through the flap 33 moves into a rotating and at the same time oscillating cylindrical sieve 9. Moreover, the oscillatory movement of the sieve 9 is ensured by the fact that the hubs 2 and 3 are mounted on the shaft 1 eccentric. Consequently, the left and right ends of the sieve are displaced in relation to it. The sieve 9 is also set eccentrically with respect to its shaft of rotation 1, with a variable eccentricity along its length. As a result, the center of gravity of the sieve is shifted relative to the shaft 1 by a certain amount. Sieve 9 becomes like an imbalance, leaves the equilibrium position and undergoes spatial oscillations. The magnitudes of the eccentricities of the hubs 2 and 3, and hence the values of eccentric screens of the left and right parts of the sieves 9, are adjusted as follows. You- twisting the locking bolts 10 from the nuts 11 (FIG. 2) ensure the turning of the outer rings 7 and 8 (on which the sieve 9 is fastened) on the internal spherical rings 5 and 6. Then unscrewing, for example, the bolt 16 from the nut W, is screwed the bolt 1 into the nut 15. Consequently, the slider 18, rigidly mounted on the shaft 1, is pressed by the bolt 17 and begins to move, along the slot of the hub 2 (Fig. 2), to the side of the screw 16, but since the ends of the shaft 1 are supported through the sleeves 26 and 27 on the elastic elements 28, the reverse occurs, that is, not the slider 18 together with the shaft 1, but the hub 2 itself begins movable with respect to them. But the connection between the hub 2, the spokes and the usual rim is rigid, and the sieve 9 is constant. Obviously, as soon as the rims would begin to move in one direction or the other with respect to shaft 1, a cylindrical sieve would deform, causing it to either break from the rims or damage. This eliminates the proposed design of the rims and, as a result, the sieve 9 is hinged on the inner spherical rings 5 and 6, which can move in one direction or the other with respect to the shaft 1, and the outer rings 7 and 8 in turn can be set obliquely to one or the other. INUI side with respect to the inner rings. So in FIG. 1 and shows the case where the right inner. 656 spherical ring 5 is displaced upward, as if lifted towards shaft 1, and the left one is displaced downward, as it were, omitted. That is, these rings 5 and 6 are displaced in different directions with respect to shaft 1. They are also found in planes perpendicular to shaft 1. spherical rings 5 and 6. The points of contact of the outer rings with the inner ones will lie in a plane perpendicular to the direction of displacement of the hubs. For example, if the hubs 2 and 3 with respect to the shaft 1 move vertically (as shown in Fig. 1), then the contact points of the rim rings will lie in a horizontal plane, and it is in these points, in order to transmit rotation from the inner rings 5 and 6 to the sieve 9, and the locking locking bolts 10 must be installed. The transfer of rotation from the shaft 1 to the inner rings 5 and 6 of the rims is ensured by the fact that the hub is fixed movably on the shaft 1 in such a way that it only moves along the slide 18, but does not rotate, but rotates with it. Thus, fastening the hubs eccentrically on the shaft, making the rims in the form of internal spherical rings rigidly connected through the spokes to the hubs, and the outer rings on which the sieve is fixed, allows the sieve itself to be installed eccentrically with respect to its shaft of rotation, and that its left and right parts can be installed either with the same eccentricity, or with different ones. Moreover, they can be shifted either in one direction (in this case, the sieve performs circular oscillations with the same or with different amplitudes of oscillations of the right and left end parts depending on the values of the eccentricities of the left and right hubs), or in different directions (in this case the sieve makes spatial oscillations with the same or with different amplitudes of oscillations of the right and left end parts depending on the values of eccentricities of the left and right hubs). It is necessary to install a smaller eccentricity at the hub, closest to the place of loading, 19 loads, and the larger one - at the hub at the places where the mixture vanishes. Then the vertical component | {) (the oscillation amplitude will increase along the sieve length from the place of loading the mixture to the place of unloading, which intensifies the process of weed seeds passing through the grain layer and the sieve. As if unbalanced by the load, i.e. unbalance, and by changing its position on the shaft, spatial oscillations are achieved. This simplifies the design, reduces power consumption, since it eliminates one drive designed for message to the lattice of spatial oscillations. Invention formula 1. Vibration-centrifugal sorting, containing a cylindrical sieve mounted on a shaft, connected to the shaft with the help of rims, 6 17 319 7 § 5 knitting needles and hubs, drive, racks in which the ends of the shaft are placed using elastic elements, characterized in that, in order to reduce energy costs, the hubs are mounted eccentrically on the shaft, and the rims are made in the form of interconnected inner and outer spherical rings, while the inner ring is connected to the hubs, and outer her with a sieve. 2. Sorting according to claim 1, characterized in that in order to adjust the hub eccentricities, the latter are mounted on the shaft with the possibility of axial movement. 3. Sorting according to Claim 1, characterized in that the rings of the rim are interconnected by means of locking bolts. Sources of information taken into account in the examination of 1, USSR Copyright Certificate № 501773, cl. B 07 B 1/22, 1976. 2. USSR author's certificate No. 309750, cl. B 07 B 1/26, 1970 (prototype). 17 years 18 th 32. 33 p / eleven eleven 18 8t / ffA S