SU842200A1 - Rock loading machine working member - Google Patents

Description

(54) WORKING ORGAN OF THE BREEDING-LOADING MACHINE

one

The invention relates to the mountainousness and is intended for loading the rock mass of a low fortress, as well as for loading the compacted rock mass from the pile to the transport.

The known rock-loading machine has a working body in the form of a pipe with a cross section with a bucket-shaped front part that moves forward and backward. Clll The disadvantage of this working body is that its introduction into the mountain massif is accompanied by large power consumption, since with increasing depth of penetration of the cutting edge in the rock mass, the density of the rock along the cutting edge insertion line increases accordingly. And with an increase in the density of the rock, the resistance to digging increases, which ultimately leads to unproductive energy consumption and a decrease in operating efficiency.

Known working body rock loading machine, including mounted on the frame eccentric.

AND

a mechanism including an eccentric shaft, a connecting rod, a slider and suspensions and a cutting edge with an inclined surface and a horizontal base Gz associated with the eccentric mechanism.

The disadvantage of such a working body is that, due to the coincidence of the directions of introduction of the cutting edge and the eccentric beat, there is an intense compaction of the rock along the insertion line, which entails a corresponding increase in the proportion of energy leaving to overcome the resistance to digging, which ultimately also reduces work efficiency. In addition, the eccentric mechanism consists of a series of interrelated

0 between each node, which complicates its design and reduces reliability.

The purpose of the invention is improving the efficiency of work.

five

This goal is achieved by the fact that the working body is provided with two additional eccentrics and a roller supported on the top of the frame, which is mounted on the longitudinal axis 0 of the frame and fixed to the inclined

surface of the cutting edge, the horizontal base of which is made with an open longitudinal slit and is supported on the central open in the longitudinal opening and on the flanks of the frame are flanking eccentrics that are fixed to the frame horizontally by means of the axes of rotation, and the flanking eccentrics are mounted on the axis of rotation in this way that the most distant parts of them are directed in opposite directions, and the central eccentric is mounted on the rotation arbitrarily and mounted on the longitudinal axis of the frame.

Figure 1 shows the described working body, side view / figure 2 slit LL in figure 1.

The working body contains flanking 1 and 2 central eccentrics and roller 3 supported on the upper part of the frame 4 and fixed to the bottom of the inclined surface of the cutting edge 6 by means of axis 5. The roller 3 is mounted on the longitudinal frame 4. The horizontal base of the cutting edge 6 is made “with the longitudinal open slot 7 and operated on the flank 1 and central 2 eccentrics. All eccentrics 1 and 2 are fixed horizontally to frame 4 by means of their axes of rotation 8, on which they are fitted rigidly. Moreover, the flagi eccentrics 1 are mounted on the axis —.a1PoN 8 in such a way that the most distant parts of them are directed in opposite directions (see FIG. 2), and the central eccentric 2 is mounted on the axis of rotation 8 arbitrarily and mounted on the longitudinal axis of the frame 4 .. Eccentrics 1 and 2 are provided with a STATE-CYM drive from the engine 9 and the chain transmission 10. On the frame 4 there is a belt conveyor 11 for moving the rock mass.

The working body works as follows.

The frame 4 is forcefully applied to the bulk in bulk. When the cutting edge b is inserted into it, the engine 9 is turned on, which, through the chain transmission 10 BpaiiaeT, eccentrics 1 and 2. Since the cutting edge b is in front of the pile and the rear edge is in eccentrics 1 and 2, the rotation of the latter causes the cutting edge 6 complex movement. The rotation of the flank eccentrics 1 causes the cutting edge to perform a frequency-adhering motion relative to the roller. This movement is due to the fact that the flanking eccentrics 1 are mounted on the axis of rotation 8 in such a way that the most distant parts of them are directed in opposite directions (see fig. 2). Therefore, the flank eccentrics 1 beat the horizontal base of the cutting edge b alternately, causing it to make a tandem like

oscillatory motion relative to the roller 3. The rotation of the central eccentric 2 causes the cutting edge 6 together with the roller 3 to perform a frequency-alternating movement in the transverse direction perpendicular to the longitudinal axis of pc1m 4. The last transverse movement of the cutting edge 6 is due to the fact that the central eccentric 2 rotates beats with its most distant part alternately along the longitudinal sides of the open slot 7. The frequency-mounted motion of the cutting edge b relative to the roller 3 allows it to be actively introduced channel, and the frequency alternating movement in the transverse direction until it allows intense be loosened rock along line embedding. The latter prevents compaction of the rock before the cutting edge b and thereby increases the rate of its introduction into the pile, and consequently, increases the efficiency of the rock-loading machine.

The fact that the inclined surface of the cutting edge b from the bottom is provided with a roller 3 supported on the frame 4 contributes to an increase in the efficiency of the rock loading machine, thereby preventing friction between the inclined surface of the cutting edge b and the upper part of the frame 4.

The horn mass from the pile, moving along the inclined surface of the cutting edge b, falls on the conveyor belt 11, and from there to the means of transport.

Claims (2)

1. Patent CfJA 3032325, cl. 299-67, publ. 1962. 2. Vibrocomplice for universal loaders. - Industrial transport, 1975, No. 3, p. 24