RU2654892C1 - Roller of vibrating roller - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to road-building machinery and is intended for compaction of building materials. Roller of the vibrating roller contains a shaft connected to the roller and fastened with rubber shock absorbers to the frame of the vibrating roller. Two pairs of unbalanced shafts are rotatably mounted on the shaft, the axes of which are perpendicular to the axis of the roller in such a way that the axes of the first pair of the unbalanced shafts are located in the vertical plane, and the axes of the second pair are symmetrical to the line passing in the middle between the axes of the first pair of the unbalanced shafts, the ends of which are equipped with identical large gears engaged in one another, the ends of the unbalanced shafts of the second pair are equipped with small gears twice as small as in the first pair, one of the gears of the second pair engages the gear of the lower unbalanced shaft of the first pair above its axis, and the other engages with the gear of the upper unbalanced shaft below its axis, with the same horizontal orientation of the imbalances of the first pair of the shafts, the imbalances of the second pair of the shafts are directed vertically in one direction. In addition, annular projections are provided on the outer surface of the roller shell.

EFFECT: invention is aimed at reducing energy costs for compacting the material, increasing productivity and reducing the weight of the rollers.

1 cl, 4 dwg

Description

The invention relates to road-building equipment and is intended for compaction of materials from which soil and concrete structures are erected, such as dams, roads, airfields, backfill pits, embankments, etc.

A known vibratory roller containing a pneumatic wheel tractor with which the frame is pivotally attached to it, by means of rubber shock absorbers, a vibratory roller made in the form of a cylindrical steel shell inside of which there are unbalances (eccentrics), the rotation axis of which, as a rule, coincides with the geometric axis of the vibratory roller, the vibration of which caused by the rotation of the unbalances is transferred to the material being compacted, in which particles are re-arranged leading to an increase in its density (L. Forssblad. Vibration compaction of soils and bases. - Moscow, Transport, 1987, S. 55-61).

This type of vibratory roller is most rational for compaction of thick up to 2 m coarse-grained materials, where intense vibration is required, which determines its disadvantages: crushing of material particles, deconsolidation of the surface layer, vibration propagation by tens of meters, which negatively affects nearby structures, low efficiency, which is defined as the energy cost of compaction of a unit mass to a given degree of compaction.

The oscillator type of a vibratory roller is known, which contains a pneumatic wheel tractor with which the frame is articulated with a rubber shock absorber mounted to it, made in the form of a cylindrical steel shell, inside of which there are two unbalanced shafts that are symmetrical relative to the axis of the vibratory roll and rotate in one direction with one shaft moving off-balance 180 ° relative to the unbalances of the second shaft, in the roller the vibrocrank performs torsional vibrations around the geometric axis, resulting in the contact of the surface of the vibrating roll with the material being compacted results in horizontally directed tangential stresses that more effectively contribute to its compaction (MP Kostelov. A new method of compaction of road-building materials. - Roads. 1991, No. 6, P. 13-15).

The disadvantage of the oscillating vibratory roller is its lower compaction ability compared to the vibratory roller, since the intensity of the impact on the material being compacted is limited by preventing slipping of the drum surface along the material being compacted and the rapid attenuation of dynamic tangential stresses in depth, as a result of which oscillating vibratory rollers are mainly used for laying road surfaces up to 20 cm thick.

A known roller of a vibratory roller containing a shell with a set of elastic tires filled with water, equipped with two opposed unbalanced shafts rotating in one direction, with 180 ° offset eccentric masses and a central unbalanced shaft 90 ° offset with respect to the first two eccentric masses (Patent of the PM of the Russian Federation No. 121260, IPC: Е01С 19/28, publ. 20.10.2012). In this design, circular and torsional vibration pathogens are located in one drum. Moreover, circular vibrations are generated by the central unbalanced shaft, the axis of which coincides with the axis of the roller driven by a hydraulic motor, and torsional vibrations are excited by two unbalanced shafts mounted on the edges of the roller symmetrically to its axis. At the ends of these shafts the same gears are fixed, which mesh with the same gear fixed on the central shaft.

According to the number of similar features and the achieved result, this technical solution is selected as a prototype of the claimed technical solution.

The disadvantages of the prototype include the fact that the circular vibrations of the drum and its torsional vibrations act on the material being compacted alternately, in addition, when the circular excitation force is close to the horizon, the tangential forces weakening on the contact of the roller with the material being compacted, the degree of which depends on the direction of rotation of the roller and speed of its movement. In addition, equipping the drum with elastic rubber tires leads to vibration damping, i.e. to a decrease in sealing ability. An analysis of the behavior of the rheological model of the material, the properties of which are determined mainly by the coefficient of internal friction, shows that the maximum decrease in internal friction under the action of vibration, due to which the particles of the material being compacted and the formation of a denser structure is re-formed, occurs when the shear and normal stresses are subjected to joint dynamic compression and static components of which are interconnected in certain proportions (V.E. Kondakov. On vibration ionic liquefaction of concrete plane stress condition -. Proceedings of the universities, Construction and Architecture, 1984, pp 55-60).

The technical result, the achievement of which the invention is directed, consists in increasing the efficiency i.e. reducing energy costs for compaction of the material, in increasing productivity and reducing the weight of vibratory rollers.

To achieve the technical result, a vibratory roller roller comprising a shaft rotatably connected to the roller and fastened with rubber shock absorbers to the roller frame, two pairs of unbalanced shafts are fixed on the roller shaft, the axes of which are perpendicular to the roller axis so that the axes the first pair of unbalanced shafts are located in a vertical plane, and the axes of the second pair are symmetrical with the lines passing in the middle between the axes of the first pair of unbalanced shafts, the ends of which are equipped with one with large gears meshing with each other, the ends of the unbalanced shafts of the second pair are equipped with small gears half the diameter than the first pair, one of the gears of the second pair meshes with the gear of the lower unbalanced shaft of the first pair above its axis and the other engages with the gear of the upper unbalanced shaft below its axis, with the same horizontal orientation of the unbalances of the first pair of shafts, the unbalances of the second pair of shafts are directed vertically in one direction.

In addition, the claimed technical solution has an optional feature characterizing its particular case, namely:

- additionally, annular protrusions are made on the outer surface of the drum shell.

Distinctive features of the proposed design of the roller from the above known, closest to it, are equipping the roller of the vibratory roller with two pairs of unbalanced shafts whose axes are perpendicular to the axis of the roller so that the axes of the first pair of unbalanced shafts are located in a vertical plane and the axes of the second pair are symmetrical with the lines in the middle between the axes of the first pair of unbalanced shafts; equipping the ends of the first pair of unbalanced shafts with the same large gears engaged with each other; equipping the ends of the unbalanced shafts of the second pair with small gears half the diameter than in the first pair; the engagement of one of the gears of the second pair with the gear of the lower unbalanced shaft of the first pair above its axis; engagement of the second wheel of the second pair with the gear of the upper unbalanced shaft below its axis, with the same horizontal orientation of the unbalances of the first pair of shafts; the direction of the unbalance of the second pair of shafts vertically in one direction.

Due to the presence of these signs, the roller of the vibratory roller makes simultaneous vibrations in the horizontal direction along the axis of the roller and vertical directional vibrations that more effectively contribute to compaction. The presence of annular protrusions on the outer surface of the shell of the drum increases its adhesion to the material being compacted, which makes it possible to increase the intensity of the impact, and hence the productivity of the vibratory roller.

The proposed roller of the vibratory roller is illustrated by the drawings shown in FIG. 1-4.

In FIG. 1 shows a vertical section of a roller of a vibratory roller with a plane parallel to its axis.

In FIG. 2 is a section of a roller of a vibratory roller with a vertical plane perpendicular to its axis and passing through its center.

In FIG. 3 - surface relief of the shell of the roller of the vibratory roller with annular protrusions.

In FIG. 4 - the position of the unbalances in different phases of rotation:

а - horizontal force is directed to the left, vertical - up;

b - horizontal force is directed to the right, vertical up.

The vibratory roller roller contains a first pair of unbalanced shafts 1, a second pair of unbalanced shafts 2, a central shaft 3, bearings 4, one of which is radial and the other persistent, a cover 5 (in the amount of two), a shell 6, rubber shock absorbers 7, a frame of the vibratory roller 8, large gears 9, small gears 10, annular projections 11.

The proposed design works as follows.

When the unbalanced shafts of the first pair 1 and the second pair 2 rotate by means of a hydraulic or electric drive (not shown in the figures), there are directed horizontal, along the roll axis, vertical vibrations. The doubled frequency of vertical vibrations provides their simultaneous effect with horizontal vibrations when changing the direction of the latter. The directed horizontal and vertical driving forces are applied to the central shaft 3 and, through bearings 4 (persistent and radial), are transmitted through the covers 5 of the roller to the shell 6.

To eliminate the overturning moment arising from the interaction of the horizontal force and the resistance of the material being compacted in contact with the roller, the axis of symmetry of the first pair of unbalanced shafts 1 should be located below the center of gravity of the roller, in this case there is a moment from a couple of forces: horizontal driving force - inertial resistance directed against overturning moment. The plane in which the axes of the unbalanced shafts 2 are located should have the smallest possible deviation from the horizon, for which the distance between the non-engaging gears large 9 and small 10 should be taken as minimal as possible based on the design features.

If the proposed roller vibratory roller is not designed to obtain a smooth surface of the compacted material, for example, pavement, then the outer surface of the shell 6 may have a relief surface formed by annular protrusions 11, which increases the efficiency of the roller.

Claims (2)

1. The roller of the vibratory roller, comprising a shaft 3, rotatably connected to the roller and fastened with rubber shock absorbers 7 to the frame 8 of the vibratory roller, characterized in that two pairs of unbalanced shafts 1 and 2 are fixed on the shaft 3 of the roller for rotation which are perpendicular to the axis of the roller in such a way that the axes of the first pair of unbalanced shafts 1 are located in a vertical plane, and the axes of the second pair 2 are symmetric to the line running in the middle between the axes of the first pair of unbalanced shafts 1, the ends of which are equipped with one With the large gears 9 engaged with each other, the ends of the unbalanced shafts 2 of the second pair are equipped with small gears 10 half the diameter than in the first pair 1, one of the gears 10 of the second pair 2 is engaged with the lower gear 9 the unbalanced shaft 1 of the first pair is above its axis, and the other engages with the gear 9 of the upper unbalanced shaft 1 below its axis, with the same horizontal orientation of the unbalances of the first pair of shafts 1, the unbalances of the second pair of shafts 2 are directed vertically in the bottom side. 2. The roller of the vibratory roller according to claim 1, characterized in that in addition to the outer surface of the shell 6 of the roller ring protrusions are made.

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