RU2278209C1 - Ground slope consolidation device - Google Patents

Abstract

FIELD: building and road-building engineering, particularly ground compressing equipment.

SUBSTANCE: device comprises basic machine made as jib type crane and having frame to which arm is hinged. Device also has ground compressing working tool installed on free end of the arm and including roller, which perform free rotation, steel sleeve freely put on the roller so that the sleeve encloses the roller, vibro-cart freely bearing on steel sleeve by rolls, driving mechanism made as two-shaft inertia body installed on the vibro-cart.

EFFECT: simplified structure, increased operational reliability and reduced material consumption.

5 dwg

Description

The invention relates to construction and road engineering, in particular to soil compaction machines, and can be used in the construction of dams, embankments and other earthworks.

The stability of bulk earthworks is largely determined by the timely consolidation of soil slopes from the damaging effects of natural factors - precipitation, wind and temperature changes.

Since almost all bulk structures are covered, as a rule, with layers of compaction of each layer to the design density, then, apparently, it should be considered as a rule - the slope of each soil layer must be compacted immediately after compaction of the last or simultaneously. With such an organization of soil compaction works, the influence of natural factors on the stability of a layer-by-layer dumped and layer-by-layer compacted earthwork is reduced to zero.

However, in the vast majority of cases, compaction of soil slopes is organized and carried out after filling the entire structure (for example, a road embankment), which is also facilitated by the construction of the well-known soil compaction technique with which this work can be performed.

Known vibration roller for sealing slopes (AS No. 746018, MKI 2 E 01 C 19/28), containing the base chassis, on which a winch is installed with a rope passed through the blocks and connected to the drum frame, a power source located on the chassis and connected to the drum with a cable, an additional rope to which the cable is suspended using an adjustment device made in the form of a lever.

A device for compaction of soil slopes is also known (AS No. 721495, MKI 2 E 01 C 19/28), comprising a base machine, a rotary platform, a telescopic boom with a transverse balancer mounted on the platform, a vibratory roller mounted at the end of the telescopic pipe, supporting element, made in the form of a plate with a mechanism for regulating its inclination, installed in front of the vibratory roller and connected to its axis using a bracket.

In addition, special machines are known for sealing slopes of embankments, for example the self-propelled Telepactor machine of the French company Albaret, moving along the edge of the embankment and compacting the soil with two rollers, which are alternately lowered and then pulled to the base machine using two steel ropes wound around on the drums of winches ("Reference manual on mechanized soil compaction, M., 1965, p. 84, Fig. 28), where soil compaction is carried out by two rollers.

All of these devices have the following disadvantages. Firstly, in these devices, the head working element (vibratory roller) is articulated with the base machine so that it rolls along the slope from top to bottom and, conversely, along its entire length after the building is dumped, as a result of which the risk of erosion or weathering of the slope in dumping process. Secondly, in all these devices there is a very high energy intensity of the rolling process (including vibro-rolling), since the mass of the rollers is not fully realized. With a slope slope of 1: 1.5, the road embankment is used at only 80%.

Closest to the proposed solution is a device for compaction of soil slopes (AS No. 1749332, MKI 5 E 01 C 19/34). The device contains a self-propelled base machine, a support frame made of two sections: the base, rigidly mounted on the machine, and the working, connected to the base, respectively, in the lower part - by a hinge, in the upper - by means of a spring damper, a working body, a drive mechanism of the working body. The working body is made in the form of a tamper plate, one face of which is pivotally mounted on the drive mechanism located in the lower part of the working section of the support frame, and the drive mechanism is made in the form of a gear motor connected to an overrunning mechanism, including a pair of ratchet wheels, two lifting drums, fixed on the drive shaft and connected with leashes with cables of two tension drums, mounted on the same drive shaft.

The known device allows the compaction of soil slopes in layers, i.e. the slope part of each soil layer to be filled is compacted immediately after compaction of its middle part with the help of a tamper plate.

The device operates as follows. After installing the device on the axis of penetration, it begins to move, the drive mechanism is turned on. The ramming plate is rotated in a vertical plane and is set to its initial position for impact, then the ramming plate, under the influence of its own weight, is rotated in the opposite direction until it hits the embankment slope surface, after which the ratchet wheels are engaged to raise the rammer for the next impact.

A significant disadvantage of the known device is that it is complex, cumbersome and expensive to manufacture, and therefore unreliable in operation.

The objective of the proposed device is to simplify its design, increase reliability in operation and reduce metal consumption.

The problem is solved as follows.

In the known device for compaction of soil slopes containing a self-propelled base machine, a soil sealing working body and a drive mechanism for a working body, an additional handle is mounted pivotally articulated with the frame of a self-propelled base machine, the working soil sealing body is fixed to the free end of the handle and is made in the form of a spatial frame, inside which mounted a freely rotating roller, a steel tire freely covering the roller, the diameter of which is greater than the diameter of the roller, a vibrating cart, articulated Enclosed with a spatial frame and freely supported by rollers on a steel tire, and the drive mechanism is made in the form of a two-shaft inertoid mounted on a vibrating cart and consisting of a housing, two circular racetracks located inside the housing, two drive shafts with slots mounted eccentrically to the racetracks, two unbalanced masses installed in the slots with the possibility of free movement, while a jib crane is used as a self-propelled base machine.

Distinctive features of the proposed device for compaction of soil slopes from the above known, closest to it are: use of a jib crane as a base machine, additional installation of a handle pivotally articulated with a base machine, implementation of a soil sealing working body in the form of a spatial frame, inside of which a freely rotating a roller, a steel tire freely covering the roller, the diameter of which is larger than the diameter of the roller, a vibrating cart articulated with with a spatial frame and freely supported by rollers on a steel tire, installing a soil-sealing working body at the free end of the handle and performing a drive mechanism in the form of a two-shaft inertoid mounted on a vibrating cart and consisting of a housing, two circular treadmills located inside the housing, two drive shafts with slots, installed eccentrically to the treadmills, two unbalanced masses installed in the slots with the possibility of free movement.

Due to the presence of these distinctive features, the compaction of the surface of the soil slope occurs due to the mass of a freely moving working body and due to the often shock load, which is transmitted to the ground by means of an inertoid through a steel tire. The simultaneous impact on the soil of a constant static load from the entire mass of the device and the often shock load from the inertoid allows you to get the most effective effect on the compacted soil mass. This combination of load is almost equivalent for any soil conditions, which allows us to consider the device universal and optimally efficient in operation and inexpensive.

By transferring the often shock load from the inertoid to the ground through the steel bar, bypassing the heavy roller, energy losses due to overcoming the inertia of the roller are eliminated, which helps to reduce the energy consumption of the process.

The proposed device for compaction of soil slopes is illustrated by the drawings shown in figures 1-5.

Figure 1 shows a schematic diagram of a device for compaction of soil slopes, side view, figure 2 view of "A" in figure 1, figure 3 view of "B" in figure 2, figure 4 schematic diagram inertoid, figure 5 is a plot of the disturbing forces of a two-shaft inertoid.

A device for compacting soil slopes (Fig. 1) contains a self-propelled base machine 1 in the form of a jib crane, a handle 2 pivotally mounted on the frame of the base machine, a soil-sealing working body 3 mounted on the free end of the handle 2, and a drive mechanism for the working body 4 (Fig. .2).

The soil-sealing working body (Fig. 2, 3) consists of a spatial frame 5, articulated with a handle 2, a roller 6, the axis 7 of which is installed in the spatial frame 5, a steel tire 8 with stiffeners 9, covering the roller 6, vibrocart 10, which one the end is articulated with the spatial frame 5, and the rollers 11 freely rests on a steel bus 8.

The drive mechanism 4 (figure 2, 4) is mounted on a vibrating cart 10 and is made in the form of an inertoid. The inercoid includes a housing 12, two treadmills 13 installed inside the housing, two drive shafts 14 with slots 15, unbalanced masses 16 mounted in slots 15 with free movement, an electric motor 17 (figure 2), an output shaft 18 of an electric motor 17 and a gear gear 19, articulating the output shaft 18 with the drive shafts 13.

The device operates as follows.

After backfilling of the next layer of soil "H" (Fig. 1) and its compaction with the appropriate soil compaction equipment to seal the slope within the sprinkled layer, a set of a jib crane with a soil compaction tool and a mobile (coupled with a crane) power station (not shown) is formed to power electric energy drive mechanism.

Keeping on the slope in the required position of the soil sealing working body is ensured by the accuracy of the breakdown and fixing of the axis of the penetration of the crane and the accuracy of tracking this axis.

Using the base machine 1 in the form of a jib crane, the soil-sealing working body 3 moves along the slope.

At the same time, the drive mechanism is switched on, the disturbing force of which in the form of an often shock load is transmitted to the contact of the roller 6 with the tire 8 and further to the ground.

As a result of exposure to the soil, a static load from the mass of the working body and frequent shock load from the inertoid occurs compaction of the soil.

If it is necessary to pass along one track, but in the opposite direction, the free end of the handle with the soil-sealing working body fixed on it is suspended on the cargo hook of the base machine and it unfolds.

The use of the perturbing force of the inertoid allows several times to reduce the weight of the soil-sealing working body, while maintaining the required regime of exposure to the soil in order to obtain the required density, thereby achieving a reduction in metal consumption and resistance to movement of the machine. In addition, the proposed device contains fewer parts in comparison with the known device, which makes it more reliable in operation.

The interdependence of the main parameters of the inercoid and their selection is as follows.

When using a commercially available rolling bearing with roller rolling bodies as the most loaded inertoid - treadmill assembly, the selection of parameters begins with the size of the diameter of the bearing inner ring - "D" (figure 5), the eccentricity - "e" between the axis of the treadmill and the axis the drive shaft, in the slot of which is placed with the possibility of free movement unbalanced mass in the form of a rod 16 (figure 4). The value of "D" is selected according to the current catalog, and the value of "e" should be taken equal to 0.25 D. The required value of the disturbing force for the two-shaft inertoid is determined by the formula

where m is the mass of the unbalance (rod), w is the angular velocity of the drive shaft, R is the distance from the axis of the drive shaft to the center of gravity of the unbalance (figure 4)

The maximum value of "P" corresponds to the position of the unbalanced mass (rod), when either end is at the point on the treadmill that is farthest from the center of rotation, i.e. at R _max , the value of which is determined by the formula

where A is the unbalance length (see Fig. 4, 5), which is calculated from the expression

Getting A = 0,86 value of R _max , the selected value of "D" is determined

Then the maximum value of the disturbing force for given and assigned values of "m", "w" and "D" is determined by the formula

P _max = z (mw ² · 0.32D)

D=0,4Example. Given

D = 0.4

The proposed design of a device for compaction of soil slopes allows to reduce its metal consumption and increase reliability in operation.

Claims (1)

A device for compaction of soil slopes containing a self-propelled base machine, a soil sealing working body and a drive mechanism for a working body, characterized in that it is additionally equipped with a handle pivotally articulated with a frame of a self-propelled base machine, the working soil sealing body is fixed to the free end of the handle and is made in the form of a spatial a frame inside which a freely rotating roller is installed, a steel tire freely covering the roller, the diameter of which is larger than the diameter of the roller, a vibrocar, sha articulated with a spatial frame and freely supported by rollers on a steel tire, and the drive mechanism is made in the form of a twin-shaft inertoid mounted on a vibrocarriage and consisting of a housing, two circular treadmills located inside the housing, two drive shafts with slots mounted eccentrically to the treadmills , two unbalanced masses installed in the slots with the possibility of free movement, while a jib crane is used as a self-propelled base machine.

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