RU2232849C2 - Construction method with the use of free falling load for compacting and planing submerged rockfill foundation - Google Patents

Abstract

FIELD: building submerged foundations, particularly with the use of free falling load.

SUBSTANCE: method involves erecting embankment of rock fill having height slightly greater than design height of rockfill foundation and crest width slightly greater than design width of rockfill foundation, wherein both side parts increasing crest width are formed as temporary crest steps and inclined surfaces have inclination of friction slope; repeated compacting and planning embankment with the use of free falling load beginning at central crest part along temporary steps for decreasing crest height up to design height; crushing rock fill of temporary steps by applying load for reducing crest width up to design width; uncovering design crest steps from outer embankment sides to crest width; changing inclination angle of inclined surfaces up to design inclination angle.

EFFECT: possibility of crest steps planning by load application, provision of required crest step solidity and strength; minimized submerged finishing works carried out by divers and, as a result, reduced time and cost of foundation building in comparison with prior art.

3 cl, 3 dwg

Description

The present invention relates to an improved construction method using a free-falling load for compaction and layout of an underwater rock-fill base.

A known method of constructing an underwater rock-fill base (schematically shown in FIG. 3), in which an embankment of rock outline M with a cross section in the form of a hill, which has a ridge width corresponding to the design width W of the ridge, is slightly larger than the design height H, and two side inclined surfaces G ', G' with a slope of natural slope essentially equal to 1: 1 (in this case, the slope is the ratio of the length of the vertical line from the upper edge, namely, from the ledge S of the ridge to the bottom of the embankment to burn length the horizontal line from this vertical line to the lower edge of the slope; a similar one will be applied in the future). Then carry out the planning of the crest of the embankment through repeated free fall of the load P, suspended from the crane boom of the working boat, for compaction and planning to the design height.

The closest is the construction method using free-falling cargo for compaction and planning of an underwater rock-fill base, including its planning and compaction with cargo (see, for example, SU 252202 A, 02/09/1970, E 02 B 3/12). This method is the most effective and economical method of construction among the commonly proposed methods for planning an underwater rock-fill base.

The planning by the load P and compaction of the stone outline by means of planning are successively carried out from the central part of the ridge of the embankment from the stone outline to the outer edges, namely, to the ledges S, S of the ridge. Excessive stone fill is pushed to an open inclined surface.

In particular, since the ledges S, S of the ridge are in the open state on the outside, the layout with the load P will not lead to compaction, but rather will cause a fall of the stone outline in this part.

Therefore, the load planning P is not carried out directly on the ledges S, S of the ridge, but ends on the inside, and the formation of the ledges S, S of the ridge and the inclined surfaces G ', G' adjacent to them is carried out exclusively by divers during finishing work carried out under water by hand.

Namely, in practice, when carrying out underwater finishing works, they use the necessary template for the slope and pour the necessary amount of stone sketches into the ledges S, S of the ridge and the inclined surfaces G ', G' adjacent to them for finishing to the design width W of the ridge, design height H and design slope of inclined surfaces G, G (slope from about 1: 2 to 1: 3).

Thus, the density and strength of the ledges S, S of the ridge are essentially small compared with the density and strength in the central part of the ridge, where the layout is carried out with a load.

On the other hand, underwater finishing work should be carried out by divers in a floating state. In particular, in shallow water, the body becomes unstable even with a small wave, which makes it difficult to carry out such work in an accurate and safe way.

The objective of the present invention is to provide a construction method using a free-falling load for compaction and planning of an underwater rock-fill base, which allows you to plan the load even in the ledges of the ridge with achieving sufficient density and strength in these places, which, thus, can minimize the performance underwater finishing work by a diver and, thereby, significantly reduce the time and cost of construction compared with the prior art.

According to one aspect of the present invention, a construction method using a free-fall load for compaction and layout of an underwater rock fill base comprises the following steps.

1. The construction of the embankment from a stone sketch having a height slightly greater than the design height of the finished stone-spreader foundation, the width of the ridge, slightly larger than the design width of the crest of the finished stone-spacer foundation, while both side-increasing widths are temporary ledges of the crest , and inclined surfaces having a slope of natural slope.

Repeated free fall of compaction and planning from the central part of the ridge along temporary ledges of the ridge to reduce the height of the ridge to the design height.

2. The collapse of the weight of a stone sketch on temporary ledges of the ridge to reduce the width of the ridge to the design width of the ridge, exposing the design ledges of the ridge on the outer edges along the width of the ridge, and changing the slope of the inclined surfaces from the slope of the natural slope to the slope of the design inclined surfaces.

The design slope of the inclined surfaces is preferably from 1: 2 to 1: 3. A construction method using a free-falling load for compaction and planning of an underwater rock-fill base may also include the stage of the necessary finishing work on the project ledges of the ridge and adjacent project inclined surfaces, which are manually performed by a diver underwater.

The present invention is explained below with reference to the accompanying drawings on the example of a preferred embodiment of the present invention, which, however, should not be construed as limiting the invention, but as serving only to explain and understand it.

The drawings show:

figure 1 - section of the first embodiment of the embankment of the stone outline according to the present invention;

figure 2 is a section showing the collapse of the temporary ledge of the ridge after compaction of the embankment from the stone outline to the design height;

figure 3 - section of the embankment of the stone outline, designed to discuss the usual method.

Below the present invention is described in detail by way of example of a preferred variant of its implementation and with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. However, as is apparent to those skilled in the art, the present invention can be practiced without these specific details. On the other hand, in order to avoid unnecessary ambiguity of the present invention, a well-known structure is not shown in detail.

The present invention is described in detail on the example of a preferred variant of its implementation, shown in figures 1 and 2.

It is assumed that the finished underwater rock-fill base has a design width W of the ridge, design height H, design inclined surfaces G, G (with a slope essentially from 1: 2 to 1: 3), and thus the outer edges of the ridge on it the design width W and the upper edges of the design inclined surfaces G, G form ledges S, S.

First, from a working boat, in a known manner, a stone sketch is performed for constructing embankment M from it with a cross section in the form of a hill and with the following structure.

The embankment of the rock outline M is formed with a height H ', slightly larger than the design height H, namely with an additional outline. On the other hand, the width W of the ridge is greater than the design width W of the ridge, for example, exceeding the length of one edge of the load P at least twice (about 2.5 m). The parts corresponding to both elongated side parts L are temporary steps S ', S'. In addition, the slope of the inclined surfaces G ', G' is equal to the slope of the natural slope (essentially 1: 1).

Then, for compaction and planning from the height H 'of the ridge to the design height H, the free-fall planning P is carried out, suspended from the crane boom of the working boat, from the central part of the ridge in its additional outline towards the outer edges, namely along the temporary ledges S', S 'formed by incremental parts of length L.

Since, in this case, temporary steps S ', S' are open to the outside, striking with a load P would lead to a collapse of the outline in the corresponding parts, while the compaction would essentially become insufficient.

However, it should be noted that the ledges S, S of the ridge located inward from the temporary ledges S ', S' of the ridge, namely the ledges S, S of the ridge at the outer edges of the projected width of the ridge W and the upper edges of the projected inclined surfaces G, G, are densely sealed like the central part of the surface of the ridge.

Then, by vertical sliding or lateral swinging of the load P relative to the temporary ledges S ', S' of the ridge, the width of the ridge is brought to the design width W, exposing the ledges S, S of the ridge and changing the slope of the slope (essentially 1: 1) of the inclined surfaces G ', G 'to the slope of the design inclined surfaces G, G, essentially equal to from 1: 2 to 1: 3.

After that, to obtain the desired underwater stone-casting foundation, the necessary finishing work is carried out in relation to the ledges S, S of the ridge and the inclined surfaces G, G adjacent to them, performed by divers manually under water to complete the stage of the construction method using a free-fall load for compaction and layout of the underwater stone-cast foundation.

As follows from the foregoing, when using the construction method using a free-falling load for compaction and planning of an underwater rock-fill base, even in the ledges of the ridge, sufficient density and strength can be achieved by planning with the load. In this way, underwater finishing work performed by a diver can be minimized. Therefore, compared with the conventional method, it is possible to significantly reduce the time and cost of construction.

Claims (3)

1. The method of construction using free-falling cargo for compaction and planning of an underwater rock-fill base, including its planning and compaction with cargo, characterized in that the following stages are carried out: a mound of stone skeleton is constructed, having a height slightly higher than the design height of the finished stone -based base, the width of the ridge, slightly larger than the design width of the ridge of the finished stone-filled base, while both increasing the width of the side parts are temporary lips the ridge, and inclined surfaces having a slope of natural slope, repeatedly compact and lay from the central part of the ridge along temporary ledges of the ridge to reduce the height of the ridge to the design height by freely dropping the load, and then load the stone outcrop on temporary ledges to reduce the width of the ridge to the design width of the ridge, exposing the design ledges of the ridge on the outer edges along the width of the ridge, and change the slope of the inclined surfaces from the slope of the natural slope to the slope of the design inclined surfaces. 2. The method of construction using free-falling cargo for compaction and planning of an underwater rock-fill base according to claim 1, in which the slope of the design inclined surfaces is from 1: 2 to 1: 3. 3. The method of construction using free-falling cargo for compaction and planning of an underwater rock-fill base according to claim 1 or 2, which additionally includes the stage of the necessary finishing work on the project ledges of the ridge and adjacent project inclined surfaces, which are manually performed by a diver under water.

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