RU2530136C2 - Method of preparation for storage and usage of bulk geogrid - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to the road and railway construction, construction of aerodromes, objects and structures for various purposes, landscape construction and can be used to organize the storage and use of bulk geogrid when developing the base of the road pavement. Method of preparation for storage and usage of bulk geogrid manufactured from the flexible strips stacked on each other and connected inter se in transverse direction in staggered order, consists in forming of package for its placing on the prepared surface. Formation of package is carried out by continuous zigzag laying on the prepared surface of indicated interconnected flexible strips at least in one horizontal row, at that the loops of zigzags have the same geometric dimensions.

EFFECT: technical result consists in providing the compact arrangement of bulk geogrid on the support surface while simplifying the process of geogrid usage.

6 cl, 1 dwg

Description

The invention relates to road and rail construction, the construction of airfields, objects and structures for various purposes, landscape construction and can be used to organize storage and use of volumetric geogrid when arranging the foundation of pavement.

Known volumetric geogrid (patent RU 2322543 C1, IPC Е01С 3/06, publ. 04/20/2008), formed from interconnected strips made of polymeric materials, and representing a single non-separable roll construction.

Known geogrid can be made in the factory and transported in roll packaging with its subsequent deployment when laying on a subgrade.

A disadvantage of the known solution is the lack of compactness during storage, as well as the low speed of deployment of the geogrid when using it.

As a prototype, the well-known geogrid (patent RU 98763 U1, IPC E02D 17/20, publ. 10/27/2010) made of stacked flexible strips stitched to each other and connected in the transverse direction by welded seams, while connected between the flexible strips are twisted by means of a bundle into a bag to place it on a prepared surface, with the possibility of forming a volumetric geogrid when the package is unfolded.

The well-known geogrid in the form of twisted packets is stored in a stack, which, when used, is freed from fasteners, stretched by hand and fastened to each other with metal staples by a mechanical stapler according to the technological process.

The disadvantage of the prototype is the lack of compactness during storage or transportation of packages, as well as the inability, at least partially, to mechanize the process of stretching and splicing packages to cover the required area of the equipped surface, as a result of which this process is slow, with great manual labor.

The technical result of this solution is to provide a compact placement of the volumetric geogrid on the surface of the carrier while simplifying the process of using the geogrid.

The specified technical result is achieved by the fact that the method of preparing for storage and use of geogrid made of stacked flexible strips stacked on each other and connected in the transverse direction between each other consists in forming a package for its placement on the prepared surface, while in accordance with the present method, the formation of the package is carried out by continuous zigzag laying on the prepared surface of the aforementioned interconnected flexible strips of at least one burn the horizontal row, and the zigzag loops have the same geometric dimensions.

There is a causal relationship between the set of essential features and the technical result, namely, due to the zigzag stacking of the connected flexible strips in at least one horizontal row formed from zigzag loops having the same geometric dimensions, compact arrangement of the package volumetric geogrid of technologically sufficient length with the possibility of continuous sequential pulling of the geogrid from the package row by row, n starting from the bottom beyond its end and its subsequent unfolding with the desired degree of stretching in the longitudinal and transverse sections, thus allowing the quick laying of the volumetric geogrid on the subgrade with very little effort if the stretched row is isolated from the impact other rows.

It is advisable to lay the interconnected flexible bands of the geogrid in one or more additional rows so that each subsequent row is located above the previous one, which allows you to place more bulk geogrid on the carrier.

Between the rows of the formed package, it is advisable to lay dividing elements in the form of strips, rods, belts, etc., and arrange them in the transverse direction relative to the longitudinal axis of the package, which allows sequentially, as each row is used up, to hang the package of the volumetric geogrid on the carrier between the geogrid rows, the said dividing elements so that the weight of the upper rows does not act on the lower (stretch row) and does not interfere with its movement, thus simplifying the process geogrid extraction.

It is advisable to tighten the formed package with one or more additional fasteners, which can be made in the form of tightening belts, which allows tightly pressing sections of the package to each other to reduce the overall structure during transportation or in the delivery state, followed by removal of fasteners when loading the package onto the carrier.

The invention is illustrated in figure 1, which shows a General view of the package geogrid (3 layers) in the delivery state.

The compact design of the elongated package volumetric geogrid according to the proposed method is formed as follows.

The scourge of the volumetric geogrid 1, consisting of flexible strips previously connected to each other by transverse, for example, welds, arranged in a checkerboard pattern (not shown), is laid on the prepared surface in several horizontal rows 2. The formation of rows 2 is carried out by continuous zigzag laying of the geogrid The result of which are areas that are loops 3 that have the same geometric dimensions. Between the rows 2 of the formed package design, spacer elements 4 are laid (for example, in the form of strips, rods, belts, etc.).

They are placed in the transverse direction relative to the longitudinal axis of the package.

In the state of delivery, the finished structure for convenience of transportation is pulled together by additional fastening elements 5 in the form of coupling belts.

Before using the geogrid, additional fastening elements 5 are removed and the rows of 2 lying on each other 2 are lifted by the dividing elements 4 above the lower row of the packet, thereby eliminating the effect of the weight of these rows on it.

When using the package, the beginning and the end of the volumetric geogrid constituting it are fixed, if necessary.

Next, for the end section 6 of the lower released row of the package, the geogrid is pulled and then stretched in cross section to install the resulting volumetric cellular structure on the subgrade.

As the lower row is used up, the following ones are isolated in their place, isolated from the action of the upper rows in the same way.

The proposed method allows you to place on a carrier of the same dimensions that is used in the prototype, a larger number of whips of a volumetric geogrid, and also facilitates the implementation of the technological process of its use, for example, when feeding a geogrid from a package from a platform of a railway repair complex into the basement and then stretching the geogrid into mute, where it becomes an element of the protective ballast layer.

Claims (6)

1. A method of preparing for storage and use of a volumetric geogrid made of flexible strips stacked on each other and stitched in the transverse direction between each other, consisting in forming a bag for its placement on a prepared surface, characterized in that the bag is formed in a continuous zigzag shape laying on the prepared surface of the aforementioned interconnected flexible strips in at least one horizontal row, and the zigzag loops have the same geometry sizes. 2. The method according to claim 1, characterized in that the laying of interconnected flexible strips is performed in one or more additional rows, and laying is carried out so that each subsequent row is located above the previous one. 3. The method according to claim 2, characterized in that between the rows lay separating elements in the form of strips, or rods, or belts, which are located in the transverse direction relative to the longitudinal axis of the package. 4. The method according to any one of claims 1 to 3, characterized in that the package is pulled together by one or more fasteners. 5. The method according to claim 4, characterized in that the fastening elements are in the form of coupling belts. 6. The method according to any one of claims 2, 3, 5, characterized in that the use of the volumetric geogrid is carried out by sequentially pulling its end from the packet row by row, starting from the bottom.