RU60545U1 - GEOMAT - Google Patents

Abstract

The proposed technical solution relates to the field of construction, namely, to the field of soil strengthening on slopes and slopes of embankments, trenches when laying pipelines, and can also be used when carrying out soil works during the construction of structures for various purposes, or to strengthen natural soil formations subject to wind erosion water erosion or landslide hazard. The objective of this technical solution is to reduce the complexity of manufacturing a geomat by ensuring the connection of non-woven synthetic material tapes by heat welding along the entire height of the tape with the formation of diamond-shaped geomate cells when stretched, which ensure effective filtration of water through all the walls forming the cell, inclined to the geomat stretching direction, this is achieved by that the geomat is formed by ribbons of non-woven synthetic material laid parallel to each other with the formation the transverse direction of the foot and welded continuous seams in adjacent tapes with respect to their height along the height alternating along the length of the tape connecting the two tape seams in a staggered manner with seams connecting these tapes with adjacent outer years, so that when the tapes are moved in the direction of the longitudinal axis of the geomat is perpendicular to the initial moment of their surface, they form diamond-shaped cells. At the same time, at least part of the tapes can be made with reinforcing elements. The tape reinforcing element can be made in the form of an additional tape connected to the main one by welding discretely or along the entire length,

performed before joining the tapes in the geomat. The reinforcing element can be made in the form of an additional tape connected to the main one by volumetric thermal bonding of their fibers by jointly blowing hot gas through them. The tape reinforcing element can be made in the form of at least one groove located longitudinally or obliquely to the axis of the tape and made by mechanical action on the heat-treated surface of the tape. The tape reinforcing element can be made in the form of a series of holes with edges formed by the melted tape material, which after cooling has a stiffness exceeding the stiffness of the tape material. At the same time, the holes can be evenly spaced along the entire length of the tape or discrete in groups along the length of the tape with a step between groups that is a multiple of a step or half a step between the seams connecting adjacent tapes. In this case, the holes can be located on a pair of adjacent sides of the diamond-shaped cell, symmetrical to the longitudinal axis of the geomat, or located on a pair of opposite sides of the diamond-shaped cell. In addition, tapes with reinforcing elements can be arranged alternately between tapes without reinforcing elements. Tapes with different filtering properties can be used. A geomat can be formed by alternating in the groan of tapes of needle-punched and needle-punched non-woven synthetic material. At least part of the geomat tapes can be matched. In addition, at least part of the tapes has loops on opposite columns for attaching the geomat with anchors or for connecting to a nearby geomat.

Description

The proposed technical solution relates to the field of construction, namely, to the field of soil strengthening on slopes and slopes of embankments, trenches when laying pipelines, and can also be used when carrying out soil works during the construction of structures for various purposes, or to strengthen natural soil formations subject to wind erosion water erosion or landslide hazard.

Known geokarkas used to reinforce the slope, and arranged in the form of parallel arranged polymeric tapes forming the bag and stitched together lengthwise staggered to form tensile rhomboid cell shape (Application Geomaterials during construction and renovation of transport objects, Materials II ^Second International Scientific Technical Conference, St. Petersburg, 2002, p.108, 109).

Known geo-frame, which is a cellular structure made of flexible polyethylene tapes mounted on the ribs and connected by welded spot seams located in it in a checkerboard pattern (patent RU No. 2156025 C1, 2001).

Such geocarcass structures do not provide the necessary filtration of water through tapes, which leads to leaching of the soil placed in the cells, or to leaching of the base on which the geocad is located.

A geomat is known, which is a package made of flexible geotextile strips of nonwoven fabric hardened by dressing, installed on the ribs and connected to each other in a checkerboard pattern by vertical stitched seams, providing when stretching the strips in the direction normal to their surface, a honeycomb structure with hexagonal cells ( RU patent No. 2180030 C1, 2002).

The closest known one is a geomat containing a set of flexible tapes stitched together in a checkerboard pattern perpendicular to the long sides of the flexible tapes with seams with the possibility of forming a cellular structure filled with bulk soil when laying a set of flexible tapes with their long edges on the ground and applying transverse and longitudinal tensile forces to the extreme tapes with subsequent fixation on the soil of the cells around the perimeter of the stretched set of flexible tapes, while, to increase stability, In order to ensure the stability and transverse rigidity of the geogrid, flexible ribbons are made of soft rolled materials, and the geogrid cells are hexagonal, for which the fastening seams are made of equal strength material of the ribbons and are doubled with a distance between the double seams not exceeding half the distance between the internal seams of the pairs forming the geogrid cells, while in the set of flexible tapes the outer one can be double or of a material with higher mechanical properties and light fastness (patent RU No. 2228479 C1, 2004) .

The well-known geomat is laborious to manufacture, since it involves the operation of joining tapes with double seams, and also in connection with the execution of cells hexagonal - an increase in labor costs for the formation of seams, which determines the given shape of the cell. In addition, the shape of the cell determines the presence of two faces in it, perpendicular to the direction of the tensile force during the formation of the cell and perpendicular to the direction of influence on them filling the cell material, which leads to clogging by the particles of the filtering structure of the ribbons and a decrease in the filtering ability of the geomat as a whole. This circumstance can lead to an increase in filtration through the open surface of the cells and, as a result, to the washing away of the protected soil base or to washing out the contents of the cell with the subsequent loss of its shape and folding of its walls, which excludes the fulfillment of its basic functions by the geomat. In addition, when technical fabric used for ballasting underground pipelines is used for the manufacture of flexible tapes, its connection is possible only by firmware with preliminary fixing of the tape edge with a seam, eliminating the shedding of the longitudinal edges of the threads.

The objective of this technical solution is to reduce the complexity of manufacturing a geomat by providing the connection of non-woven synthetic material tapes by heat welding along the entire height of the tape with the formation of diamond-shaped geomate cells when stretched, which ensure effective filtration of water through all the cell walls inclined to the geomat stretching direction.

This is achieved by the fact that the geomat is formed by ribbons of non-woven synthetic material, laid parallel to each other with the formation in the transverse direction of the foot and connected in adjacent ribbons with each other along their height by welded solid seams with alternating along the length of the tape alternating stitches connecting two ribbons in a checkerboard pattern

in order with the seams connecting these tapes with adjacent external tapes, so that when the tapes are moved in the direction of the longitudinal axis of the geomat, perpendicular to the initial moment of their surface, they form diamond-shaped cells. At the same time, at least part of the tapes can be made with reinforcing elements. The tape reinforcing element can be made in the form of an additional tape connected to the main one by welding discretely or along the entire length, performed before the tapes were joined in the geomat. The reinforcing element can be made in the form of an additional tape connected to the main one by volumetric thermal bonding of their fibers by jointly blowing hot gas through them. The tape reinforcing element can be made in the form of at least one groove located longitudinally or obliquely to the axis of the tape and made by mechanical action on the heat-treated surface of the tape. The tape reinforcing element can be made in the form of a series of holes with edges formed by the melted tape material, which after cooling has a stiffness exceeding the stiffness of the tape material. At the same time, the holes can be evenly spaced along the entire length of the tape or discrete in groups along the length of the tape with a step between groups that is a multiple of a step or half a step between the seams connecting adjacent tapes. In this case, the holes can be located on a pair of adjacent sides of the diamond-shaped cell, symmetrical to the longitudinal axis of the geomat, or located on a pair of opposite sides of the diamond-shaped cell. In addition, tapes with reinforcing elements can be arranged alternately between tapes without reinforcing elements. Tapes with different filtering properties can be used. A geomat can be formed by alternating in the foot tapes of needle-punched and needle-punched non-woven synthetic material. At least part of the geomat tapes can be matched. In addition, at least part of the tapes has

opposite ends of the loop for attaching the geomat with anchors or connecting to a nearby geomat.

Figure 1 presents a General view of the geomat (fragment) with years assembled in the drive from non-woven synthetic material;

Figure 2 presents a fragment of the geomat, a top view in the working position.

For the design of the geomat, we use ribbons 1 made of non-woven synthetic material, for example TU 63.178.59-79, TU 63.178.51-78 or polyester TU RB 300478750-002-3001. Tapes 1 are laid parallel to each other with the formation in the transverse direction of the foot (Fig. 1) and adjacent ones are connected to each other by their height by welded solid seams 2 with alternating along the length of the tape in a checkerboard pattern with seams 3 connecting these tapes with adjacent ones them with external tapes. Tapes 4 have amplification elements. When the tapes 1 and 4 are moved relative to each other in the direction of the longitudinal axis of the geomat, perpendicularly at the initial moment to their surface, they form diamond-shaped cells 5. The reinforcement element of the tape 4 is made in the form of an additional tape connected to the main one by welding discretely or along the entire length made before joining the tapes in the geomat - in this case, the rigidity of the geomat design increases. As an option, the reinforcing element is made in the form of an additional tape connected to the main by volumetric thermal bonding of their fibers by jointly blowing hot gas through them - in this case, the filtering ability of the tape is preserved with increasing strength characteristics. The reinforcing element of the tape can be made in the form of at least one groove 6 located longitudinally or inclined to the axis of the tape 4 - (figure 3). The groove 6 is made by mechanical action on the heat-treated surface of the tape 1 or 4. The reinforcing element of the tape 6 may be in the form of a hole (figure 3) with the edges (groove) formed

melted tape material having, after cooling, a stiffness exceeding the stiffness of the tape material. The holes are evenly distributed over the entire length of the tape or discrete in groups along the length of the tape 4 with a step between groups that are a multiple of a step or half a step between the seams connecting adjacent tapes - this ensures a different arrangement of holes on a pair of adjacent sides of the diamond-shaped cell 5 - symmetrically to the longitudinal axis of the geomat or on a pair of opposite sides of the diamond-shaped cell. Tapes 4 with reinforcing elements are arranged alternating between tapes 1 without reinforcing elements, which ensures the formation of enlarged areas with more efficient (water filtration, thereby preventing soil erosion. This is also facilitated by the use of tapes 1 and 4 with different filtering ability - zones with increased filtration ability can be calculated by the effective filtration area depending on the properties of the soil at a given location.The geomat can be formed by alternating in the foot tapes of needle-punched and gloproshivnogo non-woven synthetic material - this also provides a different filtration ability of the geomat over its area.At least, the cleanliness of the geomat tapes can be adjusted, which also changes the strength characteristics - the stiffness of the tape, and also binds the fibers that form it, fixing the attached structure for the entire duration of operation Tapes 1 or 4 may have loops 7 at opposite ends for attaching the geomat with anchors or connecting to a nearby geomat.

The design of the geomat is highly technological, it can be manufactured with the use of an automated line, in which the formation of welds is carried out by placing in a given place (immediately along the entire length of the mites) a package of rod (wire) heaters, fixed on the traverse and removed from the space between the stacked ones

tapes followed by compression of tapes. As a result, high-strength seams 2 and 3 are formed at the places of the material melt. A packet of interconnected tapes 1 n 4 forming a geomat is delivered to the object, for example, to the slope of the soil embankment, then stretched to form diamond-shaped cells 5 in it, and fixed through loops 7 and the cells 5 are filled with imported or local soil. The difference in the filtering characteristics of the tapes allows to increase the active filtration surface, to exclude soil displacement in the cells and clogging of their porous structure due to only the inclined arrangement of the cell walls 5.

For the manufacture of geomats, progressive non-woven synthetic materials of various chemical composition can be used, affecting the density of the tapes and their filtering properties.

Claims (14)

1. A geomat formed by ribbons of non-woven synthetic material, stacked parallel to each other with the formation in the transverse direction of the foot and connected in adjacent ribbons with each other along their height by welded continuous seams with alternating along the length of the tape stitching the two ribbons of stitches in a staggered manner with seams, connecting these tapes with adjacent external tapes, so that when moving the tapes in the direction of the longitudinal axis of the geomat, perpendicular to the initial moment of their surface, they form a diamond-shaped cells, with at least part of the tapes made with reinforcing elements. 2. The geomat according to claim 1, in which the reinforcing element of the tape is made in the form of an additional tape connected to the main one by welding discretely or along the entire length made before connecting the tapes in the geomat. 3. Geomat no. 1, in which the reinforcing element is made in the form of an additional tape connected to the main by volumetric thermal bonding of their fibers by jointly blowing hot gas through them. 4. The geomat according to claim 1, in which the tape reinforcing element is made in the form of at least one groove located longitudinally or obliquely to the axis of the tape and made by mechanical action on the heat-treated surface of the tape. 5. The geomat according to claim 1, in which the tape reinforcing element is made in the form of a series of holes with edges formed by the fused tape material, which after cooling has a stiffness exceeding the stiffness of the tape material. 6. The geomat according to claim 5, in which the holes are evenly distributed along the entire length of the tape. 7. The geomat according to claim 5, in which the holes are arranged discreetly in groups along the length of the tape with a step between groups that is a multiple of a step or half a step between the seams connecting adjacent tapes. 8. The geomat according to claim 7, in the cells of which the holes are located on a pair of adjacent sides of the diamond-shaped cell, symmetrical to the longitudinal axis of the geomat. 9. The geomat according to claim 7, in the cells of which the holes are located on a pair of opposite sides of the diamond-shaped cell. 10. The geomat according to claim 1, wherein the ribbons with reinforcing elements are arranged alternately between the ribbons without reinforcing elements. 11. Geomat but to any one of claims 1-10, in which tapes with different filtering capabilities are used. 12. A geomat according to any one of claims 1 to 10, which is formed by alternating in the foot of tapes of needle-punched and needle-punched non-woven synthetic material. 13. The geomat according to claim 1, in which at least a portion of the ribbons are finished. 14. The geomat according to claim 1, in which at least a portion of the tapes has loops at opposite ends for attaching the geomat with anchors or for connecting to a nearby geomat.