RU1788806C - Multilayer hydraulic deal protection material - Google Patents

Abstract

FIELD: hydraulic seal protection materials. SUBSTANCE: multilayer hydraulic deal protection material contains monolith coating layer 1 made of low density polyethylene, underlayer 2 made of radiation-modified foam polyethylene, and reinforcing layer 3 made of reticulate fiber glass material having polymer film 4 on its surface, with all layers connected by welding. EFFECT: increased reliability. 2 dwg

Description

 The invention relates to materials for the protection of waterproofing.

 Known multilayer material made of elastically interconnected underlying and covering layers of polymeric materials and a reinforcing layer located between them.

 The covering layer of the material is a polymer fabric, i.e., its outer surface is cellular, uneven. The covering and underlying layers are not interconnected over the entire surface. Their connection is carried out through the reinforcing layer only at individual points of the coating.

 When using such material in tunneling, reliable protection of the tunnel waterproofing from mechanical damage during backfilling of the soil and during operation when there are shifts of soil in contact with the cellular surface of the covering layer is not provided.

 The aim of the invention is to increase the reliability of protecting the object from mechanical damage.

 This goal is achieved by the fact that in a multilayer protective material containing interconnected underlying and covering layers of polymeric materials and a reinforcing layer located between them, the covering layer is made of monolithic polyethylene, the underlying layer is made of radiation-modified polyethylene foam, and the reinforcing layer is made of mesh fiberglass material with a polymer film on its surface, while the connection of the constituent layers is made welded.

 In FIG. 1 shows a multilayer material, general view (plan); in FIG. 2 is a cross-sectional view of a multilayer material (section AA in FIG. 1).

 The multilayer protective material comprises a covering layer 1 and an underlying layer 2 made of polymeric materials that are elastically connected to each other. The covering polymer layer 1 is made monolithic and is a dense thermoplastic material with a smooth outer surface. The underlying polymer layer 2 is made of foamed thermoplastic material. Between layers 1 and 2 there is a reinforcing layer 3 made of fiberglass mesh material, the surface of which is covered with a polymer film 4. All layers are directly connected to each other by welding, i.e. their joint 5 is made welded, forming a coating resistant to mechanical influences.

 As a polymer material in a particular multilayer material of the present invention, low pressure polyethylene is used, radiation-modified polyethylene foam is used as a foamed polymer material, and a high-pressure polyethylene film is used as a polymer film.

 Protective material works as follows.

 The multilayer protective material is fixed in the conditions of the construction site on the walls of the tunnel, previously coated with waterproofing material. During backfilling of the soil during the construction of tunnels in an open way (or when the soil moves in the zone of already existing underground structures), the protective coating experiences significant tensile loads. Moreover, since the covering layer 1 is monolithic, all soil components slide along its smooth outer surface, without violating its integrity. Monolithic polyethylene of the covering layer 1, having high tensile strength combined with elasticity, together with the reinforcing layer 3 perceives tensile stresses, and since all layers are directly connected by welding, the protective coating does not delaminate and reliably protects the waterproofing layer from mechanical damage.

 Possible shock and compressive loads that occur during backfilling of the cargo are largely perceived by the fiberglass mesh material of the reinforcing layer 3 together with monolithic polyethylene of the covering layer 1, which have high impact-resistant characteristics, and are evenly distributed on the waterproofing surface with polyethylene-based soybean 2, which has buffering properties.

 The mesh size of the mesh is selected from the conditions for providing the possibility of welding 5 layers. (To ensure a sufficient contact area of the welded coating layers, the cell size should not be less than 5 mm).

 The foamed material of the underlying layer 2 ensures the adhesion (or contacting) of the protective coating over the entire surface of the waterproofing of the underground structure (even if it is uneven). Therefore, loads, which are still partially transmitted through the protective coating to the waterproofing, are distributed evenly over the surface and do not reach dangerous values.

 Thus, the proposed multilayer protective material in operation does not delaminate and, in addition, significantly levels the loads transferred to the waterproofing on the surface, which allows reliable and long-term protection of the waterproofing of underground structures from mechanical damage.

Other positive properties of the claimed material are:
- ensuring the protection of waterproofing from temperature extremes, which is explained by the high heat-insulating properties of polyethylene foam;
- simplicity of the technology of manufacturing a multilayer material;
- the convenience of the method of installing protective material at the construction site. (56) UK patent N 2083115, CL. E 02 B 3/04, 1982.

Claims (1)

 MULTI-LAYERED WATERPROOFING PROTECTION MATERIAL, containing interconnected underlying and covering layers of polymeric materials and a reinforcing layer located between them, characterized in that, in order to increase the reliability of protection of the object from mechanical damage, the covering layer is made of monolithic low-pressure polyethylene, the underlying layer made of radiation-modified polyethylene foam, and the reinforcing layer is made of a mesh fiberglass material with a polymer film on its surface , The compound of constituent layers formed weld.

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