RU2398647C2 - Welded wire net for gabions - Google Patents

Abstract

FIELD: process engineering. ^ SUBSTANCE: invention relates to welded wire net for gabions intended for slope protection or erection of walls. Add to integrity of used wire net, particularly in weather conditions of Europe, net steel wire with diametre varying from 3.5 to 8 mm is coated with zinc-aluminium mix wherein fraction of aluminium and zinc makes 6-16 wt % and 84-94 wt %. ^ EFFECT: 200-to-300%-increase in life of gabions ^ 6 cl, 1 tbl, 1 ex

Description

The invention relates to a welded wire mesh for gabions for reinforcing slopes or erecting walls.

Gabions have long been known in various forms. They are also used to strengthen slopes or erect noise screens on highways.

As a rule, gabions consist of a mesh basket filled with rubble stone, gravel or other material, depending on the application. The mesh basket consists, as a rule, of steel wire.

The biggest problem of gabions is the low resistance of the steel wire used, especially in the climatic conditions of Europe. On motorways and highways of local importance, gabion nets are particularly stressed due to salinization of roads in winter. In particular, in noise barriers on motorways or highways of local importance, a grid failure caused by corrosion would have dire consequences, as falling stones would threaten traffic. In addition, the repair of the grid is associated with high financial costs and traffic restrictions.

As a rule, the steel wire used for gabion nets has a thickness of 3.5-6.0 mm and a GALFAN coating to increase corrosion resistance according to DIN EN 10326. GALFAN is a zinc-aluminum alloy coating with a 5% aluminum content in the immersion bath. When the coating hardens, a crystalline structure forms, which differs from the known structure of zinc streaks of hot-dip galvanized materials. The addition of 5% aluminum prevents the formation of intermetallic phases that adversely affect the behavior of the material during deformation. Depending on the requirements, the wire can therefore be rolled and edited. Zinc is a less noble metal than iron, and due to this, it gives its electrons as an anode to iron. Even if the zinc coating is damaged, when the base material is steel exposed, with sufficient moisture, a galvanic cell forms, which covers and protects the damaged area. These protective layers are composed of zinc carbonate and arise from exposure to carbon dioxide. The formation of so-called white rust makes it difficult to spread corrosion while zinc is applied. Then the base material is exposed, and red rust may form. From this we can conclude that with an increase in the proportion of zinc in the coating, the resistance of the wire increases.

Gabion nets are welded and woven. Weaving is significantly more complicated and, in accordance with this, also causes a significantly higher cost of manufacture. However, it is more difficult to produce welded meshes because high demands are placed on welded joints. Preferably, the welded gabion nets are resistant to shear stress.

For these reasons, for many years, attempts have been made to develop inexpensive, durable and corrosion-resistant nets for gabions.

The objective of the invention is the creation of a welded wire mesh for gabions, which has a significantly longer service life.

According to the invention, the wire for the mesh is coated with a zinc-aluminum mixture with a mass fraction of aluminum of 6-16% and a mass fraction of zinc of 84-94%. Unexpectedly, it turned out that the gabion net according to the invention, compared with the prior art, i.e. by coating with a mass fraction of aluminum of 5% and a mass fraction of zinc of 95%, it achieved a 200-300% increase in the service life confirmed by the salt spray test.

It was not obvious to the average person how to go beyond the eutectic point in the binary state diagram of aluminum-zinc at 5% aluminum and 95% zinc, since, thus, it is known that the quality of the structure deteriorated. It should be added that with an increase in the proportion of aluminum in the alloy, an increase in the melting temperature occurs and, as a result, this leads to an increase in energy consumption and the cost of manufacturing a mesh for coated gabions by immersion.

The cold drawn or hot rolled clean wire is first coated in a continuous process with a mixture consisting of 84% to 94% by weight of zinc and 6% to 16% by weight of aluminum. Then the coated wire is crossed and connected by the method of spot welding into the lattice.

Alternatively, in particular with a small load, first welding and then final immersion in a bath filled with a mixture of zinc and aluminum in accordance with the present invention can be performed.

Cold drawn or hot rolled bare wires are first coated continuously with a mixture of zinc with a mass fraction of 84-94% and aluminum with a mass fraction of 6-16%. Then, the cross-linked wires are connected to the grid by electric spot welding.

The cost of manufacturing a gabion net according to the invention differs only slightly from the cost of manufacturing traditional nets with a 2-3-fold increase in service life. Innovative coating does not affect the weldability of the wire.

Mostly the wire for the grid is coated with zinc-aluminum alloy with a mass fraction of aluminum of 8-12% and a mass fraction of zinc of 88-92%. In this range, the coating has the best deformation ability. This is important, in particular, for subsequent bending of the protruding ends of the wire in the form of eyes in order to avoid peeling of the coating.

In one preferred embodiment, the wire mesh is coated with zinc-aluminum alloy with a mass fraction of aluminum of 10% and a mass fraction of zinc of 90%.

Preferably, a cold drawn steel wire is used to make the gabion net.

In another preferred embodiment, up to 0.05% silicon is added to the coating components. Silicon improves adhesion of the coating.

In another preferred embodiment, more magnesium is added to the coating components with a mass fraction of 1-2% with respect to the total weight of the coating. Magnesium increases the flexibility of the coating.

The addition of magnesium and silicon is preferred for subsequent deformation / bending of the coated mesh.

The invention is illustrated below by examples of its implementation.

Example 1

A welded gabion net 300 × 100 cm with a mesh size of 10 × 10 cm consists of coated and cross-welded wires with a diameter of 4.5 mm. The wire has a tensile strength of at least 450 N / mm ² and is coated with a zinc-aluminum alloy with an aluminum fraction of 10% and a density of 300 g / m ² , which corresponds to a layer thickness of about 45 μm. Density should be understood as the mass of coating per unit area of the lateral surface of the coated wires. Welded joints are made by electric spot welding.

The coated gabion net was subjected to salt spray test. The test was carried out according to DIN 50021 SS in a test chamber for testing corrosion resistance under alternating load. The test was interrupted with a proportion of red rust of 5%. A mesh of identical dimensions and with the same tensile strength, but with a coating with an aluminum fraction of only 5% and a density of 350 g / m ^2, reached a reference value of 1050 hours in the described test. The mesh according to the invention reached a service life of 2520 hours. This corresponds to a significant increase in service life by a factor of almost 2.5 at a lower density.

The following table shows the data of the following five exemplary embodiments of the invention and other reference samples.

Try reference IN 2 IN 3 AT 4 AT 5 AT 6 Lattice size in cm 50 × 100 50 × 100 50 × 50 50 × 50 50 × 50 100 × 100 Cell size in cm 10 × 10 10 × 10 10 × 10 10 × 10 10 × 10 10 × 5 Wire diameter in mm 4.4 3,1 3,5 4,5 5,0 3,5 The tensile strength of the wire R _m in N / m ² 490 500 480 505 515 450 The proportion of aluminum in the coating 5 7 10 16 fourteen 10 Layer in g / m ² 350 350 300 350 350 350 Layer Thickness in µm 52 46 42 52 57 fifty Salt spray test life 1050 1950 2980 3200 3200 3100

With an increase in the proportion of aluminum in the coating, a distinct increase in service life occurs. Since the cost of manufacture, in particular energy costs, is simultaneously increasing, the optimal technological mode is between 8% and 12% of the share of aluminum in the coating.

Claims (6)

1. Welded mesh for gabions made of steel wire with a diameter of 3.5 mm≤d≤8 mm and coated with a zinc-aluminum mixture with a mass fraction of aluminum of 6-16% and a mass fraction of zinc of 84-94%. 2. The grid according to claim 1, characterized in that the mass fraction of aluminum is 8-12%, and the mass fraction of zinc is 88-92%. 3. The grid according to claim 1, characterized in that the mass fraction of aluminum is 10%, and the mass fraction of zinc is 90%. 4. The grid according to claim 1, characterized in that the wire is a cold-rolled wire. 5. The grid according to claim 1, characterized in that the coating contains as an additive up to 0.05% silicon. 6. The grid according to any one of the preceding paragraphs, characterized in that the coating contains as an additive 1-2% of magnesium.