RU2157440C2 - Expansion joint for engineering structures - Google Patents

Abstract

FIELD: repairs of engineering structures including bridges. SUBSTANCE: expansion joint has base layer and protective layer. Base layer is composed of flexible rubber material whose expansion saturation coefficient at -50 C is 0,30 to 0,60 and whose rubber mass changes after swelling in standard fluid SZhR-1 at +100 C for 24 hours from +1,0 % to +8,0 %. Base layer has two grooves on external surface and one more on inner side of layer with metal reinforcement inside layer. Protective layer is made of base layer rubber or metal sections. EFFECT: improved working characteristics at low temperatures with high corrosion resistance of rubber layers. 3 cl, 1 tbl, 2 dwg

Description

 The invention relates to the construction and repair of engineering structures, in particular bridges.

 Known temperature seam for bridges and other engineering structures, containing a carrier layer of elastic rubber material with two grooves on the outer surface and one on the inner side of the layer and with metal fittings located inside the layer and a protective layer made of metal profiles [1].

 The disadvantage of this expansion joint for bridges and other engineering structures is the unsatisfactory low-temperature and corrosion-resistant performance characteristics determined by the properties of the rubber of the bearing layer.

 Known temperature seam for bridges and other engineering structures, containing a bearing layer of elastic rubber material made of rubber based on natural, styrene butadiene or ethylene propylene rubbers, with two grooves on the outer surface and one on the inner side of the layer and with metal reinforcement located inside the layer and a protective rubber layer of rubber based on polychloroprene rubber [2].

 The disadvantage of this expansion joint for bridges and other engineering structures is the unsatisfactory low temperature performance.

 The aim of the invention is to improve the low-temperature operational characteristics of the temperature joint for engineering structures while maintaining a high level of corrosion-resistant properties of the rubber layers.

This goal is achieved in that the temperature seam for engineering structures, comprising a carrier layer of elastic rubber material with two grooves on the outer surface and one on the inner side of the layer and with metal fittings located inside the layer and a protective layer, is characterized in that the carrier layer is made of rubber having a coefficient of frost resistance to tension at a temperature of -50 ^o C from 0.30 to 0.60 and a change in the mass of the rubber sample after swelling in a standard liquid SZHR-1 at a temperature of +100 ^o C for 24 hours from + 1.0% to + 8.0%. The protective layer is made of rubber of the carrier layer or of profiles.

 In FIG. 1 shows in cross section a temperature seam for engineering structures with a protective layer of rubber bearing layer. In FIG. 2 - temperature joint for engineering structures with a protective layer of metal profiles.

The temperature seam for engineering structures contains a carrier layer 1 of elastic rubber material made of rubber having a coefficient of frost resistance to tension at a temperature of -50 ^o C from 0.30 to 0.60 and a change in the mass of the rubber sample after swelling in a standard liquid SZHR-1 at a temperature of +100 ^o C for 24 hours from + 1.0% to + 8.0%, with two grooves on the outer surface 2 and one on the inner side of the layer 3 and with a metal reinforcement 4 located inside the layer, and a protective layer 5 made of rubber of the bearing layer or of metal profiles.

 As elastic rubber material for the carrier and protective layers, propylene oxide rubber rubbers or a combination thereof with poorly defined rubbers such as butyl rubber, ethylene propylene rubber or hydrogenated nitrile butadiene rubber can be used.

 The metal reinforcement is covered with rubber sheets of the carrier layer, then rubber sheets of the protective layer or metal profiles of the protective layer are applied. After such assembly, the resulting preform is placed in a mold and vulcanized in the press under the influence of temperature and pressure. At the end of the vulcanization process, the finished temperature seam for engineering structures is removed from the mold.

The low-temperature operational characteristics of the temperature joint for engineering structures were evaluated by the coefficient of reliability coefficient (KN) at room temperature and -40 ^o C according to the following method.

 The test samples were fragments cut in the transverse direction with full preservation of the cross section with a length of 350 mm from expansion joints for engineering structures, made according to the prototype and according to the invention.

 The prototype sample had a carrier layer made of rubber based on ethylene propylene rubber.

The tests were carried out at temperature seams for engineering structures with a nominal extension of 25 mm, which is installed for this type of temperature seam for engineering structures. The testing device was a horizontal tensile testing machine with special fasteners for samples of expansion joints for engineering structures. Prior to testing at -40 ^° C, the samples were preliminarily aged 48 hours in a refrigerator at a given temperature.

Коррозионную стойкость защитного и несущего резиновых слоев оценивали по изменению массы образца резины после его набухания в стандартной жидкости СЖР-1 при 100^oC в течение 24 ч в соответствии с ГОСТ 9.030-74.The fixed samples of the temperature joint were stretched on the testing device until fracture, while fixing the elongation during fracture. KH was calculated by the formula:

The corrosion resistance of the protective and bearing rubber layers was evaluated by the change in the mass of the rubber sample after swelling in standard liquid SZHR-1 at 100 ^o C for 24 hours in accordance with GOST 9.030-74.

The coefficient of frost resistance of carrier rubber and protective layers under tension at a temperature of -50 ^o C was determined according to GOST 408-78 method A.

The test results of samples of expansion joints for engineering structures are presented in the table, from which we can draw the following conclusions:
1. The temperature seams for engineering structures (2-4), made according to the invention and control example (6), have higher values of the coefficient of reliability at room and low temperatures compared to the temperature seam for engineering structures made according to the prototype (1) and test case (5).

 2. The temperature seams of engineering structures (2-4) made according to the invention have more corrosion-resistant rubber layers compared to the temperature seam according to control example (6) and the carrier layer of the prototype (1).

 3. High low-temperature operational characteristics of the temperature joint for engineering structures while maintaining a high level of corrosion-resistant properties of the rubber layers can only be obtained using the technical solution according to the invention.

References
1. The patent of Germany N 2330640, E 01 D 19/06, 1973.

 2. The patent of Germany N 2709708, E 01 D 19/06, 1981 - prototype

Claims (3)

1. A temperature seam for engineering structures, comprising a carrier layer of elastic rubber material with two grooves on the outer surface and one on the inner side of the layer and with metal fittings located inside the layer and a protective layer, characterized in that the carrier layer is made of rubber having a coefficient frost resistance under tension at a temperature of -50 ^o C from 0.30 to 0.60 and a change in the mass of the rubber sample after swelling in a standard liquid SZHR-1 at a temperature of +100 ^o C for 24 hours from +1.0 to +8.0 %  2. The temperature seam for engineering structures according to claim 1, characterized in that the protective layer is made of rubber carrier layer.  3. The temperature seam for engineering structures according to claim 1, characterized in that the protective layer is made of metal profiles.

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