RU2209269C1 - Support of contact network erected on swelling soils - Google Patents

Abstract

FIELD: construction and running of supports of contact network across sections of swelling soils in permafrost regions and in regions of deep season freezing. SUBSTANCE: novelty of invention lies in that antiswelling fixture comes in the form of complex of cooling facility operating in season built into support, having predominantly form of thermal siphon, layer hydraulic insulation and antiswelling rim. Hydraulic insulation is laid over day surface of soil around support and has radius not less than depth of seasonal soil thawing, it is produced from frost-resistant material, preferably foam polystyrene, is covered by layer of soil 10-20 cm thick or turf 15-25 cm thick. Antiswelling rim has form of protective mantle made of frost-resistant composite material, predominantly polymer material, arranged around part of support worked deep in soil, bordering on floor of layer of hydraulic insulation and having length equal to 0.4-0.6 depth of seasonal soil thawing and non-freezing grease put between mantle and surface of part of support worked deep in soil. Part of support above ground surface is painted by light-reflecting paint to height of 0.5-1.0 m. EFFECT: enhanced stability of support erected on swelling soils by reduced effect of forces of freezing swelling on support in season-thawed layer and by rise of forces reacting against its freezing together with permafrost soils. 1 dwg

Description

 The invention relates to the construction and operation of the supports of the contact network in areas of heaving soils in areas of permafrost and deep seasonal freezing.

 Known design methods for ensuring the stability of the supports of the contact network in areas of heaving soils in areas of permafrost and deep seasonal freezing: wooden boxes with draining soil, wrapping with plastic wrap, anchor plates, etc. [1].

 The above methods require large expenditures for the construction and maintenance of the support facilities in working condition and, as experience in the construction and operation of railways in the permafrost zone [2] indicates, do not ensure the stability of the supports of the contact network. It is necessary to periodically correct and replace unstable supports in areas of heaving soils, thereby increasing unproductive costs.

 The closest to the proposed design in terms of technical nature and the achieved result is the support of the contact network, erected on heaving soils, including an anti-dehumidification device - filling the sinuses of the upper 2/3 of the pit depth with non-porous drainage soil, protected from surrounding soil by a wooden box or geotextile [1].

 The main disadvantage of the known design is the requirement for deep groundwater level (not less than 2.7 m from the calculated surface of the soil), which is actually difficult for heaving soils of the seasonally thawed layer. And when saturated with water, backfilling of the sinuses during freezing also becomes heaving - anti-porcine measures become ineffective. Over time, this is also facilitated by frosty weathering of large-fragment particles of backfill and pore colmatation by weathering products.

 The objective of the invention is to increase the stability of the support erected on heaving soils by reducing the effects of frost heaving forces on the support in the seasonally thawed layer and increasing the opposing forces of freezing it with permafrost soils.

 The problem is solved due to the fact that the support erected on heaving soils includes an anti-damper device, which according to the invention is made in the form of a complex of a seasonally acting cooling device integrated in the support, mainly in the form of a thermosiphon, a layer of thermal waterproofing and an anti-canopy bandage, moreover, thermal waterproofing is applied to the surface soil around the support and made with a radius not less than the depth of seasonal thawing of the soil, from frost-resistant material, preferably extrusion polystyrene foam, sprinkled on top with a layer of soil or turf with a thickness of 15-25 cm and a thickness of 10-20 cm, and the anti-dam bandage is made in the form of a protective casing of frost-resistant composite material, mainly polymeric, placed around a part of the support buried in the ground adjacent to the bottom of the layer thermal waterproofing and a length equal to 0.4-0.6 of the depth of seasonal thawing of the soil, and non-freezing grease between the casing and the surface of the support part, buried in the ground, and the above-ground part of the support A height of 0.5-1 m from the surface of the earth is painted in a reflective color.

 The technical result provided by the given set of features is to increase the stability of the support of the contact network, erected on heaving soils due to the combined action of a seasonal cooling device and thermal insulation, as a result of which the roof of the permafrost rises around the support and the corresponding reduction in the thickness of seasonal soils also due to the fact that the anti-canopy bandage protects the support from the effects of heaving during freezing of seasonally thawed soil a, and coloring the above-ground part of the support in a reflective color reduces its heating by sunlight and the corresponding heat transfer to the soil, which also helps to reduce the depth of its seasonal thawing. As a result, the strength of buckling of the support in seasonally thawed soil decreases and its pinching in the permafrost increases, which generally ensures the stability of the support erected on heaving soils in areas of permafrost. In the case of installing such a support in the areas of deep seasonal freezing of the soil, permafrost is first formed, the seasonal freezing layer turns into seasonally thawed layers, and then the support interacts with the soil as described above.

 The invention is illustrated by the drawing, which schematically depicts the support of the contact network with the anti-dam device in section. The support of the contact network 1, erected on heaving soils, includes an anti-damper device made in the form of a complex of a seasonally acting cooling device 2 integrated in the support, a layer of thermal waterproofing 3 of the soil surface around the support and an anti-dam band 4 on the part of the support buried in the ground, as well as painted in reflective the color of the aerial part of the support (not shown in the drawing). Seasonal cooling device 2, mainly in the form of a thermosiphon, is inserted into the hollow reinforced concrete support 1 in the space from the bottom plug to the bottom hole for installing embedded parts (not shown in the drawing). In the case of a metal support, which usually consists of a tubular metal foundation and a metal stand installed on it, the seasonal cooling device is placed in the hollow foundation so that the ground heat exchanger of the seasonal cooling device is in the space between the lower end of the support foundation and the level of the daily surface of the surrounding soil, and the air heat exchanger of a seasonal cooling device was located in a space above this level up to ur vnya lower holes for fixings metal arm support. To preserve the winter cold accumulated by means of a seasonally acting cooling device in the soil massif, a thermal waterproofing 3 of frost-resistant material, preferably extruded polystyrene foam, for example, Penoplex 45 heat-insulating plates, is applied around the support around the support of the soil surface. The thickness of the thermal insulation layer is 10-20 cm, the radius of the surface to be closed around the support is not less than the depth of seasonal thawing of the soil 5. To prevent damage by sunlight and mechanical stress when people are near the support, as well as to protect against abduction and vandalism, the thermal insulation is covered with a protective layer of soil or turf with a thickness of 15-25 cm (not shown in the drawing). To protect the support from the effects of heaving when freezing seasonally thawed soil, an anti-canopy bandage 4 is made of non-freezing grease of the type TsIATIM-201, BAM, etc. and a protective casing, for example, of a frost-resistant composite material, predominantly polymeric. Since the roof of permafrost soils 6 near the support 1 under the action of a seasonally acting cooling device 2 and thermal insulation 3 rises and, accordingly, the depth of seasonal thawing of soil 5 decreases, the active heaving zone also decreases during winter freezing. Therefore, the anti-dam bandage 4 is applied to the part of the support buried in the ground only in the area from the bottom of the thermal insulation 3 to a depth equal to 0.4-0.6 of the depth of seasonal thawing of the soil 5.

 The technology for installing the support is as follows.

At the beginning, in the factory or on the spot, a seasonal-acting cooling device of, for example, a steam-liquid thermosiphon designed by the Foundationproject Institute is inserted into a reinforced concrete support. A non-freezing grease and a frost-resistant protective cover, mainly made of polymeric material, are applied to the part of the support buried in the ground so that the surface of the support is isolated from seasonally thawed soil in the area of its active heaving. Then the support is installed in a specially drilled well. The space around the support in the well is carefully filled with dispersed soil (preferably fine-grained sand). Then, the surface of the soil around the support in a zone with a radius not less than the depth of seasonal thawing of the soil is covered with thermal insulation from extruded foam polystyrene, for example, Penoplex-45, which has high thermal insulation properties in the temperature range from -50 to +75 ^o С - compressive strength not less than 0.45 MPa and preserving these properties after 1000 cycles of freezing and thawing. Top layer of thermal insulation is sprinkled with soil or covered with turf. The aerial part of the support, 0.5-1 m from the surface of the earth, is painted in a reflective color.

 In the case of a metal support of the contact network, consisting of a tubular metal foundation and a metal stand installed on it, the procedure is as follows. At the work site, an anti-bandage bandage is applied to the upper portion of the underground portion of the metal foundation of the support. Then, a hole of a larger diameter is drilled to the depth of the installation of the bandage than is necessary to install the foundation of the support. Further, the borehole pass with a smaller diameter, sufficient to install (for example, by screwing) a metal foundation. A foundation is then installed in the well with an applied anti-canal bandage with precautions to prevent damage to the bandage. Fill the annulus with soil with a layer-by-layer compaction. Impose a layer of thermal insulation. Insert a seasonal cooling device into the foundation. The internal space in the foundation is filled with moist soil. The upper opening of the metal foundation protects against atmospheric precipitation. Then, a metal stand is mounted on the foundation in such a way that inside it is an air heat exchanger of a seasonal cooling device. Lay a layer of thermal insulation around the foundation and cover it with a protective layer of soil or turf. The aerial part of the metal foundation, the air heat exchanger of the seasonally acting cooling device, and also, if possible, the metal pillar of the support are painted in reflective color.

 The invention has several advantages compared to the prototype. It has no restrictions on the depth of permafrost water and is more effective, since it not only reduces the effect of frost heaving of seasonal soil on the support, but also significantly increases (creates) jamming it in the permafrost, which together eliminates or drastically reduces vertical displacements and horizontal slopes of the support. When using the invention increases the reliability and service life of the supports of the contact network, erected on heaving soils and there is no need for periodic dressing and replacing them.

 The invention is intended to be used in electrification, in the repair of unstable sections of the supports of the contact network of railways in areas of permafrost and deep seasonal freezing. It can also be used in the construction and repair of overhead power lines of alarm devices, centralization and blocking and longitudinal power supply, etc.

Sources of information
1. Guidelines for securing the supports of the contact network in severe climatic and difficult geological conditions. M .: TsNIIS Transstroy USSR, 1975.

 2. High voltage. Electrification of the Trans-Baikal Railway 1982-1993. Chita, Zabtrans, 1993.

Claims (1)

 The support of the contact network, erected on heaving soils, including an anti-damper device, characterized in that it is made in the form of a complex of a seasonally acting cooling device integrated in the support, mainly in the form of a thermosiphon, a layer of thermal waterproofing and an anti-canopy bandage, and thermal waterproofing is laid on the day surface of the soil around the support and is made with a radius not less than the depth of seasonal thawing of the soil, from a frost-resistant material, preferably an extrusion foam policy tyrol is sprinkled on top with a layer of soil or turf with a thickness of 15-25 cm and has a thickness of 10-20 cm, and the anti-dam bandage is made in the form of a protective casing of frost-resistant composite material, mainly polymeric, placed around the part of the support buried in the ground adjacent to the sole of the thermal insulation layer and made with a length equal to 0.4-0.6 of the depth of seasonal thawing of the soil, and non-freezing grease between the casing and the surface of the part of the support buried in the soil, and the above-ground part of the support is 0.5-1 m from the surface The earth’s surface is painted in reflective color.