RU22158U1 - FOUNDATION FOR SUPPORTS OF CONTACT NETWORK - Google Patents

Description

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HQ: 7 E 02D 27/42

FOUNDATION FOR SUPPORTS OF CONTACT NETWORK

The proposed utility model relates to the field of construction of a contact network of electrified railways and is intended for the construction of foundations for the supports of the contact network in rock formations.

A technical solution to the prismatic foundation is known, the cross-sectional dimensions are minimal and determined by the dimensions of the support base 1.

The installation of such foundations in rocks is associated with the implementation of labor-intensive work to develop a pit: drilling wells, blasting and producing rock.

In order to reduce the time of work, the rational use of mechanisms, save labor, it was proposed for distillation cantilever supports to close the anchors of the supports directly to the rock.

The upper part of the foundation from the projected edge to the contact with the rocks is concreted in the formwork according to the size of the prismatic foundation. The minimum thickness of the concrete pillow is 15 cm. The concrete grade is 110 kg / cm.

Anchors with a diameter of 32 mm and a length of 1.0 to 2.5 m were embedded in rocks of various densities.

Some of the anchors were embedded without finishing the ends. Another group of anchors was terminated with wiring ends. To this end, the ends of the anchors to a length of 10 cm were cut by the autogenous in two very perpendicular directions. Sectors moved apart somewhat, in

An electric detonator was inserted into the resulting space and all voids were filled with ammonal. An anchor thus prepared with an electric fuse cord was lowered into a pre-drilled well with a diameter of 50 mm. Then, an electric machine explodes, as a result of which the sectors of the anchor moved apart and pressed against the walls of the well, which created the embedment of the anchors.

After installing the anchors, the squash was poured with a cement mortar with a composition of 1: 1.

The disadvantage of this foundation is that when embedding supports in rock, it is necessary to increase the depth of embedment of the anchor into fractured, slightly weathered rocks to E, 5 m, which increases the cost of the work.

In addition, in order to save iron, composite anchors were used.

When arranging the station supports of the contact network with flexible crossbars, a metal frame made of profile iron is laid in the foundation. To connect the support to the frame, 16 bolts are usually put.

 The disadvantage of this solution is that a large number of bolts are laid in the foundation. The accuracy of their location complicates the mounting of the support. Drilling and embedment of anchors in the rock showed the complexity and inefficiency of these works. It is especially difficult to maintain design distances between anchors.

Known technical solution C2, which relates to the field of construction of power lines and is intended for the construction of foundations of steel tower supports and guy wires of steel single-column or portal supports installed in rocky soils.

the foundation, including a trunk extended from top to bottom with a through vertical cavity, is additionally provided with internal and external fillings from rock rubble, and a through vertical cavity is made extended from top to bottom.

This solution provides the possibility of fixing the foundation in a cylindrical pit in rocky ground.

The disadvantage of e © is that it requires the development of a large diameter pit in rocky soil and the manufacture of a conical hollow foundation of complex construction.

The well-known foundation of single-column supports intended primarily for power lines built on rocky soils of SZZ, including plate-linked anchor rods located in holes filled with bonding material. The holes are made oblique, disjoint, approaching each other to the zone of the middle part of their lengths.

This constructive solution of the foundation makes it possible to use it in crash and collapsible soils.

Its disadvantage is that it requires the drilling of a large number of wells with strict observance of the inclination angles, which are often covered with obrushes, a trash, and a yellowish rock.

Known support frame racks for mounting metal racks to the foundations 4, including a supporting base plate with a pair of scarves placed on it, made with opposite holes and installed on the outside of the rack, the axis of which is located in the holes of the scarves.

To reduce the complexity of mounting and dismounting the rack, the base plate is equipped with an inclined plate installed between the scarves and attached to it, and the holes in the scarves are made in the form

slots, the longitudinal axis of which are parallel to the inclined plate, and the hinge is supported on the inclined plate with the possibility of movement along it. .

The closest technical solution to the claimed solution is a reinforced concrete foundation for installing contact network supports in. rocky soils C5.

The foundation includes a supporting cylindrical part installed in a foundation pit drilled in rocky soil, and an element for mounting the support on the foundation, made in the form of a rectangular head on which the support of the contact network is fixed. To fix the support to the foundation, anchor bolts are laid in it during manufacture. The foundation is reinforced with longitudinal working reinforcement and transverse spiral.

The disadvantages of the known construction of the foundation are

the following, we eat: a large mass, the need to drill a pit of large diameter (400 mm), which complicates the process of work and increases the labor costs in the manufacture, construction, dismantling and disposal.

The main task, which the utility model is aimed at, is to reduce, labor costs for manufacturing, construction. dismantling and disposal, providing the required layer, its ability and increasing durability.

To solve this problem, a foundation has been proposed for the supports of the contact network, which, like the prototype, includes a support part installed in a foundation pit drilled in rocky soil, and an element for attaching the support to the foundation.

The proposed foundation differs from the prototype in that

the supporting part is made in the form of a metal pipe, and holes for bolts for mounting the support are made in the fastening element of the support on the foundation.

The supporting part of the foundation can be made in the form of two metal pipes mounted along the direction of action of the operating loads on the foundation.

When the supporting part is made in the form of a metal pipe, the element for fixing the support on the foundation is made in the form of a head, which is a metal plate with ribs fixed on it.

When the supporting part is made in the form of two metal pipes, the element for fastening the support on the foundation is made in the form of a grillage mounted on these pipes.

All the structural elements of the foundation are coated with a hot dip galvanized coating.

The essence of the proposed utility model is that due to the implementation of the support part installed in a foundation pit drilled in rocky soil in the form of a metal pipe or two metal pipes, the foundation mass is reduced by an average of 3.5 (for single-pipe) and 2.5 (for two-pipe) times.

In addition, the implementation of the supporting part of the foundation in the form of two metal pipes installed along the line of operational loads, can increase the bearing capacity of the entire foundation.

The application of anti-corrosion coatings to all the foundation elements by hot dip galvanizing can increase its durability.

Based on the foregoing, we can conclude that the technical result achieved in the proposed utility model is to reduce labor costs for the development of excavation in rocky soils, to increase durability, reduce the cost of manufacturing, construction, dismantling and disposal of the foundation and to ensure the required bearing capacity.

The proposed utility model is illustrated by drawings.

Figure 1 - presents the foundation with a supporting part made in the form of a metal pipe; in Fig.2 is a top view; in Fig.Z - the foundation with a supporting part made in the form of two metal pipes; figure 4 is a top view.

The foundation for the supports of the contact network includes a support part 1 installed in a foundation pit drilled in rocky soil, an element 2 for attaching the support of the contact network to the foundation, on which holes 3 are made for bolts or studs for attaching the support.

When performing the supporting part 1 in the form of a metal pipe (Fig. 1), the element 2 for attaching the contact network support to the foundation is made in the form of a head, which is a metal plate with ribs 4 fixed to it.

When the supporting part 1 is made in the form of two metal pipes (FIG. 3), the element 2 for attaching the contact network support to the foundation is made in the form of a grillage mounted on metal pipes installed along the direction of action on the foundation of the operating load.

In view of the small size of the foundation, all its structural elements are coated with an anti-corrosion coating by hot dip galvanizing.

The operation of the device is as follows.

The foundation is installed in a pit drilled in rocky ground using light crane equipment, or manually, thanks to

relative lightness of construction.

Then, cement mortar is injected between the walls of the pit and the walls of the pipe 1. After the mortar has hardened, the support of the contact network is installed on the foundation and, using element 2, it is fixed to the foundation with bolts or studs.

Under external load (bending moment) the foundation works on bending and cf, ez.

The depth of the foundation should be 6-10 diameters of the supporting part 1, depending on the fracture of the soil.

Thus, the advantage of the proposed utility model is to reduce the mass of the foundation, reduce the complexity of drilling a foundation pit in rocky soil, increase the bearing capacity of the foundation and reduce labor costs in the manufacture, construction, dismantling and disposal.

SOURCES IN ROMATION

1.G.F.Nazarenko. The foundation foundations of contact network supports in rocky soils., Transport construction, N5, 1955, OS .., 18-20.

2. The author's certificate of the USSR N 633988, M class .: E 02D 27 / 42,1974.

3. The author's certificate of the USSR N 726268, M class .: E 02D 27 / 42,1973.

4. The author's certificate of the USSR N 718557, M class .: E 02D 27 / 42,1978.

5. The foundation is reinforced concrete for the installation of contact network supports in rocky soils. Project of TsNShS EL-98-7361 OJSC, prototype.

Claims (4)

1. The foundation for the supports of the contact network, including the support part installed in the excavation drilled in rocky soil and the element for attaching the support of the contact network on the foundation, characterized in that the support part is made in the form of a metal pipe, and in the element for attaching the support of the contact network holes are made on the foundation.  2. The foundation for the supports of the contact network according to claim 1, characterized in that the element for mounting the supports of the contact network on the foundation is made in the form of a head, which is a metal plate with ribs fixed to it.  3. The foundation for the supports of the contact network according to claim 1, characterized in that the support part, made in the form of a metal pipe, is supplemented with a second metal pipe, and the element for attaching the support of the contact network on the foundation is made in the form of a grillage mounted on metal pipes installed along the direction of action on the foundation of the operational load. 4. The foundation for the supports of the contact network according to claims 1 to 3, characterized in that all the structural elements of the foundation are coated with a hot dip galvanized coating.