WO2018223208A1 - Rail for a transport system - Google Patents

Abstract

The invention relates to elevated and suspended rail transport systems having a string-type track structure. A rail for a transport system comprises at least one head with a running surface. The head is adjoined to an elongate body. The body comprises a load-bearing structure formed by prestressed load-bearing elements. The rail head comprises vertically oriented strips gathered into a block. The strips are mounted on ribs either in a single groove, or in a plurality of grooves. The strips are connected to one another by interlays. The outer end faces of the strips and of the interlays form the running surface of the rail head. This provides simplified manufacture and reduced labour and material costs. Assembly of the rail under field conditions is simplified. The technical performance characteristics are stabilized throughout the entire length of the rail track as a result of an increase in the rigidity and elastic stability of the track structure.

Description

 TRANSPORT SYSTEM RAIL

 The invention relates to the field of transport, in particular to railways, related trestle and overhead transport systems with a track structure of the string type. It can be used to create both single-rail and multi-rail highways to provide passenger and freight traffic in rough terrain, mountains, deserts, as well as in megacities and on sea sections of transport lines.

 State of the art

 Known rail for low-speed sections of roads (mainly on ships - ferries), in which the rail is made in the form of a two-layer head located on the sole (Patent RU K ° 2022070, IPC ЕВВ 5/08, ЕВВ 25/00, publ. 30.10.1994 )

 The upper layer of the rail head is made by welding and surfacing of metal longitudinal strips with alternating hardness. Moreover, sections with greater hardness are located along the center line, and the total width of these sections is 1/3 of the width of the rail head.

 The disadvantages of this rail design are limitations on the smoothness and softness of the ride, not the stability of the operational properties of the contact surface of the rail head, which does not allow to develop high speeds.

 Known load-bearing rail used for overhead railways, crane tracks and similar transport systems, containing several ropes enclosed in a casing (Description of the application EPO 0137153, G 01 B 25/24, publ. 1985).

 A disadvantage of the known design is the lack of rigidity, which leads to a deflection of the rail when moving a vehicle over it.

A linear transport system is known which uses a rail containing a head, a body and a sole (Description to application EPO 0010733, E 01 At 25/00, publ. 1980). The rail is connected to a prestressed longitudinal element mounted on the base. The prestressed longitudinal element is made in the form of a pipe placed in a cement-concrete sheet on which the rails are placed, and connected to the rail sole by means of transverse partitions.

 The disadvantage of this design is the connection of the prestressed element with the rail not along the entire length of the rail (with gaps) and keeping the distance between the rail and the prestressed element constant, which leads to a variable stiffness of the rail between the joints of the rail with the prestressed longitudinal element and is the cause of the variable deflection along the rail when moving a vehicle along it. As a result, the presence of rail joints and variable deflection are a serious obstacle to creating a "velvet" path for a mobile unit and to achieve high speeds on such a transport system.

 A transport system rail is known, comprising a head and a hollow U-shaped body with at least one pre-stressed longitudinal longitudinal stacking element inside, the lower edges of the body being provided with outward thickenings, the cross-sectional area of which is selected from certain conditions (Patent RU JY ° 2201482, E01 B 5/08, E01 B 25/00, publ. 03/27/2003).

 The disadvantages of the rail of the given design are its limited torsional rigidity and bearing capacity with equal values of such other operational characteristics of the structure as its weight and cost. In addition, the high complexity of installation and the lack of manufacturability of the design limit the widespread use of such a rail.

A rail of the Unitsky transport system is also known, comprising a hollow body in the form of side walls and an upper shelf with a prestressed longitudinal stacking element placed inside it, equipped with means installed along its length for clamping it to the upper shelf, the distance between the pressure points of the longitudinal stacking element to the upper shelf of the rail housing is selected from the above ratio (Patent RU JY ° 2208675, E 01 B 25/00, publ. 20.07.2003 )

 The disadvantages of this rail are also its limited torsional rigidity and bearing capacity with equal values of such other operational characteristics of the structure as its weight and cost. In addition, the high complexity of installation and the lack of manufacturability of the design limit the widespread use of such a rail.

 The Unitsky transport system rail is known, comprising a hollow tube-shaped body with an overhead head, inside of which there is a power element made of prestressed power elements, mainly wires and / or rods, in which the body is made in the form of a spiral covering the power element, and the overhead head is fixed on the turns spirals (Patent RU 2204639, Е0 1 В 5/08, Е01 В 25/00, В61 В 3/02, В61В 5/00, В61 В 13/04, publ. 05.20.2003).

 Due to this, the power elements pulled together in a tight package by a spiral casing acquire the properties of a monolithic beam, i.e. each elementary segment of the power organ under working loading works like a monolithic beam, although the rail lash retains flexibility. This helps to improve the strength properties of the rail and its bearing capacity with reduced material consumption.

 The disadvantage of such a known rail is the relatively low stiffness achieved by it with the imposed restriction of mass and size characteristics.

The closest to the claimed technical essence and the achieved result is the rail of the Unitsky transport system (Patent RU JY <> 2080268, IPC B61 B 5/02, E01 B 25/22 publ. 05/27/1997), which is adopted as a prototype. The known rail comprises a hollow tubular body, an overhead made in the form of dialed into a block tapes. A power element is placed inside the hollow body, made in the form of pre-stressed longitudinal type-setting force elements installed in a special holder below the rail head. The type-setting element is made of wires placed parallel to each other with a cross-section of arbitrary shape - square, round, rectangular, hexagonal, etc. or plates. The rail head is connected to a prestressed longitudinal element, and the tapes in the block are mounted on the ribs.

 A rail of this design, designed to create highways, allows you to build transport systems close to trestle that do not require the creation of a traditional crushed stone pillow and sleepers. Thanks to this, a significant reduction in labor costs and material resources is provided.

 The rail of this embodiment provides a high specific load-bearing ability and low material consumption, due to which the necessary straightness of the path is achieved, which in turn provides high speeds.

 However, for the manufacture of rails of this design, stationary conditions are necessary, as well as components, the cost of which during mass production remains still substantially high. The components of this kind include, first of all, steel pipes used for the manufacture of the rail body. Their presence in the construction determines the need for stationary equipment and stationary conditions for the assembly of rails.

In addition, the disadvantages of the rail of this design are: its lack of adaptability, due to the complexity of installation and low maintainability; low bearing capacity of the rail, without prejudice to its strength, torsional stiffness and stability, due to the limited area of the supporting surface; relatively high cost due to insufficient unification of components, material consumption and a significant range of elements used in its design; non-uniform dynamic characteristics, low and unstable operational parameters of the contact surface of the rail head, due to a significant change in the uniformity of the composition of the contact spot along the rolling surface, including those caused by wear of the contact surface during operation.

 The basis of the invention is the task of achieving the following technical goals and advantages:

 - simplification of manufacturing and reducing the complexity of rail installation when performing work in the field;

 - stabilization of operational and technical parameters along the entire track by increasing the stiffness, elastic stability (monolithic) of the track structure, its reliability and evenness of the rail;

 - reduction in cost and material consumption.

Disclosure of invention

 The solution to this problem is provided by the entire set of distinctive features of the rail construction.

 The necessary technical results and the goals set in accordance with the object of the invention are achieved in the proposed rail design of the transport system, which contains at least one rail head with a rolling surface conjugated with an extended casing, and combined with the power structure formed by prestressed power elements, the space between which are filled with hardening material, while the rail head contains vertically oriented strips of thickness S, m, distributed and akreplonnye in a plurality of grooves formed between a pitch W, m, defined by:

1.1 <W / S <3. The solution to this problem is also provided provided that the vertically oriented stripes are made in the form of a block built into a single groove with a width of Wi, m, determined by the dependence:

 5 <Wi / S <100.

 The achievement of the technical goal is also ensured by the fact that the bands are interconnected by interlayers of thickness Si, m, determined by the dependence:

 0.01 <Si / S <2.

 The solution to this problem is achieved provided that many grooves or a single groove are made along the body to a depth of Hi, m, interconnected with the height of the block But, m, by the dependence:

 0.2 <Ηι / Ηο <1.

 The indicated result is also achieved by the fact that the strips or block of strips are fixed, respectively, in a plurality of grooves or in a single groove with an adhesive layer.

The solution to this problem is also provided provided that the thickness S, m, strip is connected with the thickness S ₂ , m, of the adhesive layer by the ratio:

0,2 <S ₂ / S <1.

The solution of this problem is provided provided that the ratio of the elastic moduli Ei, Pa, strip material and E ₂ , Pa, the adhesive layer material is determined by the dependence:

100 <Ει / Ε ₂ <10000.

 The achievement of the technical goal is also ensured by the fact that a single groove or each of the many grooves is made in cross section in the form of an isosceles or rectangular trapezoid.

 The solution to this problem is also provided provided that the strips are made at least two-layer.

The indicated result is also achieved by the fact that the strips are interconnected by resistance welding, or by soldering, or by an adhesive layer. The achievement of the technical goal is also ensured by the fact that the strips are connected to each other via interlayers.

 The specified result is also achieved by the fact that the housing contains at least two rolling surfaces.

 The achievement of the technical goal is ensured by the fact that the rolling surface is formed by the external end faces of the strips and interlayers.

 The solution of this problem is also achieved by the fact that hardening material based on polymer binders, composites and / or cement mixtures with filler additives is used as interlayers. It is advisable to use electrically conductive materials, for example, graphite, as filler additives.

 The achievement of the technical goal is also ensured by the fact that antifriction materials are used as filler additives.

 It is advisable to use friction materials as filler additives.

 It is advisable to use composite materials as filler additives.

 The solution to this problem is also provided provided that at least one layer and / or strip is made with the possibility of connecting to a source of electricity.

 It is advisable to interlayers and / or strips related to different rolling surfaces to connect to different poles of the source of electricity.

 The solution to this problem is provided provided that the casing is made of dielectric material.

 Brief Description of the Drawings

 The essence of the present invention is illustrated using the drawings of Fig.1 - Fig. 5, which depict the following:

figure 1 is a schematic representation of a cross section of a rail (embodiment); figure 2 is a fragment of a schematic image of a cross section of a rail head (embodiment);

 fig.Z is a fragment of a schematic image of a cross section of a rail head (embodiment);

 4 is a fragment of a schematic image of a cross section of a rail head (embodiment).

Embodiments of the invention

 The invention is described in more detail as follows. The proposed rail transport system Unitsky (figure 1) contains at least one head 1 (1.1 and / or 1.2) with a rolling surface 2 (2.1 and / or 2.2, respectively) associated with an extended body 3 containing a power structure 4 formed by prestressed power elements 5, the space between which is filled with hardening material 6.

 As the power structure 4, the cross-section of which is schematically shown in figure 1, use prestressed power elements 5, made, for example, in the form of twisted and / or non-twisted ropes, cables, tapes, strips, threads, strands, reinforcement, high strength steel wire, pipes or other extended elements from any high-strength materials.

 As the hardening material 6, known materials can be used - polymers and composites, or cement mixtures, including: foamed polymers, foam concrete, ceramics, concrete, etc., which are rigidly bonded into a single housing 3 and previously placed in it stressed power elements 5 (see Fig. 1).

 When this occurs, the monolithic power structure 4 of the housing 3 of the rail.

Rail fastening devices on anchor and intermediate supports (not shown in the figures) are any known devices, similar to devices used in suspension and cable-stayed bridges, cableways and prestressed reinforced concrete structures for fastening (anchoring) of tensioned power elements (reinforcement, ropes, high-strength wires, etc.).

 The rail head 1 consists of vertically oriented strips 7 assembled in a block, mounted on ribs in a single groove 10, or distributed in a plurality of grooves 10 and connected to each other by means of interlayers 8, and the block and strips 7 are fixed with an adhesive layer 9, respectively, in a single a longitudinal groove 10, or in a plurality of grooves 10 of the housing 3, as shown in FIG. 2 to 4.

 In this case, the external end faces of the strips 7 and the interlayers 8 of the head 1 of the housing 3, respectively 2 A and 2B, define a single contact surface of the rail head 1 — the rolling surface 2 (see Fig. 2-4).

 To achieve the required stiffness and bearing capacity of the head 1 of the rail body 3, it is necessary to ensure that a number of its structural characteristics depend on the design parameters and technical feasibility.

 In particular, the thickness S, m, of the strip is connected with the step W, m, between the multiple grooves 10 in which they are distributed (see Figs. 3 and 4), by the ratio:

 1.1 <W / S <3 (1)

 If the ratio (1) is less than 1.1, then, due to the insufficient thickness and strength of the walls of the many grooves 10, it is difficult to ensure their mechanical strength, as well as the rigidity and reliability of the fastening of the strips 7 of the head unit 1 in the rail body 3.

If relation (1) is greater than 3, then the rolling surface 2 of the rail may experience a pressure exceeding the elastic limits of the materials of the block of the rail head 1, which can cause its premature wear and reduced driving safety. As a result, such a transport system will have insufficient rigidity, strength and bearing capacity.

 At the same time, the thickness S, m, of the strips combined in a block, built into a single groove with a width of Wi, m, (see Fig. 2) is determined by the dependence:

 5 <W! / S <100 (2)

 If the ratio (2) is less than 5, then the rolling surface 2 of the rail will experience a pressure exceeding the elastic limits of the materials of the block of the head 1 of the rail, which can cause the rolling of the rail and reduce the safety of movement.

 If the ratio (2) is more than 100, it is difficult to provide mechanical strength and rigidity of the adhesive layer 9 of the block of strips 7 of the head 1 in the housing 3 of the rail.

 To improve the fixation of the block of strips 7 in a single longitudinal groove or strips 7 in the multiple grooves 10 of the casing 3 and increase the bearing capacity of the rail, it is advisable to increase the bearing surface of the rail head 1.

 The dimensions of a single groove 10, or a plurality of grooves 10, are selected in such a way that the inequality is satisfied for the ratio of their depth Hi, m, to the height Ho, m, of the strips 7 (see Fig. 2-4):

 0.2 <Ηι / Ηο <1 (3)

 When performing depth Hi, m, a single groove 10 or multiple grooves 10 and height Ho, m, bands 7 with values corresponding to relation (3), it is possible to simply provide the required strength of fixation of the block of strips 7 in the rail body 3 and the necessary rigidity of its head 1 with minimal material consumption and high manufacturability.

 If the ratio (3) is less than 0.2, then the transverse rigidity and stability of the rail head 1 is unacceptably reduced, which entails a decrease in the bearing capacity of the transport system.

If ratio (3) is greater than 1, then the operational parameters of the transport system deteriorate, in particular, the coefficient increases friction of the rolling surface 2, which entails a decrease in speed and smoothness of movement with increasing energy costs.

 Along with this, it is advisable to fix strips 7 or the block assembled from them, respectively, in a plurality of grooves or in a single groove of the casing 3 with an adhesive layer 9, which makes it possible to increase the manufacturability of the rail structure, simplify its manufacturing process, reduce the complexity of installation work in the field, and ensure the smoothness and softness of the movement of vehicles (not shown in the figures) throughout the rail track.

 In this regard, the thickness S, m, strip 7 should be associated with the thickness

S2, m, adhesive layer 9 (see Fig. 2) by the ratio:

0.2 <S ₂ / S <1 (4)

When performing thickness S, m, strips 7 and thickness S ₂ , m, adhesive layer 9 with values corresponding to relation (4), it is possible to simply provide the required adhesion of the head 1 to the housing 3, their increased damping properties while maintaining the solidity and strength of the rail (see Figs. 2-4).

 If the ratio (4) is less than 0.2, then the adhesive layer 9 will have an uneven and unstable contact area with the side surface of the strips 7, or, the block as a whole, drawn from the strips (see Fig. 2), and, as a result, the fastening of the strips, or of the block assembled from them, respectively, in a plurality of grooves 10 or in a single groove 10 of the housing 3 with such an adhesive layer 9 will not be strong enough and will not be able to provide a damping effect for the rail head, as well as the required solidity and fixation of the head 1 in case 3.

If relation (4) is greater than 1, then such a rail will have insufficient bearing capacity, hardness, rigidity and strength, limited by the corresponding parameters of the adhesive layer 9, the influence of which, in this case, increases significantly. Due to the fact that the rail head 1 is exposed to a significant part of such unfavorable external factors as braking and accelerating forces from vehicles, cyclic loads, temperature fluctuations, atmospheric effects and others (not shown in the figures), it is obviously advisable to provide an optimal combination of high the hardness and rigidity of the strips 7 with the ductility and elasticity of the interlayers 8 and the binding and damping properties of the adhesive layer 9.

The ratio of the elastic moduli Ei, Pa, the material of the bands 7 and E ₂ , Pa, the material of the adhesive layer 9 is determined by the dependence:

100 <Ei / E ₂ <10000 (5)

 The limits indicated in relation (5) determine the optimal range of elastic moduli of the materials of the strips 7 and the adhesive layer 9, which provides the necessary rigidity and strength of the rail head 1, and, consequently, its bearing capacity in the spans between the supports with the minimum material consumption of the structure.

 If relation (5) is less than 100, then the rail head 1, having significant rigidity, will not be plastic enough to damp external dynamic loads and evenly redistribute them to the entire rail structure, which can cause the formation of local cracks, shells and premature rail wear, in particular in areas of braking.

 If the ratio (5) is more than 10000, then such a rail, with high ductility, will have insufficient rigidity and, therefore, low bearing capacity.

A single groove 10 or a plurality of grooves 10 in the housing 3 can be made as a rectangular cross-section (see Fig. 2), and in the form of an isosceles (see Fig. 3 and 4) or a rectangular trapezoid (not shown in the figures). In the case of grooves 10 of a trapezoidal shape, additional fixation of the strips 7, or the block as a whole, of the head 1 in the housing 3 is achieved rail due to their transverse compression when jammed in a single curly groove or in a variety of trapezoidal grooves of the material of the body 3.

 It is advisable strip 7 to perform at least two-layer (see Fig. 2). This will increase the manufacturability of the structure and the rigidity of the rail, and, as a result, increase its bearing capacity.

 In accordance with any of the unlimited options for connecting the strips 7 to each other, they can be connected, for example, by resistance welding, soldering or an adhesive layer.

 An alternative type of execution of the rail head 1 is the union of strips 7 by means of strips 7 made across the width of strips 7, which can be used as hardening materials based on polymer binder composites and / or cement mixtures, which leads to a simplification of manufacturing technology and reduction of installation labor costs rail when performing work in the field.

 In addition, instead of vertically oriented strips, the rail head can also be assembled from tapes made of any high-strength materials and / or, if the requirements are determined by technical and economic feasibility, from their various combinations.

 At the same time, strips 7 are interconnected by interlayers 8, the thickness of Si, m, of which (see Fig. 2-4) is determined by the dependence:

 0.01 <Si / S <2 (6)

 If the ratio (6) is less than 0.01, then the lateral surface of the strip 7 will have an uneven and unstable contact area with the interlayers 8, and, as a result, the head 1 will have insufficient solidity and mechanical strength.

 If relation (6) is greater than 2, then head 1 will have insufficient hardness and rigidity of the rolling surface 2 of the rail.

The strips 7 of the head 1 of the rail body 3 and the body 3 itself can be pre-tensioned in the longitudinal direction. With this strip 7 fixed in a prestressed state with the help of interlayers 8 and an adhesive layer 9.

 Forming the rail head 1 in this way creates its monolithic structure with improved operational properties, including increased load-bearing capacity.

 The hardening material 6 for filling part of the cavity of the housing 3, free from the volume of prestressed power elements 5 and the material of the interlayer 8 for filling part of the volume of the head 1, free from the volume of strips 7, can be of the same type and have the same composition, or can be different types and / or have a different composition depending on the design parameters and technical feasibility.

 In particular, strips 7 can be connected to each other via interlayers 8, which can be used as hardening materials based on polymer binders, composites and / or cement mixtures and other various similar similar modifications of materials, which, together with strips 7, form a monolithic rail head 1 with predetermined rolling surface properties 2.

 In accordance with any of the unlimited embodiments of the interlayers 8 and the use for their formation of various hardening materials based on polymer binders, composites and / or cement mixtures, it is advisable to use a suspension of hardening material with filler additives as such.

 Antifriction materials can be used as filler additives. In this case, an increase in the efficiency of the rail of the Unitsky transport system on hauls is achieved by reducing the coefficient of friction of the rolling surface 2, preventing wear, reducing energy consumption, improving the smoothness and softness of the vehicle.

It is advisable to use friction materials as filler additives, for example, corundum, silica sand, cement, etc. As a result, the efficiency of such a rail increases significantly in acceleration and deceleration zones, as well as on ascents and descents, which, in turn, ensures acceleration, deceleration, reduction of energy costs, and increases the smoothness and softness of vehicles.

 It is advisable to use composite materials as filler additives. This will significantly increase the range of specific strength of the rail head, as well as increase its rigidity, wear resistance and fatigue strength under cyclic loads, which have the most negative impact on the rail head 1.

 At least one layer 8 or strip 7 is expediently made of an electrically conductive material with the possibility of connecting to an external source of electric power 1 1 (see Fig. 1).

 It is advisable to use electrically conductive materials, for example graphite, as filler additives. In this case, an additional decrease in the coefficient of friction between the wheels of the vehicle (not shown in the figures) and the rolling surface 2 is provided, as well as the stabilization of the electrical parameters of the head 1 of the rail of the transport system along its entire length.

 The specified design of the head 1 of the housing 3 of the rail provides an increase in the smoothness and softness of the vehicle (not shown in the figures), as well as the stability of operational parameters along the entire rail track, which, in turn, allows you to develop high speeds.

In turn, the implementation of the rail in this way ensures the transfer and redistribution of high contact stresses from the wheels of the vehicle (not shown in the figures) to all its prestressed elements, which greatly increases the bearing capacity and bending stiffness of the rail body 3. It is advisable to provide the housing with at least two rolling surfaces 2, respectively 2.1 and 2.2 (see Fig. 1). This will increase the stability and balancing of the vehicle (not shown in the figures), which, in turn, will increase the rigidity of the transport system, its reliability, safety, smoothness and softness of movement.

 An alternative type of rail execution is to supply its body 3 with two symmetrically located heads 1.1 and 1.2, respectively. Moreover, the head 1.2 is performed similarly to the first one and is positioned, as shown, in FIG. one.

 The corresponding rolling surfaces 2.1 and 2.2 formed by the heads 1.1 and 1.2 are expediently made with the possibility of connecting the interlayers 8 and / or bands 7 forming them related to different rolling surfaces 2.1 or 2.2, respectively, to different poles 1 1 (+) or 1 1 (- ) source of electricity (see Fig. 1).

 The housing 3 is preferably made of a dielectric material, for example, fiberglass, steam - aramid fiber (Kevlar), etc.

 The assembled rail is placed between the anchor supports (not shown in the figures) of the mounted transport system, and its power structure 4, and, if necessary, the strips 7 of the head 1 of the rail body 3 and the body 3 itself, before they are monochromatic, are pulled with anchors to the rated forces , after which they are fixed in a pre-stressed state using hardening material 6, interlayers 8 and adhesive layer 9, respectively.

 Industrial applicability

 Rail transport system Unitsky described design works as follows.

When a wheeled vehicle moves (not shown in the figures) along the rail, a zone of local deformation of the rolling surface 2 of the rail head 1 is formed under each of its wheels. This zone, in the form of a deformation wave, moves with the wheel along the surface rolling 2 of the rail head 1 formed by the end surfaces 2A of the strips 7 of the rail head 1, as well as the end surfaces 2B of the interlayers 8 connecting them together.

 From the outer to the inner surface of the rail head 1, the deformation zone extends through a pre-stressed block of strips 7, in which the strips 7 are connected, for example, by the hardening material of the interlayers 8, and then through the casing 3, to the pre-stressed power element 5, monolithic in the casing 3 hardening material 6.

 Due to such a transformation of large local pressures from the wheels of the vehicle (not shown in the figures), the structural elements of the rail do not experience transcendental pressures and, therefore, the bearing capacity of the Unitsky transport system rail remains constant over time.

 The implementation of the strips and / or tapes 7 of the head 1 and the material of the rail casing 3 itself pre-stressed can significantly reduce material consumption and improve the operational characteristics of the transport system as a whole, as well as achieve stable straightness and evenness of the rail along its entire length.

 The implementation of the rolling surface 2 of alternating sections having different mechanical properties (hardness, ductility, coefficients of friction and elasticity), allows to obtain a developed contact surface of the rolling surface 2 of the rail head 1 with predetermined operational properties for different sections of the Unitsky transport system.

The result is an improvement in the operational properties of the rolling surface 2 by preventing the rolling of the rail. Thanks to the optimization of the coefficient of friction in various parts of the transport system, improvement of the parameters of movement during acceleration, braking, on ascents, descents is achieved; expanding the functionality of this system by increasing the angles of ascent, descent; acceleration, braking time reduction; reduction in energy costs; ensuring the smoothness and softness of the movement of mobile vehicles.

 The rail of the described construction, due to its strength properties and simplified construction of the hull, as well as lower cost of components for its manufacture, can significantly reduce the cost of production, as well as the total cost of building a transport system. This, in turn, allows you to speed up the process of its construction. In addition, it becomes possible to assemble the rail in the field when using equipment delivered directly to the installation site of the transport system. At the same time, component materials (wire, strip or tape) can be delivered to the installation site of the transport system in a compact form - in the form of rolls, which also helps to reduce transport costs and the total cost.

 The rail of the Unitsky transport system of the described design allows you to create a string-type transport system with a high load capacity with predetermined enhanced performance characteristics along its entire length.

Claims

CLAIM

1. The rail of the transport system, which contains at least one rail head with a rolling surface conjugated with an extended body, and combined with a power structure formed by prestressed force elements, the space between which is filled with hardening material, while the rail head contains vertically oriented stripes of thickness S, m, distributed and fixed in a variety of grooves made between each other with a step W, m, determined by the dependence:

 1.1 <W / S <3,

or made in the form of a block of strips embedded in a single groove with a width of Wi, m, determined by the dependence:

moreover, the bands are interconnected by interlayers of thickness Si, m, determined by the dependence:

and many grooves or a single groove are made along the body to a depth of Hi, m, interconnected with the height of the block But, m, by the dependence:

 0.2 <H, / But <1.

2. The rail according to claim 1, characterized in that the strip or block of strips are fixed, respectively, in a plurality of grooves or in a single groove with an adhesive layer.

3. Pearlitic rail according to any one of claims 1 and 2, characterized in that the thickness S, m, strip S is connected with the thickness of ₂ m, the adhesive layer by the relation:

0.2 <S ₂ / S <1.

 4. Rail according to any one of squares 1 and 2, characterized in that the ratio of the elastic moduli Ei, Pa, strip material and Er, Pa, adhesive layer material is determined by the dependence:

100 <Έ _λ ΙΈ ₂ <10000.

5. The rail according to claim 1, characterized in that the single groove or each of the multiple grooves is made in cross section in the form of an isosceles or rectangular trapezoid.

 6. The rail according to claim 1, characterized in that the strips are connected to each other by means of interlayers.

 7. The rail according to claim 6, characterized in that hardening material based on polymer binders, composites and / or cement mixtures with filler additives is used as interlayers.

 8. The rail according to claim 6, characterized in that at least one layer and / or strip is made with the possibility of connecting to a source of electricity.