EP1783275A1 - A floating slab track bed - Google Patents

Abstract

The invention relates to a track superstructure of the railway, which consists of elastically mounted track plates and spring elements. This invention overcomes the disadvantages of existing rubber-supported track plate medium and low insulation and complex design, and meet the demand for medium and high insulation. The invention is characterized not only by simpler designs, but also higher driving stability, and higher ride comfort and higher driving safety.

Description

Technical part

The invention relates to railroad track / track construction, and more particularly relates to a track / Schienenoberoberbauform the railway. The invention can be used in railways, subways, trams, elevated railways and high speed railways.

State of the art

Traditional railway or urban rail traffic can cause strong vibration and noise in adjoining buildings when the road / track is near the buildings. The vibration and the noise are mainly caused by the unevenness and the relative movement of the wheel-rail system, on the one hand, the noise can be directly transmitted through air into the buildings (the so-called airborne sound), on the other hand, the vibration on the rail, the track plate, Introduce the tunnel wall and the ground or over the rail, the track plate, the bridge, the pier and the ground in the building. This causes the remaining low-frequency stimuli low-frequency vibration in the floor and ceilings, the remaining high-frequency excitations caused high-frequency vibration in the walls, floors and ceilings of buildings and radiating structure-borne noise in the room, s.g. secondary sound. This vibration and the noise has a negative impact on humans.

Due to the above knowledge different measures for vibration isolation and noise reduction have been developed worldwide, eg. As noise barriers against direct airborne sound and various elastic rail fastening technology and track plates against vibration and the secondary structure-borne noise, from them the so-called Cologne egg and the short socket with rubber mount are well known.

The Kölner Ei and the short socket with rubber surround can fulfill the requirement of a low insulation effect of 5-8 dB (insertion insulation values). However, the Cologne egg has a small horizontal stiffness, so it is not suitable for the curved route. With poor production technology or bad material, the rubber ring may drop, so driving safety is affected. The rubber-base short socket can be affected by water and dust, and it is not easy to check, repair and replace.

The rubber-mounted track plates can meet the requirement of the average insulation 8-15 dB. Normally, they consist of track plates and rubber elements or rubber elements made of steel-rubber layers. The track plates are usually prefabricated in reinforced concrete, and they are relatively short. The rubber-mounted track plates have the following disadvantages: the stiffness of the rubber elements or rubber elements of multiple steel-rubber layers are directional and they influence each other; the horizontal stiffness is too small to meet the horizontal stability of the track plate, therefore, rubber elements are required for horizontal support in addition to the rubber elements for vertical support, which complicates the construction of the track system; the rubber elements are hidden under the track plate, and they are difficult to adjust, repair and replace, especially they can not be repaired from the top or side of the track plate; the track plates are relatively short and have high resonance tendency; the rubber itself has only low damping, so the kinetic energy of the vibration of track plates is not absorbed, therefore, the track plates and the vehicles vibrate more than on other track, the airborne noise in the car is greater, further, the wheel-rail wear is stronger; the rubber quality and processing requirements are higher, rubber aging is easy and it has limited life; When replacing the rubber elements, the operation of the rail system is interrupted and thus disturbs the public transport very strong.

A high requirement for the insulating effect, i. if the insulation effect should be from 15-40 dB, the rubber-mounted track plates can not technically realize or from an economic vantage point, this is not worthwhile.

task

In order to avoid the above-mentioned disadvantages and to meet the demand for the high insulating effect, the present invention provides a new glazing plate system.

The track plate system of the present invention is composed of track plate and spring members, and the track plate is elastically supported on spring members.

The pre-written spring element consists essentially of spring and spring housing. The spring and the spring housing are assembled as an assembly, so that the transport, assembly and connection with the track plate is simplified. The spring may be a coil spring, a plate spring or rubber-metal composite spring. The spring is highly elastic and can be designed in a wide range of elasticity. The horizontal stiffness of the spring can be determined by the horizontal driving stability of the track plate, so an additional horizontal support is not necessary, and the structure of the system is easy. As a result, the spring element of rubber elements or rubber elements differs from several steel-rubber layers in rubber spring mounted track plates.

In order to increase the damping of the track plate and avoid resonance, and to reduce the vibration and the noise of the track plate, a damping element or a damping structure is provided in the track plate.

A separate damping element on the track plate needs additional space and attachment. To save this space and to simplify the structure, the damping can be integrated into the spring element, there are two options. first, the spring housing of the spring element is sealed, liquid damping material is filled in the housing, and the lower part of the spring is immersed in the damping fluid; second, at least on a part of the spring surface, the limiting damping is attached, or at least a part of the spring is inserted in solid damping material.

With regard to the relative position between the spring elements and the track plate, there are two types: first, the spring elements are located under the track plate in a lateral position, which is the so-called "lateral structure"; secondly, the spring elements are in an opening on the track plate, on the inner side of the opening support stops are constructed, and the track plate is supported by the support stops on the spring elements, that is the so-called "internal structure".

The support stop may be a reinforced concrete structure in the opening of the track plate or a steel part embedded in the reinforced concrete. It is also possible that a connecting sleeve is inserted into the opening of the track plate, and on the wall of the connecting sleeve of the support stopper is provided. The support stop can first be welded together with the connection sleeve, then the connection sleeve has been concreted into the track plate. The support stop can also be a whole stop ring.

In order to lift the track plate from above and to adjust the height and inclination of the track plate, the lift-up stop is mounted in the prefabricated hole of the track plate or on the inner wall of the coupling sleeve. Washers are placed between the spring element and the support stop and there is a lift hole in the center of the washer. By adjusting the overall height of the washers, the height and inclination of the track plate can be adjusted. The lifting stop can also be a whole stop ring.

The washer has a simple structure, high strength and high reliability, and it can transmit great power, but it is not infinitely adjustable. The invention therefore additionally provides a stepless Adjustment mechanism, so an adjusting bolt and an adjusting plate are installed between spring element and support stop, then the track plate is supported by support stop, adjusting plate and adjusting screw on spring element. There are two types of structure, the "upper nut shape" and "the lower nut shape": the "upper nut shape" means that the thread is provided on the adjustment plate or the nut is attached; "the lower nut shape" means that the thread is provided on the spring element or the nut is attached.

The support stop member or the lifting stop member forms an inner contour which is similar to the outer contour of the supporting cover plate of the spring element and the outer contour of the washer and the adjusting plate, and the outer contours fit into the inner contours and axially pass, and the supporting cover plate of the spring element as well as the washer and the adjustment plate can be arranged twisted below the support stop after passing through the inner contour of the support stop and the lifting stop.

The track plate may be in the form of a plate, a frame or a ladder, and the spring elements are approximately regularly laterally below the track plate.

The length of the track plate is normally 10-60 m, usually cast or prefabricated in reinforced concrete, but it can also be composed of reinforced concrete and steel structure. If the track plate is prefabricated, a long plate can be connected from several small plates in the long direction. The head side of the small plates is a rough surface or concavo-convex surface, and damping material, elastic material or concrete is filled and connected between the small plates. The concave-convex joining between small plates can be in longitudinal section or top view even in both sections.

An even longer elastically mounted roadway may consist of several track plates. In order to ensure the thermal expansion and the cold shrinkage of the track plate, a joint clearance between the adjacent track plates should be kept. The adjacent plates are connected by transverse force coupling, so that the plates can be loaded more uniformly in the vertical and horizontal directions. The lateral force coupling consists of connecting rod and sliding sleeve. The connecting rod and the sliding sleeve form a sliding guide in the axial direction, but they are limited to each other in the radial direction. The connecting rod and the sliding sleeve are respectively fixed or embedded in the adjacent track plates.

In order to ensure the smooth transition between an elastically mounted track plate and an adjacent track plate (eg, fixed track), the relative to a unit length rigidity should at least the vertical direction of the plate gradually transferred to the rigidity of the adjacent plate. For this purpose, the spring elements with the same stiffness should be arranged at different distances (eg, always denser), or the spring elements with different rigidity (eg, always stiffer) should be uniformly arranged.

In order to prevent the horizontal displacement of the spring element against the base, a connection mechanism is constructed on the upper and lower surfaces of the spring element, with which the spring element is coupled to the top track plate and bottom base plate. The connection mechanism may be an anti-slip plate, a screw connection or a concavo-convex structure.

Due to the structural dynamics and the theory of vibration isolation, when an elastic element is used in a system, the natural frequency of the system decreases, so that the exciter frequencies that are above 1.4 times the natural frequency, can be isolated. The greater the quotient of the excitation frequency to the natural frequency of the system, the better the insulating effect of the excitation oscillation. Without vibration, the structure-borne noise can not be generated. The damping can restrain the resonant vibration of the system and the structure so that the system can stabilize quickly after excitation. The lower the natural frequency of the system, the better the insulating effect, the mass of the system should be large, and the elasticity of the spring should be high. However, in practice, the mass of the system and the spring's elasticity should be kept within a limited range, and they should not be too large or too small. For the lower rail mat, the Kölner Ei and the short base with rubber mount, the oscillating mass of rail and wheel is determined, so only the bearing elasticity can be increased. However, if the bearing elasticity is too large, the rail will again be deformed too much. The horizontal stiffness is also small, so that the driving safety is impaired. For today's rubber-mounted track plate, the vertical rigidity, the horizontal stiffness and the mass are coupled, so it is not possible to design a simple and inexpensive system that meets the medium and high demands on insulation.

In the present invention, a spring member is used, and the track plate has good elasticity and stability in all directions, so additional support in the transverse direction is not necessary, therefore, the structure becomes simple. The spring element can be adjusted from top or side of the track plate, repaired and replaced, so it is easily accessible. The length of the track plate can be designed according to the requirement, so that the resonance frequency can be avoided. Damping mechanisms can be inserted into the track plate to increase the structural damping of the track plate and prevent the vibration and noise of the track plate. When a damping element is incorporated into the track plate or damping structure is integrated in the spring element, the vibration energy of the track plate can be absorbed, so the stability of the track plate, the driving safety and seismic safety can be improved. The Spring is highly elastic and can be designed in a wide range of elasticity, so it is possible to design a simple system that corresponds to the average insulating effect and replaces the rubber elastically mounted plate. It has therefore become possible to design a track plate with high insulation (15-40dB transfer loss).

Explanation of the pictures

• Figure 1 is a sketch of the structure of an embodiment 1 of the invention;
• Figure 2 is a cross section of Figure 1;
• Figure 3 is an enlarged sketch of part of Figure 2;
• Figure 4 is a plan view of Figure 3;
• Figure 5 is a sketch of the structure of Embodiment 2 of the invention;
• Figure 6 is a cross section of Figure 5;
• Figure 7 is an enlarged sketch of the A-A longitudinal section of Figure 5;
• Fig. 8 is a sketch of the structure of Embodiment 3 of the invention;
• Figure 9 is a cross-section of Figure 8;
• Figure 10 is a first enlarged sketch of part of Figure 9;
• Figure 11 is a second enlarged sketch of part of Figure 9;
• Figure 12 is a sketch of the structure of Embodiment 4 of the invention;
• Figure 13 is part of the cross section of Figure 12;
• Figure 14 is a sketch of the structure of Embodiment 5 of the invention;
• Figure 15 is an A-AA elevational view of Figure 14;
• Fig. 16 is a sketch of the structure of Embodiment 6 of the invention;
• Fig. 17 is a plan view of Fig. 16;
• Figure 18 is a sketch of the structure of Embodiment 7 of the invention;
• Fig. 19 is a plan view of Fig. 18;
• Fig. 20 is a sketch of the structure of Embodiment 8 of the invention;
• Figure 21 is a longitudinal section of Figure 20.

1 track plate, 1a plate-shaped, 1b convex, 1c ladder-shaped, 1d frame-shaped; 2 spring element; 3 connecting sleeve, 3a lifting stop; 4 support stop; 5 Spring housing, 5a top plate, 5b bottom plate, 5c sealing collar, 5d anti-slip plate; 6 spring, 6a screw / coil spring, 6b plate spring, 6c rubber and metal composite spring or rubber-metal composite spring; 7 damping, 7a fluid damping, 7b solid / solid damping, 7c damping core, 7d restraint damping sleeve; 8 washer; 9 adjusting screw, 9a bolt, 9b adjusting plate; 10 limitation / limiting attenuation; 11 cross connection bar; 12 lateral force coupling, 12a connecting rod, 12b sliding sleeve, 12c substructure; 13 metal plate; 14 gum; 15 anchor bolt; 16 rail.

application method Embodiment 1

As shown in Figure 1, Figure 2, Figure 3 and Figure 4, the plate-shaped track plate 1a is cast in place. Two rows of openings are located on the outer sides of the rails in the track plate. In the openings connecting sleeves 3 are embedded, and on the inner wall of the connecting sleeve of the support stops 4 is welded. The track plate 1 a is elastically supported by the support stop 4 on the spring elements 2, so "the inner-type track plate" is constructed.

Figure 3 shows the internal structure of connecting sleeve 3 and spring element 2, consists of coil spring 6a and spring housing 5. The spring housing 5 consists of upper and lower spring sleeve, in the upper sleeve, a top plate 5a is set to transmit the spring force, and in the lower Sleeve is but a lower plate 5b set up. The two sleeves are welded from steel and sealed and connected by a flexible sealing collar 5c. In the lower spring sleeve liquid damping 7a is filled, and here high viscosity methyl silicone oil is used. The coil spring 6a is fixed in the spring sleeve, and the lower part of the spring is immersed in damping fluid 7a. In order to prevent the horizontal displacement of the spring member, a non-slip disc 5d (having a large friction coefficient) is placed under the lower plate 5b.

In order to lift the track plate from above and to adjust the height and the plane of the track plate, the lifting stopper 3a is mounted on the inner wall of the connecting sleeves. Washers 8 are placed between the top plate 5a of the spring member and the support stopper 4, and there is an armature hole in the center of the washer. By adjusting the overall height of the washers, the height and inclination of the track plate can be adjusted. On the connection sleeve, a sealing lid is attached, which is fixed on the lifting stopper 3a.

As shown in Figure 4, the inner contour of the support stopper 4, the outer contour of the upper plate 5a of the spring element and the washer 8 quadrangular whose dimensions match. The spring element and the washer can be inserted from above under the support stop, after insertion of the spring element and washer, the spring element and washer can be rotated about the vertical axis, so that the upper plate 5a of the spring element and the washer 8 overlapping under the support Stop can be arranged.

In order to reduce the vibration and the noise of the track plate, a damping structure 10 is mounted on the upper and lower surfaces of the track plate, which is glued together of 1-3 mm thick viscoelastic polyurethane layer with high attenuation and 2-5mm thick steel plate (interference part). If the track plate is deformed under the excitation of the rails, the steel plate and the track plate do not deform uniformly, so that forced shear deformation occurs in the damping layer. The o. G. Damping material has a high degree of dissipation, so that the kinetic energy of the vibration can be substantially converted into heat and, so that the structural damping of the track plate can be increased and the structural resonance can be reduced.

In practice, the static and dynamic loading of the rail and the vehicle on the track plate 1a are initiated, furthermore, the loads from the track plate 1a through stop 4, washer 8 and upper plate 5a are transmitted to the coil spring 6a. The track plate, the spring and the damping form a vibration isolation system with low natural frequency, thus the medium-frequency and high-frequency dynamic loads are effectively isolated.

Because the elasticity and the carrying capacity of the coil spring can be arbitrarily set in any directions as desired, it is possible to construct a sprung track plate system that corresponds to the average insulating effect and replaces the rubber elastic plate. With the present invention, it is also possible to design a track plate with even higher insulation (15-40dB).

The horizontal stiffness of the track plate is usually greater than the vertical stiffness, so that the horizontal stability of the track plate is ensured. Because the coil spring has good elasticity in all directions, the ratio of horizontal stiffness to vertical stiffness can be arbitrarily set as desired, so that the track plate has good stability in all directions. An additional cross-brace is not necessary, and the structure is simple. For "inner type", the track plate can be adjusted, repaired and replaced from the top so it is very accessible. Because the track plate can be cast in place, the track plate length can be designed to meet the requirement so that the plate resonant frequency can be avoided. A cushioning structure for the track plate is provided to increase the structural damping of the track plate, and to reduce the vibration and noise of the track plate. The damping structure with liquid damping or firmer

Damping material is integrated in the spring element, so that the vibration energy of the track plate can be absorbed, furthermore, the stability of the track plate, driving safety and seismic safety can be improved. The natural vibration of the spring is thus prevented.

Embodiment 2:

As shown in Figs. 5, 6, and 7, the lower surface of the track plate 1b, unlike Embodiment 1, has a convex surface (T-shaped cross section). The spring element 2 supports the lateral surface, which is "track plate of the external type". The spring element is similar to the embodiment 1. The shape of the spring housing is a cuboid, which consists of upper and lower housing part and is connected to rubber seal. In the housing two coil spring 6a are placed, the upper part and lower part are used in damping body 7b. The damping body may be the set viscous-elastic polyurethane with high attenuation. It not only provides cushioning for the spring element, but also connects upper and lower sleeves to the spring. In comparison with liquid damping material, the solid damping material is waterproof, so the seal and the spring sleeve from the view of water repellency are not required. The spring element with several springs has greater load capacity than with only a single spring. The system is economical and its volume is relatively large, so it is suitable for the "outer type track plate".

Washers are placed on the head of the spring element, so the height and the plane of the track plate can be adjusted. In practice, anti-slip discs between spring element and track plate and ground are placed to prevent the horizontal displacement of the spring element.

In the "track plate of the outside type" an additional cross support is not necessary. The track plate can be adjusted, repaired and replaced from the side, making it easily accessible.

Embodiment 3

As shown in Figure 8, Figure 9, Figure 10 and Figure 11, the track plate 1c is ladder-shaped for comparison with Embodiment 1, and the arrangement of the spring members is the outer type. The track plate consists of two parallel reinforced concrete girders and a plurality of parallel cross connection bars 11, which in this example are made of steel tubes. Through the anchor steel on the cross connection bars within the concrete beams, the cross connection bars are firmly connected to the concrete beams. On the upper and lower and outer surfaces of the concrete beams, the damping structure 10 is applied, consisting of 2-3 mm thick layer of modified asphalt with strong damping and a 2-5 mm thick steel plate is glued together. If the concrete beams are deformed under the excitation of the rails, the steel plate and the concrete beams do not deform uniformly, further shear deformation will occur in the damping layer. The above-mentioned damping material has a high degree of dissipation, so that the kinetic energy of the vibration can be substantially converted into heat, so that the structural damping of the concrete beams can be increased.

The spring elements are basically similar to the embodiment 1. The springs in the spring elements are disc springs 6b, by damping body 7b (this is rubber with high damping), the plate spring are connected to the spring housings. The top plate 5a of the spring element is connected by screw (s) with the track plate. There is a positioning hole on the lower plate 5b, during assembly, the positioning hole mates with the anchor bolt 15 to prevent the horizontal displacement of the spring member and to ensure the stability of the track plate. Because the diaphragm spring has sufficient horizontal rigidity, an additional cross-brace is not necessary. The high-damping rubber and the diaphragm spring provide cushioning, so more energy is absorbed. The rubber with high damping and the diaphragm spring are loaded together, so the load capacity is great. The diaphragm spring is wrapped by the high-damping rubber, which makes it waterproof, so that the seal and even the spring sleeve is not required from the viewpoint of water repellency. The structure of the embodiment is simple and inexpensive.

The spring in the spring element may also be a spring composed of rubber and metal, in this example it is the multilayer rubber-metal composite spring, see Figure 11, in which several rubber layers and several metal layers 13 are alternately placed and vulcanized. Its shape is that of a polyhedron or cylinder and in the middle is a damping core 7c of solid damping (e.g., high damping polyurethane). The cross section of the metal plate 13 is like a broken line. When the multi-layer Gurnmi-metal composite spring is loaded in the horizontal direction, the rubber layers 14 are sheared and pressed at the same time, so the rigidity becomes greater than only with scissors. By reasonably designing the angle and thickness ratios of metal plate 13 to rubber layer 14, the metal and rubber interlayer spring may have sufficient horizontal stiffness so additional cross-brace is not needed and the structure is simpler than a spring-loaded track plate with pure rubber. or with or multilayer rubber metal spring with flat sheet steel. The rubber and damper core together provide more cushioning, reducing the resonance of the track plate more.

The multilayer rubber metal spring with buckled sheet metal described in this embodiment may be used in other embodiments, and instead of rubber, polyurethanes or other elastic polymers may be used become.

Embodiment 4

As shown in Figs. 12 and 13, this embodiment is basically similar to Embodiment 1. The difference is as follows: the track plate is in frame form, and the adjustment mechanism is an adjustment screw 9; the adjusting screw belongs to the upper nut type, which consists of screw 9a and adjusting plate 9b and is threaded together; the track plate 1d is supported by support stop 4, adjusting plate 9b and adjusting screw 9a on the top plate 5a of the spring element. With the adjusting screw 9a, the height and the level of the track plate can be adjusted continuously. To secure the screw, a locking nut is provided.

Another difference from the embodiment 1 is that the connection sleeve is saved. The support stop 4 is embedded directly in the inner wall of the opening in the track plate, and the support stop 4 may be a lock ring, further, the support stop 4 may be more center-symmetrically arranged metal rods. The structure of the present example is simple and cheaper.

The sleeve 7d of the limiting damping is mounted on the surface of the spring in the spring element, and it not only prevents the natural vibration of the spring, but also provides the damping for the spring element. The degree of damping of the track plate system is increased, and the stability of the track plate and driving safety are ensured.

Embodiment 5:

As shown in Figure 14 and Figure 15, the track plate consists of several prefabricated small plates. Concave-convex mating is provided on the head side of the small plates, and the mating surfaces are rough surfaces. Between the small plates, solid damping material 7b (e.g., modified asphalt with high damping, cast in, solid at service temperature) is filled and forms the bond after the damping material has hardened. The shape of the small plates may be in plate form, frame form or ladder form.

In this embodiment, the prefabricated small plate is used, so that the design / construction becomes faster, and the plate is suitable for a long distance. The head side is a concavo-convex surface, so the plate is slightly centered during assembly and matched. Damping material is filled between the small plates to load the adjacent plates more uniformly. The vibration transmission between the small plates is isolated by the filled damping material and the vibration energy is dissipated by

Absorbed damping material. The composite track plate has a good damping behavior, so the vibration and the noise of the track plate is greatly reduced. If the spring element has additional damping structure, the track plate has a high degree of damping, the stability of the track plate and driving safety can be ensured.

Embodiment 6:

As shown in Figure 16 and Figure 17, an elastically mounted roadway usually consists of several track panels that are assembled in the long direction. To ensure the thermal expansion and cold shrinkage of the track plate, a joint play between the adjacent plates should be kept. The plates are connected with lateral force coupling, and at each joint 3-5 transverse force couplings are provided. In this embodiment, the connection and the lateral force coupling between the track plates are shown. The lateral force coupling consists of connecting rod 12a and sliding sleeve 12b. The connecting rod is made of steel, and it consists of a fixed part and a sliding part. The sliding part of the rod and the sleeve form a sliding guide in the axial direction, they are limited to each other in the radial direction. The fixed part of the connecting rod and the outer surface of the sliding sleeve are respectively fixed and embedded in the adjacent track plates.

As the vehicle travels from one track plate to the next track plate, the two plates have a lower relative offset because of the transverse force coupling applied and this provides a very high vertical connection stiffness. The bending and shearing of the rail 16 are reduced, and the driving stability and driving safety are increased.

Embodiment 7:

As shown in Figs. 18 and 19, the embodiment shows another structure of the lateral force coupling 12. The fixed part 12a of the lateral force coupling connecting rod and the sliding sleeve 12b are fixed on the respective substructures 12c, and the substructures are walled by screws to the track plate. Compared with the last embodiment, the lateral force coupling is on top of the track plate, so it is more accessible, easy to repair and replace.

Embodiment 8:

As shown in Figs. 20 and 21, this embodiment shows the connection position between the adjacent track plates, and a track plate is a fixed track plate. To ensure the smooth transition between an elastically mounted track plate and an adjacent track plate, should the spring elements with the same rigidity are arranged in a more dense manner in the long direction until the stiffness in the vertical direction relative to one unit of length approaches the relative stiffness of adjacent hard disk.

As the vehicle leaves the stretch of the resilient track panel, the vertical stiffness gradually changes, not suddenly. The two adjacent panels have low relative settling, so bending and shearing of the rail 16 are prevented, and ride stability and ride safety are enhanced.

Another transition between an elastically mounted track plate and an adjacent track plate is: the spring elements are evenly spaced, but the vertical stiffness of the spring elements changes gradually. The spring in the spring element may be a plate spring. By changing the amount and structure of the plate spring, the desired vertical rigidity can be provided.

Claims (16)

Elastic track plate, characterized in that it consists of track plate and spring elements, and that the plate elastically superimposed on spring elements. The elastically mounted track plate described in claim 1, characterized in that the damping element or damping structure is integrated into the track plate. The elastically mounted track plate described in claim 1 or claim 2, characterized in that the spring element consists of spring and spring housing and the spring is in the spring housing, wherein the spring may be a coil spring, a plate spring or rubber-metal composite spring. The elastically mounted track plate described in claim 3, characterized in that at least on a part of the spring surface, a limited layer damping is attached, or that at least part of the spring is inserted / embedded in a solid / solid damping material. The elastically mounted track plate described in claim 3, characterized in that the spring housing of the spring element is sealed, that liquid damping material is filled in the housing, and that the lower part of the spring is immersed in the damping fluid. The elastically mounted track plate described in claim 3, characterized in that the spring elements are located under the track plate in a lateral position. The elastically mounted track plate described in claim 3, characterized in that the spring elements are in prefabricated holes / openings in the track plate, being provided on the inner side of the holes / openings Trag-Arrschlag / support stops / are or connecting sleeves in the Holes of the track plate are used, wherein on the inner side of the connecting sleeve support stop / support stops is / are provided, wherein the track plate is supported by the / the Trag-Anschiag / Trag-Anschiäge on the spring elements. The elastically mounted track plate described in claim 7, characterized in that the lifting stop / stops in the prefabricated holes / openings of the track plate or on the inner wall of the connecting sleeves is mounted, wherein between the spring elements and the / the support stop / Support stops are placed washers and wherein there is an armature hole in the center of the washer. The elastically mounted track plate described in claim 7, characterized in that between the spring elements and the / the support stop / support stops a Höheneinstellschraube and Höheneinstellplatte be installed. The elastically mounted track plate described in claim 8 or 9, characterized in that the supporting stop member or the lifting stop member forms an inner contour which is similar to the outer contour of the supporting cover plate of the spring element and the outer contour of the washer and Höhaneinstellplatte, and that the Outer contour fits into the inner contour or lets it pass axially, and that the supporting cover plate of the spring element and the washer and the Höheneinstellplatte after passing through the inner contour of the support stop can be rotated below the support stop. The elastically mounted track plate described in claim 1, characterized in that the track plate is formed in a plate shape, or frame shape or ladder shape, and that the spring elements are quasi-regular laterally in / or under the track plate. The elastically mounted track plate described in claim 11, characterized in that it consists of several track plates, wherein between the adjacent plates, an expansion joint is provided, and the adjacent plates is connected with transverse force coupling. The elastically mounted track plate described in claim 12, characterized in that the transverse force coupling consists of connecting rod and sliding sleeve, the connecting rod and sleeve form a sliding guide in the axial direction, but they restrict against each other in the radial direction, the connecting rod and the sliding sleeve are respectively in the attached or embedded adjacent panels. The elastically supported track plate described in claim 11, characterized in that the track plate is made up of a plurality of prefabricated small plates, the head side of the small plates has rough surface or concave-convex surface, and between the small plates is damping material, or elastic material or concrete filled and forms connection with it. The elastically mounted track plate described in claim 11, characterized in that in the adjacent to solid lane transition track plates spring elements of equal rigidity unevenly are arranged, the distances between the elements gradually increases or decreases or spring elements with different stiffness are arranged uniformly, the stiffness of the spring elements gradually increases or decreases. The elastically mounted track plate described in claim 3, characterized in that to prevent the horizontal displacement of the spring element, a connection mechanism is provided on the upper and lower surfaces of the spring element, with which the spring element is connected to the track plate and base, the connection mechanism can be an anti-theft Slip disk, a screw or a concave-convex structure

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