EP1206599B1 - Damping section for channel rails - Google Patents

Abstract

The invention relates to a rail assembly provided with a rail (5), in particular, a channel rail, with damping sections (1) and (2) which act on both sides of the rail (5) when in a working position. The spaces around the rail (3, 4) are partially filled by the damping sections and an area (12) of each damping section (1, 2) is located on, or can be applied to the corresponding underside (6, 7) of the rail head (8). Said area (12) stretches elastically in a vertical direction and gives against a restoring force. This configuration allows the rail (5) to be displaced vertically when subjected to stress, without being hindered by parts of a supporting layer (16) of a road section (15) which penetrate the spaces around the rail (3, 4) and without having a detrimental effect on, or destroying said supporting layers (16). Said rail assembly also provides good soundproofing and electric insulation.

Description

The invention relates to a damping profile for grooved rails, preferably for elastically mounted tram rails, which Damping profile in position of use at the bottom of the Rail head rests in the rail chamber.

Such a damping profile is known from practice and consists for example of a foam or from the Material of remanufactured old car tires.

The cross section of this known damping profile. is on adapted the rail chambers and fills them below the Rail head completely up to the rail foot. This Damping profile must therefore from the side by a Paving or concreting to be kept in place. This results in a gap in addition to the rail head this paving or concreting and the actual Rail head, the supernatant of this known damping profile corresponds to the rail head in the lateral direction. This gap must be filled with an elastic grouting material fill out.

Due to the dynamic load of the grooved rail through the on it moving trams and due to thermal expansions due to weather-related temperature differences this will Joint grout relatively quickly damaged and requires according to frequent repairs or even its replacement.

Especially in the very common for noise reduction elastic storage of the tram rails, in which below the rail foot, a yielding layer or a compliant profile is provided, also arise between the known damping profile and the lateral Road construction relative movements, to mutual Damage and destruction.

From DE 43 22 468 A1 is a damping element for a rail known to other genus, because it is about underveloped or free-standing rails, where by rail vehicles and their Wheels caused high frequencies to be damped on the rails should. The intended damping element consists of three Layers, namely a hard metal or plastic layer, a hard elastomeric layer and one of the rail itself facing soft elastomer layer of small thickness, the only serves to, on the rail existing bumps compensate. Thus, the resilience of these thin elastic layer in use position already complete or largely used up. Thus, this damping element would be for countersunk rails that move in the vertical direction must be able to perform, unsuitable.

A comparable damping element for a rail other Genus is known from EP 0 692 572 A1 and also from US-A-5464152. Also here is a damping element for an undeflected provided free-standing rail, which has a part or the entire circumference of the area below the rail head runs with largely constant thickness and not as Damping element for countersunk rails with movements in vertical direction is suitable.

DE 196 46 133 A is a substructure for a track for rail vehicles although the rails are partly known sunk but are not grooved rails. The rail chambers are practically of elastic damping profiles completely filled in and laterally by a sunk frame supported. The rail foot is not supported to the extent possible to transmit little structure-borne noise and by this arrangement should a grooved rail to be replaced, that is, the arrangement is not intended for grooved rails. A side street construction keeps a considerable distance from the respective rail.

There is therefore the task of a damping profile of the beginning to create said type, with which the advantages of a Noise damping and also an electrical insulation of the Rail can be maintained, but still the risk of Damage in particular of the road structure due to the rail movements is largely avoided.

To solve this problem it is provided that the damping profile in the position of use only partially fills the rail chambers and leaves open after the side facing away from the rail web and that of the directly at the bottom of the rail head attachable or located area of the Dämfungsprofiles against the rail head is elastically yielding that the in Use position under the rail head located part or Range of the damping profile while maintaining its lateral Dimension against a restoring force is compressible and a greater thickness than a continuation web extending on the rail web Has.

Can occur in the vertical direction rail movements take place without being in the rail chamber Materials such as an intervening concrete or a bituminous base layer is damaged or opposite to it Neighboring area sheared off. Thus, the invention allows Training the damping profile a concreting up in the rail chamber open to the side, what the Increased stability of the whole arrangement and makes it possible the rail head adjacent upper wear layer of a Road leading up close to the rail head, because this Wear layer of the engaging in the rail chamber Concrete or bitumen of the base layer can be fully supported.

Thus, a previously required in this area be filled to be avoided as far as possible. this applies especially if in the manner of a kit the respective Grooved rail with two differently shaped to her Rail chambers formed damping profiles according to the invention is provided.

It is advantageous that the in use position under the Rail head located part or area of the damping profile while maintaining its lateral dimension against a Restoring force is compressible. With many elastic Materials has a yield in one direction Enlargement of the dimension in the transverse direction result. By the inventive design is avoided, so that at a yielding of the yielding region no horizontal Forces must be absorbed. Nevertheless, the rail can the desired vertical movement, especially with elastic Perform Auflagerung and also the damping profile returns its original position, for example, after the rail a weight-related lowering raises again. The bigger one Thickness allows the corresponding compliance in vertical Direction that is not needed on the continuation web. Yet gives the continuation web the desired additional noise reduction and electrical insulation.

At the rail web in the use position facing the end the compliant area can be applied to the rail bridge Continuation web be provided, up to the rail and in particular also run over the top of the rail foot can, wherein the thickness of the continuation web is less than that horizontal extension of the rail chamber is and the damping profile lining the rail chamber. This results in a Damping profile, which indeed lines the rail chamber, due to the approximately C-shaped cross-sectional shape, but still a large part of the rail chamber free and also to the side leaves open, so that a base course of the road construction up in This rail chamber can reach though in the rail chamber the damping profile is located.

It is expedient if the below the rail head located resilient area a greater thickness - even - than the extending on the rail foot extension web has.

The yielding area can also be at its on the outer edge of the Rail chamber and the rail head located end one the side surface of the rail head at least partially have overlapping stop bar. Thus, a grooved rail in use position also on the approximately vertical area of Rail head possibly up to its upper edge with the Damping be covered or covered, so that the Wear layer of a roadway isolated from the rail and is noise-damped.

The yielding region of the damping profile may be one or more have multiple compressible or collapsible cavities. Such a design can be in the production of the corresponding damping profiles from a corresponding to Example rubber-elastic plastic or the like provide.

For example, the compliant region may be at least one channel-like, enclosed in its entire cross-section Have cavity. It then results on the damping profile in its yielding area the compliance by this Cavity and its boundaries.

It is particularly favorable, if within the yielding Area forming cavity at least one or two support webs are provided, in particular in the longitudinal direction of the damping profile and the rail run. These support bars do not prevent the compression of the cavity when Yielding to the yielding range, but improve the elastic restoring forces, if one through a load partially lowered rail raises again. The number of Support webs can be of the width of the yielding area be made dependent. For example, under the groove part of the rail head a wider yielding Area have two such support webs, while the under the other rail head located compliant area with only can get along such a bridge.

So that the support bars do not affect the compliance too much and also at a compression of the cavity do not fold and thereby limit the degree of compliance, may be the cross section of or in the cavity of the compliant Area located support webs to be arranged obliquely.

In the compliant region, many cavities, For example, be provided pore-like cavities, wherein at least the outside of the damping profile and its compliant area is closed, so no impurities or concrete can penetrate into them and through such Dirt and fillings reduces the compliance or prevented.

The one or more voids located in the compliant region can be made with compliant materials or media, preferably with Be filled with air. This represents a particularly inexpensive filling for the cavities of the yielding area, which is practically by itself results.

It is useful if the damping profile of an electric insulating elastomeric material consists, in particular of a Rubber mixture based on styrene-butadiene rubber (short form: SBR). Such a material is used as a damping profile for electrical insulation and noise damping well suited and also has the desired elastic properties, especially in the yielding area under the rail head of importance are.

Especially when combining one or more of the above Features and measures results in a rail arrangement with damping profiles, in which each of the different shaped rail chambers adapted damping profiles do not completely fill the rail chambers, so that the remaining one Part of the rail chamber with concrete, a bituminous base course or other materials can be filled without the Rail their mobility especially in the vertical direction loses. Thus, a base layer of concrete or a comparable material to reach the rail chamber and rich Wear a suitable wear layer that is close to the rail head is sufficient and a relatively wide to be filled Fugue avoids.

Fig.1

einen Querschnitt eines Bausatzes aus einer Rillenschiene und zwei an die unterschiedlichen Schienenkammern dieser Rillenschiene angepaßten erfindungsgemäßen Dämpfungsprofilen, die eine etwa C-förmige Querschnittsform haben und zur Auskleidung der Schienenkammern geeignet sind,

Fig.2

einen Querschnitt der Rillenschiene und der ihre Schienenkammern auskleidenden Dämpfungsprofile in zusammengefügter Anordnung, sowie

Fig.3

die Rillenschiene mit den erfindungsgemäßen Dämpfungsprofilen im eingebauten Zustand nach dem Anbringen von der Schiene jeweils benachbarten Straßenaufbauten, die bis in die von den Dämpfungsprofilen jeweils ausgekleideten Schienenkammern reichen, wobei die Dämpfungsprofile dennoch eine vertikale Ausweichbewegung der Schienen erlauben.

An embodiment of the invention will be described in more detail below with reference to the drawing. It shows in partly schematized representation:

Fig.1

a cross section of a kit of a grooved rail and two adapted to the different rail chambers of this groove rail damping profiles according to the invention which have an approximately C-shaped cross-sectional shape and are suitable for lining the rail chambers,

Fig.2

a cross-section of the groove rail and the lining of their rail chambers damping profiles in an assembled arrangement, as well

Figure 3

the grooved rail with the damping profiles according to the invention in the installed state after attachment of the rail respectively adjacent road structures that extend into the respective lined by the damping profiles rail chambers, the damping profiles still allow a vertical evasive movement of the rails.

In the embodiment according to Figures 1 to 3 can be seen two in total with 1 on the one hand and 2 on the other designated damping profiles that serve in the rail chambers 3 and 4 of a grooved rail 5 so inserted and inserted to be in the position of use according to the figures 2 and 3, these rail chambers 3 and 4 line, each Damping profile 1 and 2 then according to Figures 2 and 3 at the Bottom 6 and 7 of the rail head 8 of the grooved rail. 5 is applied.

The two damping profiles 1 and 2 are due to the different shape of the rail chambers 3 and 4 something different profiled, so have something modified Cross sections, as it is clearly visible in the figures. This Stems, therefore, that the rail chamber 4 under the groove 9 and the Leading edge 10 of the part shown in the figures on the right Rail head 8 because of the space requirement and the depth of the groove 9 is a smaller vertical dimension than the rail chamber 3 Has.

It is essential that the damping profile 1 and the damping profile 2 each in the use position, the rail chamber 3 and 4 only partially fill and after the of the rail web 11th opposite side leaves open, as it is clear especially from Fig.2 evident.

The at the bottom 6 and 7 of the rail head 8 respectively attachable or located area, below for both slightly different cross-section damping profiles 1 and 2 each despite the slightly different dimensions and Shaping is designated 12, is doing against the rail head towards in a manner to be described later elastically yielding designed. This is in the position of use under the Rail head 8 located part or area 12 of the respective Damping profiles 1 and 2 according to Figure 3 while maintaining its lateral dimension compressible against a restoring force, if the grooved rail 5 according to the arrow Pf in Figure 3 from above is charged, what when driving on a rail vehicle occurs.

The rail 5 will yield more, the more elastic their underground is and in many cases is under the Rail foot 13 an elastic layer or an elastic profile, to consciously grant a certain flexibility to the rail 5 enable.

At the rail web 11 in the use position according to the figures 2 and 3 each facing the end of the resilient portion 12th is at both damping profiles 1 and 2 a to the rail web 11 disposable continuation web 14 is provided, which up to the Rail foot 13 and also over the top of this rail foot 13 runs, so together with the elastically yielding area 12, the entire rail chamber 3 and 4 lines. It is the Thickness of the continuation web 14 less than the horizontal Extension of the respective rail chamber 3 and 4, so that the Rail chamber 3 and 4 still largely remains. The located below the rail head 8 compliant area 12 has one in the interest of its vertical compliance greater thickness than that at the rail web 11 and on the Rail foot 13 extending continuation web 14th

From Fig.3 it follows that this arrangement allows a Both sides of the rail 5 located road construction 15 with a Support layer 16 continuously in the rail chambers 3 and 4 let intervene, so that such a support layer 16 and the topmost position of such a road structure 15 close to the Rail head 5 can best support. By the compliant portions 12, the rail 5 can still relative to the road structure 15 and the in the rail chambers 3 and 4 protruding projections of the support layer 16 vertical movements perform without damaging the base layer 16 or to to destroy. The entire road construction is accordingly stable 15 also near the rail head 5, so that there corresponding Compensation joints are avoided.

It can be seen that the resilient portion 12 at its on outer edge of the respective rail chamber 3 or 4 and the Rail head 8 located one end of the side surface of the Rail head 8 and the leading edge 10 overlapping Stop ridge 17 has, the rail 5 also in the field of Rail head 8 of the close to the rail 5 reaching Road construction 15 shields. Thus, the damping profile 1 and 2 also electrically insulate the rail 5 towards the sides and gives the best possible noise reduction despite the Possibility that the rail 5 relative to the road structure 15th can be stored yielding.

The resilient region 12 has in the embodiment a or a plurality of compressible or collapsible cavities 18 in order to maximize the flexibility in practice realize. In the exemplary embodiment, a channel-like, enclosed in its entire cross section cavity 18, within which on the damping profile 1 and on the Damping profile 2 two support ribs 19 are provided, which in Longitudinal direction of the respective damping profile 1 and 2 and the rail 5 and therefore in the figures in Cross section can be seen. These support bars 18 help that the resilient portion 12 and the longitudinal direction extending cavity 18 back to its original thickness deformed back when the load according to the arrow Pf is over.

This is a good compromise between compliance on the one hand and restoring force in the undeformed starting position according to the Figures 1 and 2 facilitated by that in the cavities 18 of the two damping profiles 1 and 2 and their yielding Areas 12 located support webs 19 with respect to their cross section are arranged obliquely. So you can join her Yielding assume a curved shape indicated in FIG can go even further, depending on the load and flexibility as shown in Fig.3.

Particularly cost are the damping profiles 1 and 2, if the resilient portions 12 and the cavities therein 18 in addition to the yielding support bars 19 even more yielding Materials or media, preferably air included.

The respective damping profile 1 and 2 consists for example made of an electrically insulating elastomeric material, in particular from a rubber mixture based on styrene-butadiene rubber (SBR). This material has on the one hand the desired sound-absorbing and electrically insulating Properties and also the elasticity, which for the Restoring force against the arrow Pf is required.

In Figure 3 can be seen especially in the area of the rail foot 13, as the rail 5 yielded slightly under the load Pf has, because there is between the rail 13 overlapping continuation web 14 and the support layer 13 a temporarily occurring at this load joint 20, which is due to the restoring forces described again closes when the burden is over.

Overall, with the kit shown in the figures a rail 5 and two at the rail chambers 3 and 4 matched damping profiles 1 and 2, the rail 5 elastic be stored yielding and yield in the vertical direction, although provided on both sides of the support layers 16 of the road construction 15 in the lined by the damping profiles 1 and 2 Rail chambers are enough. This increases the life of the on both sides of the rail 5 located road construction 15 despite the desired rail movements, so that in this area occurring repairs are rarely necessary and a wide joint next to the rail head 8 can be avoided.

Instead of provided with support ribs 19 and filled with air Holes 18 could also be in the compliant regions 12 Pore-like cavities are provided to a comparable Effect to achieve.

A rail arrangement with a rail 5, in particular a Grooved rail, and with the two sides of this rail 5 in Use position acting on damping profiles 1 and 2 allowed due to the partial filling of the rail chambers 3 and 4 with the damping profiles and one at the Bottom 6 and 7 of the rail head 8 attachable or located area 12 of the respective damping profile 1 and 2, which region 1 2 in the vertical direction elastic and against a restoring force is yielding that the rail 5 under Load vertical movements without going through in the Rail chambers 3 and 4 engaging parts of a support layer 16th a road structure 15 on the one hand to be prevented and without, on the other hand, rendering these base layers 16 stalwart or destroy. At the same time results in a good noise attenuation and an electrical insulation.

Claims (11)

1. Damping profile (1, 2) for tramway rails (5), preferably for resiliently mounted streetcar rails, said damping profile (1, 2) abutting on the underside (6, 7) of the rail head (8) in the rail chamber (3, 4) in the position of use, characterised in that the damping profile (1, 2) only partially fills the rail chamber (3, 4) in the position of use and leaves it open on the side remote from the rail web (11), and in that the region (12) of the damping profile which can be mounted or is located on the underside (6, 7) of the rail head (8) is elastically flexible towards the rail head, in that the part or region (12) of the damping profile (1, 2) which is located under the rail head (8) in the position of use can be compressed counter to a recoil force while retaining its lateral dimensions and is thicker than an extension web (14) running along the rail web (11).
2. Damping profile according to claim 1, characterised in that the extension web (14) which can be placed against the rail web (11) is provided at the end of the flexible region (12) facing the rail web (11) in the position of use, said extension web (14) extending to the rail base (13) and more particularly over the top of the rail base as well, the thickness of the extension web (14) being less than the horizontal dimension of the rail chamber (3, 4), while the damping profile (1, 2) lines the rail chamber (3, 4).
3. Damping profile according to claim 1 or 2, characterised in that the flexible region (12) located underneath the rail head (8) is thicker than the extension web (14) running along the rail base (12).
4. Damping profile according to one of claims 1 to 3, characterised in that the flexible region (12) has, at its end located on the outer edge of the rail chamber (3, 4) and the rail head (8), a stop bar (17) which overlaps the side surface of the rail head (8) at least in some areas.
5. Damping profile according to one of claims 1 to 4, characterised in that its flexible region (12) comprises one or more compressible or collapsible cavities (18).
6. Damping profile according to one of claims 1 to 5, characterised in that the flexible region (12) has at least one channel-like cavity (18) which is enclosed over its entire cross section.
7. 'Damping profile according to one of claims 1 to 6, characterised in that inside the cavity (18) which forms the flexible region (12) are provided at least one or two support bars (19) which extend, in particular, in the direction of longitudinal extent of the damping profile (1, 2) and the rail (5).
8. Damping profile according to one of claims 1 to 7, characterised in that the cross section of the support bar(s) (19) located in the cavity (18) of the flexible region (12) is arranged diagonally.
9. Damping profile according to one of claims 1 to 8, characterised in that a plurality of cavities, such as pore-like cavities, for example, are provided in the flexible region (12), while at least the outside of the damping profile (1, 2) and its flexible region (12) is closed.
10. Damping profile according to one of claims 1 to 9, characterised in that the cavity or cavities (18) located in the flexible region (12) is or are filled with ductile materials or media, preferably with air.
11. Damping profile according to one of claims 1 to 10, characterised in that it consists of an electrically insulating elastomeric material, particularly a rubber mixture based on styrene-butadiene rubber.

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