EP2025810A1 - Railway renewing machine with triple separated spoil - Google Patents

Abstract

The construction has an excavating chain front (10) which provides a first upper layer of the substructure. A rear digging chain (80) is directed to work behind the front digging chain and arranged below the first upper layer. A second transfer body (70) is arranged in the direction of work after the first injection and compression facility is provided and dumps ballast. A digging chain (30) is arranged between the front and rear of the excavating chain to ensure that between the first upper layer and lower layer an intermediate layer is provided.

Description

The invention relates to a continuous track rail track rehabilitation machine for track-based track reconditioning, comprising: a front excavator chain configured to excavate a first upper layer of a trackway substructure, a rear excavator chain driven in the forward direction of travel behind the front excavation chain is arranged and designed to excavate a second, below the first, upper layer underlying lower layer, a first insertion device, which is arranged in the direction of travel during labor behind the second Aushubkette and is adapted for introducing a base course material, a second insertion device, the Direction of travel when working behind the first introduction and compression device is arranged and is designed for the introduction of ballast. Another aspect of the invention is a method of track-based trackside remediation in continuous motion.

Track reconditioning machines and track rehabilitation methods of the aforementioned kind are known and serve to rehabilitate track ways, which no longer meet the requirements for safety and resilience with respect to the stresses occurring in daily operation. The safety and resilience can be reduced, for example, by the fact that by ballast pollution - For example, as a result of ascended sand or Erdanteilen from the lower layer region of the track substructure or by a penetrating from the surface pollution - the safe ballasting the tracks is no longer guaranteed. In addition, the layer located below the ballast layer, be it a base layer or a lower layer designed in a different way, can no longer ensure safe drainage and load absorption due to changes such as under-flushing, leaching, warping or the like and requires a track restoration. Finally, a common reason for track shunting is that the track track no longer meets the increased demands of day-to-day operation due to, for example, higher track speeds, and consequently has to be raised to a higher standard, which also requires rehabilitation.

In the course of a track rehabilitation typically the track is raised together with thresholds, excavated the underlying substructure by means of excavation chains and introduced a new substructure and solidified, on which the track is then stored again and anchored by ballast. For this purpose is from the German patent DE 201 12 865 a track construction machine having a first and second Aushubkette which excavate the old substructure material of the track path. This material is transported away and stored in entrained bunker cars of the track construction train. From new entrainment bunker wagon of the track construction new substructure material is then introduced and introduced, in the form of a base layer, which is introduced as the lowest layer, compacted and leveled, a layer protection layer, which is introduced as a layer above and compacted and leveled and a subsequent thereto gravel layer.

Such track construction machines and the corresponding track remediation methods are suitable and practicable for track ways which require a fundamental refurbishment. Such track reclamation projects require the complete removal and use of new materials, and for this purpose a large number of bunker cars are required to provide for the appropriate Storage of the materials. The process must be interrupted at regular intervals in order to transport bunker wagons filled with waste and to introduce new, empty bunker wagons and to replace the emptied bunker wagons provided with new material with filled bunker wagons.

For track rehabilitation tasks where the track track substructure partially contains material that can be used for the new track track substructure, it is from the European patent EP 0 940 502 B1 known to sieve the excavated material and certain, filtered-out portions of the excavated waste material to use for the new track track substructure. It is fundamentally advantageous for such an approach that the volume of material to be transported off and transported can be reduced by the at least partial recycling because a partial material cycle is achieved within the track construction machine. However, the method and the track-laying machine can be further improved.

A first improvement goal follows from the fact that the suitability of the excavated material varies greatly depending on the track conditions and requires a more or less large treatment process within the track construction machine. In certain cases, material can be taken which can be used without major processing, for example, only after screening, for certain layers of the new track track substructure. In other instances, however, a major conditioning operation is required to filter, break, wash and the like heavily soiled soils or soils having substantially unsatisfactory grain fractions in order to gain the small amount of usable material for the new trackway substructure. The different soil conditions arise on the one hand in the different sections, since track paths often run along different soils, such as heavily sandy soils, heavily clay soils, rocky soils or mixtures thereof. In addition, stratifications usually occur in the various soil types, be it concretely in the surface area of the track track or in the deeper area of the bearing earth layer of the track way. It is desirable to have a track rehabilitation machine that operates efficiently and inexpensively under these different conditions.

From the European patent EP 1 643 035 B1 For the purpose of improving the known track rehabilitation method, it is known to analyze the condition of the track track on the track construction machine in order to obtain information about the quality of the old trackway substructure material and to control the track rehabilitation with optional reclamation and recovery of the old track substructure material. Although with such a method, a great progress in the track remediation can be achieved, however, a costly preparation of the excavated material must still be made and the efficiency of the track remover can be increased even with very different ground conditions or layer structures of the track.

It is an object of the invention to provide a track remediation machine and track remediation method in which improved efficiency is achieved even with widely different starting situations.

This object is achieved according to the invention by providing, in a track remover of the type mentioned above, a middle excavation chain which is arranged between the front and the rear excavation chain and is designed to excavate an intermediate layer lying between the first, upper layer and the lower layer.

According to the invention, a track reconditioning machine is provided with which the old track substructure material, ie the old ballast and the underlying soil layers, is excavated by means of three excavation chains to a depth required for the installation of the new track track substructure. The three Aushubketten are arranged in the working direction one behind the other on the Gleiswegsanierungsmaschine and lift three layers in succession. With the track remover according to the invention, it is thus possible to make in a precise manner a threefold differentiated Schichtaushebung and In this way targeted and already separated by the excavation process from each other to gain certain qualities of the old Gleiswegunterbaumaterials. This targeted, separate excavation makes it possible to significantly reduce the required treatment of the excavated material and to adapt the processing steps to the excavated material qualities.

All three excavation chains can be adjusted with regard to their excavation depth, so that the track remover according to the invention can be adapted to different layer structures of the track and different ground conditions along the track. Thus, the depth to which is excavated with a certain Aushubkette be set, and consequently also the respective volume, which is excavated with a certain Aushubkette be determined.

According to a first preferred embodiment, the front excavating chain is adjustable to excavate a near-surface gravel layer. With this preferred embodiment, it is possible that with the front excavating chain in a first step, a near-surface gravel layer is excavated. This near-surface gravel layer is typically the best preserved and least contaminated old ballast layer and is therefore suitable to be used directly as recycled ballast after a low effort treatment - younger track paths possibly even without treatment - and consequently by the second introduction device to be introduced as gravel of the new substructure. As a result, the volume of the ballast to be removed and to be newly provided can be significantly reduced, without the need for elaborate treatment measures.

In accordance with a second preferred embodiment, the middle excavation chain is adjustable to excavate an intermediate layer, which is comprised of crushed stone and contaminants, below the first upper layer. Typically, a trackway is characterized by such an intermediate layer in which the ballast mixes with underlying soil, soil or the like. Such an intermediate layer still contains essential However, gravel fractions, whose recovery is attractive and cost-saving, require a treatment, in particular a screening. The gravel material obtained from this intermediate layer is often no longer sufficiently sharp for the production of a new ballast bed or not sufficiently sharpened for this purpose. Therefore, it is often necessary to use the ballast from the intermediate layer for a different purpose or a different layer in the newly built track track substructure as the overlying shallow gravel. This is made possible by the separate excavation of the ballast of the intermediate layer.

It is further preferred if the rear excavation chain is adjustable in order to excavate a layer which is located below the intermediate layer and consists essentially of fine grain fractions. The rear excavation chain lifts the old track substructure to the depth needed to provide a standard to be met by the new track track substructure. Typically, the rear excavation chain excavates a low-lying layer portion of the old trackway substructure, often with large proportions or solely consisting of the natural soil material. This material is suitable only in certain cases, namely, when the natural soil has particularly advantageous compositions for a new track track substructure, for being fed to a recycling circuit within the track construction machine. Often, such recycling can be achieved only with elaborate processing steps within the track construction machine. However, in most track rehabilitation applications, the material excavated with the back excavating chain will not be usable for recycling and thus must be stored temporarily in entrained bunker cars.

It is preferred to train the track remover according to the invention by a first ballast conveyor for conveying the ballast conveyed by the front excavating chain to a ballast processing device and a second ballast conveyor for conveying the processed ballast from the ballast processing device to the second introduction device. With this training, it is possible to prepare the excavated in the first step gravel and bring him for the gravel bed of the newly created track. The ballast processing device may in this case comprise, for example, a screening device, a ballast washing device with a ballast washing with water, a ballast sharpening device and / or a ballast breaking device. The excavated ballast can either be fed to only one of these processing units or successively pass through several of these processing units to be brought into the condition required for the new track.

In this case, it is particularly preferred to provide a ballast mixing device and means for directing the mixture produced in the ballast mixing device to the second introduction device, wherein the second ballast conveyor device and a conveyor device for conveying new ballast empties out of a bunker carriage into the ballast mixing device. With this training, it is possible to mix the excavated ballast before introduction with Neuschotter and in this way to achieve the required volume of ballast material for the newly created track. In this case, in particular the gemstone to be mixed in can be chosen so that the mixture in conjunction with the quality of the old ballot a quality of the mixture is achieved according to the requirements, for example by the old ballast, which has basically smaller particle sizes after refraction, is mixed with Neuschotter larger grain sizes in order to achieve an overall particle size distribution according to the requirement.

Furthermore, the track remover according to the invention may be further developed by a first excavation conveyor for conveying the excavated material conveyed by the middle excavation chain to a material processing device and a second excavating conveyor for conveying the processed excavated material from the material processing device to the first introduction device. With this training is made possible to prepare the excavated in the second step excavated material and bring it in the fourth step as a base course material. In particular, this can be done with the middle excavation chain excavated material can be used to make a base layer, for example, by filtering ballast fractions out of the excavated material and breaking them down and then using them as the solid particles required for such a base layer with a larger particle shape.

It is particularly preferred to provide a base course mixing device and means for guiding the mixture produced in the base course mixing device to the first introduction device, wherein in the base layer mixing device, the second excavation conveyor and a conveyor for conveying virgin material from a bunker carriage opens , With this further training, the excavated material excavated in the second step may be mixed with virgin material prior to its incorporation into the new track track substructure to ensure the bearing capacity of the newly produced layer and optionally other properties such as drainage capability or the like.

Furthermore, it is preferred that the ballast processing device comprises a screening device, which is designed to screen out constituents below a certain grain size from the excavated ballast. This makes it possible, when processing the ballast sift ingredients below a certain grain size from the excavated old ballast, to provide recycling gravel in this way, which has only ballast stones above a certain grain size and thus is suitable for the production of the new ballast bed. The falling through the sieve smaller particle sizes can either be stored in a bunker car and ultimately disposed of or used for other layers of the new track track substructure, optionally after further treatment steps. Grain size in the sense of the invention is to be understood in particular as meaning the maximum dimension of a grain or the mean value of grain dimensions in different directions of a grain.

In this case, it is further preferred to have a conveying device for conveying excavated material from the rear excavating chain to the screening device and a material guiding device, adapted to selectively provide the screening device with ballast from the front excavating chain or excavating material from the rear excavating chain. With this embodiment, either the excavated in the first step gravel or excavated after the second step excavated material can be sieved in a common screening device. The inventively trained such track construction machine therefore requires only the structural arrangement of a single screening device that can be configured as a single-stage or multi-stage screening device and is variably equipped with this single screening device for the preparation of Gleiswegunterbaumaterial different qualities.

Trajectories which are still in relatively good condition often do not require screening of the superficial ballast, but can be used directly for recycling without specific treatment steps. In such track paths often funded with the rear Aushubkette excavated material also also be used for certain layers of the new track track substructure and this requires a screening that can be done in the screening device according to the invention. On the other hand, track tracks that are in a significantly deteriorated condition often require screening of the shallow gravel layer near the surface in order to recycle it for recycling. In such track ways this screening can be done in the screening device according to the invention. The funded with the rear excavating soil material is not suitable for such poor track structures regularly to be used for the new track track substructure and therefore requires no further processing, and can be inventively fed directly to a bunker for temporary storage and eventual disposal. With this development according to the invention, it is thus possible to provide a Gleiswegsanierungsmaschine that can be adapted to significantly different qualities in track track substructure of the track to be rehabilitated and each for rehabilitation track track substructure each can prepare the optimal proportion of excavated materials to be recycled, without this purpose processing facilities in the track reconditioning machine would have to be kept in duplicate or in multiple ways.

According to a further preferred embodiment, the material processing device comprises a screening device, a comminuting device and a conveying device for conveying filtered coarse parts from the screening device to the comminution device and a material guiding device which is designed to selectively guide the excavation of the central conveying chain to the screening device or the comminuting device , With this training, it is possible that coarse fractions of the excavated material in the second step are crushed and this - depending on the quality and composition of the excavated material - optionally after an upstream filtering step - takes place. The excavated material may thus first be subjected to filtering in order to filter out the suitable coarse fractions and these coarse fractions are subsequently comminuted, for example in order to supply them to the first introduction device and to use them as coarse components of the new support layer to be newly produced.

It is further preferred to train the track remover according to the invention by a PSS insertion device, which is arranged in the direction of travel during labor input between the first and the second insertion means and is adapted to apply to the support layer introduced by the first introduction means a layer protection layer. A cover protection layer serves in particular to ensure a reliable drainage of the new track. Tarpaulin protective layers typically need to be adapted to the natural ground in the area of the track and, depending on the nature of this natural soil, require either fluid storage capacity or liquid impermeability to prevent damage to the trackway by leaching, under-flushing, frost and the like. The leveling protective layer can typically be made using only or substantially virgin material. A use of previously excavated material is possible only with certain soil conditions and often requires very expensive treatment steps, which usually does not allow economic recycling in terms of the sheathing protective layer. With the training according to the invention is makes it possible, after the introduction of the base course and before the introduction of the ballast layer, to apply a protective layer on the base course.

Finally, the track remover according to the invention can be further developed by the front, middle and / or rear excavation chain are supported on a bridge, which is in use of the machine on a first chassis, which is arranged in front of the front excavation chain in the direction of travel, and a second chassis , which is arranged in the direction of travel behind the rear insertion device, supported. With this training according to the invention, it is possible that all the steps required for the excavation of the old track track substructure and the introduction of the new track track substructure are carried out in a continuous process with a contiguous track construction train. For this purpose, the devices required for the individual steps rely on a bridge that runs on two chassis on the track to be rehabilitated. The front chassis in the working direction runs on a track that is supported on the old track track substructure. The bridge spans the entire section where this track is levitating due to the removal of the track track substructure and the layered structure of the new track track substructure and the rear undercarriage running on the same track now supported on the new track track substructure.

In accordance with another aspect of the invention, there is provided a continuous track track recapturing method comprising the steps of excavating a first upper ballast layer of the old substructure of a track, then excavating a second lower layer of the former below the first upper layer Substructure, subsequent introduction of a base course material of the new substructure, subsequent introduction of gravel of the new substructure, wherein after the lifting of the first, upper layer and before lifting the lower layer in a second step, one between the first, upper layer and the lower layer lying middle layer of the old substructure is dug. With the method according to the invention, it is possible to use the old track track substructure in a targeted manner in three separate layer portions excavate and supply these three strata targeted to a specific treatment in order to gain the largest possible volume fraction of recycled material for certain layers of the new track track substructure.

The inventive method and the machine according to the invention are particularly suitable for continuous track reassembly. This excavation of all three Aushubketten and introducing the new layer materials take place simultaneously and spatially offset, so that - spatially resolved - takes place a successive series of steps at a location of the track.

For the individual steps of the method and the further developments of the method according to claims 15-26, reference is made to the preceding explanation of the corresponding physical embodiments of the track remover required for carrying out these method steps and developments.

Fig. 1:

eine schematische Darstellung der wesentlichen konstruktiven Bestandteile und der Stoffströme einer Ausgestaltung der erfindungsgemäßen Gleiswegsanierungsmaschine,

Fig. 2:

einen vergrößerten, vorderen Abschnitt der Gleiswegsanierungsmaschine gemäß Figur 1,

Fig. 3:

einen vergrößerten, mittleren Abschnitt der Gleiswegsanierungsmaschine gemäß Figur 1, und

Fig. 4:

einen vergrößerten, hinteren Abschnitt der Gleiswegsanierungsmaschine gemäß Figur 1.

A preferred embodiment will be described with reference to the attached figures. Show it:

Fig. 1:

a schematic representation of the essential structural components and the material flows of an embodiment of the invention Gleiswegsanierungsmaschine,

Fig. 2:

an enlarged, front portion of the track reassembly according to FIG. 1 .

3:

an enlarged, central portion of the track reassembly according to FIG. 1 , and

4:

an enlarged, rear portion of the track repair machine according to FIG. 1 ,

The track remover shown in the figures comprises a first ballast excavator chain 10 which is adjusted to engage deeply in the existing ballast layer of the old track track to be rehabilitated near-surface gravel layer is excavated. This excavated, near-surface gravel layer is supplied as a ballast 11 of a screening device 20.

The screening device 20 comprises a first screening unit 20a and a second screening unit 20b. The supplied ballast 11 can either be distributed in half each with bulkhead sub-streams 11a, b onto the screening units 20a, b in order to achieve a high throughput of the screening device 20. Alternatively, the ballast stream may initially be fed only to the screen unit 20a, here subjected to a first screening operation and the material thereby filtered out is fed with a stock flow 12 to the second screening unit 20b in order to be subjected to a subsequent screening.

The resulting from the screening process in the screening device 20 proportion of ballast with sufficient grain size is supplied with a flow of material 13 arranged in the rear part of the Gleiswegsanierungsmaschine ballast device (not shown). Before this Schottereinbringungsvorrichtung the recovered in the screening device 20 recycling gravel can still be supplied to a mixing device to be mixed with Neuschotter, which is carried on the track construction in bunker cars and the mixing device is also supplied.

The track remover machine moves during work in the direction indicated by the arrows A working direction.

In the working direction behind the first Schotteraushubkette 10 a second Aushubkette 30 is arranged. The second excavation chain 30 engages deeper in the old track track substructure than the first ballast excavation chain 10 and lifts a layer composed of a mixture of gravel fractions and fine particle fractions such as soil, sand, loam or the like. The material mix excavated by the second excavation chain 30 is supplied to a treatment device 40 with a material flow 31.

The processing device 40 comprises a screening device 41 and a comminuting device 42. The material excavated with the material flow 31 can be supplied either with a stream 31 a first of the sieve 41 and then the following with a stream 31 b, the thereby filtered out coarse fractions of the crushing device 42 are supplied. Alternatively, the material conveyed with the second excavating chain can also be fed directly to a material flow 31c of the comminution device 42 without passing through a prior screening in the sieve device 41 if the excavated material has no appreciable fines which would have to be screened out.

The particles of small and defined size emerging from the comminuting device are fed to a feed device 50 with a material flow 32. The introduction device 50 comprises an upstream mixing device 51, in which the material flow 32 opens. Further, in the mixing device 51, a conveyor from a memory 60 or a plurality of storage units 60, from which additives can be supplied to the mixer. The mixture thus produced in the mixer 51 serves to represent a material suitable for a base layer and is applied from the mixer 51 via the introduction device 50 to the bottom of the completely excavated track.

In the working direction behind the introduction of the base course material devices for leveling and compaction 52 of the base course material are arranged to produce a support layer in the required quality.

In the working direction behind the introduction device 50, a PSS introduction device 70 is arranged, which also comprises a mixer 71. In the mixer 71 PSS starting material stored in the bunker carriage is fed in the rear part of the train, mixed and applied via the PSS introduction device 70 to the previously created supporting layer.

In the area behind the point of introduction of the PSS material, planing devices and compacting devices 72 are again arranged, which produce the PSS layer in the required quality.

In the working direction behind the second excavation chain 30 and in front of the introduction device 50, a third Aushubkette 80 is arranged. The third excavation chain 80 is set to engage deeper in the original track substructure than the second excavation chain 30 and excavate the bottom layer of the original track track substructure to such a depth as to provide the required installation space for the track track substructure to be rebuilt , The excavated from the third Aushubkette 80 material is conveyed with a stream 81 in the front track construction part and can there the screening device 20 are supplied, if it does not sieve excavated with the first Schotteraushubkette gravel. In this way, recyclable coarse fractions can be filtered out of the excavated material of the third excavation chain and used with the material flow 13 as recycling gravel.

However, if, as a rule, the screening device 20 is used to screen the excavated with the first Schotteraushubkette ballast, excavated with the third Aushubkette soil material is conveyed with a stream 81 b to a arranged in the front part of the bunker wagon and stored there until disposal.

The screened out of the screening units 20a, b and 41 fine material is also conveyed with a stream 81c in the front part of the train to bunker cars and stored there until final disposal.

Claims (15)

Rail track rehabilitation machine for track-based track rehabilitation in continuous motion, comprising: i. an excavation chain (10) in the direction of travel when working, which is designed to excavate and remove a first upper layer of the substructure of a trackway, ii. a rear excavating chain (80), which is arranged in the direction of travel during labor behind the front Aushubkette and is adapted to excavate a second, located below the first, upper layer lower layer and transported away, iii. a first introduction device (50), which is arranged in the direction of travel when working behind the rear Aushubkette and is adapted for introducing a base course material, iv. a second introduction device (70), which is arranged in the direction of travel when working behind the first introduction and compression device and is designed for introducing gravel, characterized by providing a middle excavation chain (30) disposed between the front and rear excavation chains and configured to excavate an intermediate layer interposed between the first, upper, and lower layers. Track rehabilitation machine according to claim 1,
characterized in that - The front excavating chain (10) is adjustable to excavate a near-surface gravel layer, - The middle Aushubkette (30) is adjustable to excavate an intermediate layer located below the first upper layer, which consists of gravel and dirt particles, and / or - The rear Aushubkette (80) is adjustable in order to excavate a layer located below the intermediate layer, which consists of substantially fine grain fractions. A track reconditioning machine according to claim 1 or 2, characterized by a first ballast conveyor (11) for conveying the ballast conveyed by the front excavating chain to a ballast preparation device (20) and a second ballast conveyor (13) for conveying the processed ballast from the ballast preparation device to the second one Introduction device, wherein the ballast processing device preferably comprises a screening device (20a, b), which is designed to screen out ingredients below a certain grain size from the excavated ballast. A track reconditioning machine as claimed in the preceding claim, characterized by conveyor means (81) for conveying excavated material from the rear excavating chain to the screening device (20) and a material guiding device adapted to selectively dispose ballast from the front excavating chain (10) or excavated material from the screening device to feed the rear excavation chain (80). Track rehabilitation machine according to the preceding claim 3 or 4, characterized by a ballast mixing device and means for guiding the mixture produced in the ballast mixing device to the second introduction device,
wherein in the ballast mixing device, the second ballast conveyor and a conveyor for conveying Neuchotter empties out of a bunker car. A track rehabilitation machine according to any one of the preceding claims, characterized by a first excavation conveyor (31) for conveying the excavated material conveyed by the middle excavation chain to a material processing device (40) and a second excavation conveyor (32) for conveying the processed excavated material from the material processing device to the first introduction device (50), wherein the material processing device preferably comprises a sieve device (41), a comminuting device (42) and a conveying device (31b) for conveying filtered coarse parts from the sieve device to the comminuting device and a material guiding device which is designed to selectively guide the excavation of the middle conveyor chain (30) to the screening device (41) or the shredding device (42). Track rehabilitation machine according to the preceding claim, characterized by a base course mixing device (51) and means for guiding the mixture produced in the base course mixing device to the first introduction device.
wherein in the support layer mixing means, the second excavation conveyor and a conveyor for conveying virgin material (60) in particular from a bunker trolley opens. Track rehabilitation machine according to one of the preceding claims,
characterized by a PSS insertion device (70), which is arranged in the direction of travel during labor input between the first and the second insertion device and is adapted to apply a layer protection layer on the introduced from the first insertion device support layer. Track rehabilitation machine according to one of the preceding claims,
characterized in that the front, middle and / or rear Aushubkette (10, 30, 80) are supported on a bridge, which is in use of the machine on a first chassis, which is arranged in the direction of travel in front of the front Aushubkette, and a second Chassis, which is arranged in the direction of travel behind the rear loading device supported. Method of track-based trackside remediation in continuous motion, comprising the steps of: i. Excavating a first upper gravel layer of the old substructure of a track in a first step, ii. subsequent excavation of a second lower layer of the old substructure below the first upper layer in a subsequent step, iii. subsequent introduction of a base course material of the new substructure, iv. following introduction of ballast of the new substructure, characterized in that after lifting the first, upper layer and before lifting the lower layer in a second step, a lying between the first, upper layer and the lower layer middle layer of the old substructure is excavated, preferably all operations in a continuous process be carried out with a contiguous track construction train. Method according to claim 10,
characterized in that - In the first step, a shallow gravel layer is excavated. - In the second step, a below the shallow layer of gravel layer located middle layer, which consists of gravel and pollution fractions, is excavated, and / or - After lifting the middle layer, a lower layer located below the middle layer, which consists essentially of fine grain fractions, is excavated. Method according to one of the preceding claims 10 or 11, characterized in that the excavated in the first step gravel is processed, preferably mixed before introduction with Neuschotter and is introduced for the new ballast bed. Method according to one of the preceding claims 10-12,
characterized in that the excavated in the second step excavated material is processed, preferably mixed before introduction with virgin material and is introduced in the fourth step as a base course material. Method according to the preceding claim 12,
characterized in that during the preparation of the ballast components below a certain grain size are screened out of the excavated ballast and here either the excavated in the first step gravel or excavated after the second step excavated material from the lower layer in a common screening device is screened. Method according to the preceding claim 13,
characterized in that when processing the excavated material in the second step coarse fractions are crushed, gfs after they were filtered out of the excavated material in an upstream step.

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