EP1511606A1

EP1511606A1 - Method and device for the production of a precise concrete prefabricated part

Info

Publication number: EP1511606A1
Application number: EP03712020A
Authority: EP
Inventors: Stefan BÖGL
Original assignee: Max Boegl Bauunternehmung GmbH and Co KG
Current assignee: Max Boegl Bauunternehmung GmbH and Co KG
Priority date: 2002-06-13
Filing date: 2003-03-14
Publication date: 2005-03-09
Anticipated expiration: 2023-03-14
Also published as: CN1659004A; RU2316425C2; ES2287452T3; ATE362418T1; EP1511606B1; RU2005100521A; WO2003106128A1; US8439725B2; PT1511606E; DE10226407A1; JP2005534523A; US20050241262A1; AU2003218765A1; CN100358696C; DE50307298D1

Abstract

With a method for the production of a precise prefabricated concrete part, especially in the form of a sleeper or a plate for a fixed track for rail-guided vehicles, the prefabricated concrete part is ground at the functionally relevant points to the predetermined size by means of a grooved roller. The device for this is a grinding machine with a grooved roller to grind the prefabricated concrete part at functionally relevant points to a predetermined size. The grooved roller is made of a wear resistant material, especially silicon carbide.

Description

Method and device for producing a precise

Concrete component

The present invention relates to a method for producing a precise precast concrete part, in particular in the form of a threshold or a plate for a solid carriageway for rail-guided vehicles, and a corresponding device for producing a precise precast concrete part.

As precast concrete parts, for example, solid carriageways for rail-guided vehicles, wall elements, beams or supports are manufactured. In most applications of precast concrete parts, no particular precision is required with regard to the dimensions of the part. The usual tolerances that can be achieved in the concrete trade are sufficient. If other components are installed on the precast concrete parts, which must adhere to particularly tight tolerances, this is usually done with one-piece devices, so that inaccuracies resulting from the concrete can be compensated for. In particular in the production of solid carriageways, as are known, for example, from DE 197 33 909 A1, rail fastenings are therefore used at the individual support points, which make the rail adjustable in several directions in order to maintain the tight tolerances between the individual rails to be able to. In addition, elastic intermediate layers between the precast concrete and the rail are used, which have different thicknesses in order to be able to position the rail head at the required height. As a result, many intermediate layers of different thickness are required in order to be able to compensate for the relatively large tolerances of the concrete part. The intermediate layers and the adjustable rail fastenings are complex to manufacture, assemble and stock. The object of the present invention is therefore to create a method and a device with which prefabricated concrete parts can be produced, which allow tighter tolerances for add-on parts than were previously possible. This considerably reduces the effort for the manufacture, equipment and assembly of the concrete components as well as the rails and their fastening.

The object is achieved by the features of the independent claims.

According to the invention, in a method for producing a precise precast concrete part, in particular in the form of a threshold or a plate for a solid carriageway for rail-guided vehicles, the precast concrete part is ground to the predetermined dimension at the functionally relevant points using a profile roller. The profile roller has the negative shape of the cross-section to be created, which the precast concrete part should have at the function-relevant point (s). This is particularly advantageous at the support points at which rails are attached to the precast concrete part. However, other parts, such as assembly grooves, can also be prepared for the connection of two successive precast concrete parts using the method according to the invention. By grinding the precast concrete part with a profile roller, it is possible to achieve particularly tight tolerances, but the manufacture can nevertheless be carried out very quickly and inexpensively.

In contrast to the milling cutters customary in the prior art, which process the precast concrete part, the part can be grinded with a profile roller to create a much smoother and more precise surface. Rails or other precast concrete components can be attached to this surface with tolerances in the range of a few tenths of a millimeter. In the case of high-speed vehicles in particular, this is very advantageous for smooth and comfortable running of the rail vehicle. The profile roller can be used to produce the same shape at a number of support points for the precast concrete element in one operation. Bases, which are arranged one behind the other in the longitudinal direction of the precast concrete element, are ground without any settling by the feed of the profile roller along the longitudinal direction of the precast concrete element. This enables particularly fast and precise production, since the profile roller and the precast concrete part are moved relative to one another without the position of the profile roller having to be redetermined. In spite of everything, it is also possible that the profile roller can be moved not only linearly in the x-direction, but also in the y- and z-direction of the precast concrete element in accordance with a predetermined program. In this way, curves of a rail can also be realized on the precast concrete part.

The profile roller is advantageously designed such that it is used for roughing and finishing. When roughing the precast concrete part, a larger volume is removed in one production run. A material removal of 1 - 1.5 mm per pass has proven to be advantageous. Roughing already creates the rough contour of the functionally relevant point that will be required later. If necessary, roughing can also be carried out in several passes, especially if a larger amount of concrete has to be removed at the functionally relevant point. After roughing, the function-relevant point is finished with the same profile roller or with another profile roller. Material is removed at a height of approximately 1/10 - 2/10 mm. A particularly fine surface is achieved by the finishing, which moreover has small tolerances, so that a threshold or a plate for a solid carriageway is produced which is suitable for the highest speeds of rail-guided vehicles.

If the same profile roller is used for roughing and finishing, it is advantageous if the profile roller is dressed between roughing and finishing. Due to the large amount of material The shape of the profile roller may have been damaged. By dressing, the exact shape of the profile roller is restored after roughing, so that the permissible tolerance for finishing is precisely maintained.

If the precast concrete is hardened after concreting and before grinding by storage for several days, it will no longer change inadmissibly later and the machined area will therefore also maintain the machined dimension. If other components, such as rails, for example, are then mounted on the solid carriageway, these are also connected very precisely to the component.

In particular, solid carriageways can be designed so that the functionally relevant steep surfaces are of relatively small dimensions. For this purpose, it is advisable, for example, to form the solid carriageway with bumps, which represent the bases for the tracks. It is therefore only necessary to edit these bases. However, other forms can also be produced using the method according to the invention. For example, contact points between two successive plates which are to be connected to one another can be processed by the method according to the invention. As a result, the plates can be positioned very precisely in relation to each other. The same also applies to any connecting elements that may have to be installed, which are also to be used very precisely in the concrete body processed using the method. The rest of the precast concrete part can be within a tolerance range as is customary for the production of precast concrete parts. A corresponding precast element can also be manufactured by appropriate processing of the functionally relevant points. It is thus possible to achieve radii on fixed carriageways, which are composed of a plurality of rectilinear plates in a polygonal manner, by machining the corresponding support points. If the unfinished part is stored for its processing, in particular according to its later assembly position, the ground, functionally relevant points will also maintain their tolerances to one another when the precast concrete part is assembled on the construction site.

If the blank is stored stress-free for its processing, for example with the aid of load cells, the component can be installed on the construction site in such a way that the full tolerance of the component is available. When using individual support points on the component, the result is that only long-wave tolerances from support point to support point occur, which are more tolerable than short-wave tolerances. Long-wave tolerances are less disturbing in high-speed driving than the short-wave tolerances, since the latter cause wear and a lack of comfort.

If the current wear of the tool is taken into account when processing the functionally relevant points, a further measure is taken to ensure that the required target dimension is obtained very precisely.

The machined points are advantageously checked with regard to the actual and target dimensions in order to determine whether the component is suitable for the intended place of use. Otherwise, the component is intended for another location, reworked or destroyed again.

If the lowest base point of the slab to be machined is used as the basis for machining the other base points of the slab, the precast concrete part can be brought into the required shape with the permissible tolerances simply by removing concrete. In this advantageous embodiment of the invention, it is not necessary that individual bases have to be built up with additional material. This means that the precast concrete can be processed very quickly. In order to be able to manufacture the precast concrete to the finished dimensions very quickly, it is planned to manufacture the unfinished part in circulation. For a particularly stable execution of the precast concrete element it is provided that fiber concrete is used.

The raw part can be machined on site at the construction site as well as advantageously on a processing machine, in particular a grinding machine. In this case, the achievable accuracies are higher than when machining on site.

The object is further achieved by a device for producing a precise precast concrete part, in particular in the form of a threshold or a plate for a solid carriageway for rail-guided vehicles, which is a grinding machine with a profile roller. With the profile roller, the precast concrete is ground to a predetermined dimension at the functionally relevant points. According to the invention, the profile roller consists of a wear-resistant material, in particular of silicon carbide. The grinding machine, on which a profile roller made of wear-resistant material is used, ensures that the profile, which is ground with the profile roller into the precast concrete part, is obtained with extremely low tolerances. The profile roller can be designed in different shapes to grind different shapes. It is thus possible, for example, to produce a finished part for a different type of mounting for rails from a blank. This gives advantages in the manufacture of the precast concrete element, which can be used universally for various types of installation. By using wearable material for the profile roller, a surface with a very low tolerance is surprisingly obtained despite the high wear. In contrast to milling in known methods, the grinding of the precast concrete part gives a much more exact surface. The wearable material of the profile roller is advantageously arranged on a steel shaft. The profile roller is attached to a spindle of the grinding machine by means of the steel shaft. After the wearable material has been worn to an admissible level, it can be reprocessed by applying wearable material to the steel shaft again.

If a dressing device can be added to the wear-resistant material of the profile roller, it can be ensured that the required shape of the profile roller for finishing the component is always exactly maintained. The shape transferred to the component by means of the profile roller is thus maintained as desired. In addition, a certain dimension is determined by the dressing, by means of which the delivery path of the tool can be exactly determined in order to achieve the required tolerance on the component.

A dressing device which has a diamond coating has proven to be particularly advantageous. The diamond coating is very resistant and thereby ensures that the dressing device reproduces the required shape of the profile roller without impermissible tolerances.

The profile roller advantageously has a diameter between 700 and 400 mm. As a result, peripheral speeds are achieved, which enable precise machining of the precast concrete part.

If the device is assigned a measuring system for measuring the tool and / or the machined function-relevant points of the precast concrete element, the actual and the target value of the tool and / or the precast concrete element can always be checked. This avoids inadmissible tolerances.

The profile roller is advantageously used for roughing and finishing the precast concrete part. This makes it a very efficient of the precast concrete can be achieved. When roughing, the profile roller already creates the desired shape of the function-relevant point, but still with an impermissible tolerance. The tolerance is brought into the permissible range by finishing the precast concrete part.

If the device has several profile rollers, several functionally relevant points can be processed simultaneously. This is particularly advantageous when processing a slab for a solid carriageway or a sleeper, since it enables the support points of two parallel rails to be processed in one operation. This also enables particularly fast and economical machining of the precast concrete part.

Further advantages of the invention are described in the exemplary embodiments below. It shows

FIG. 1 shows a top view of a precast concrete part,

FIG. 2 shows a cross section in the region of a support point for a rail,

Figure 3 shows a grinding device according to the invention.

FIG. 1 shows the representation of a plate 1 which was manufactured as a precast concrete part. A large number of such plates 1 are laid in a row and form a fixed track for a rail-guided vehicle. On the surface of the plate 1 bumps 2 are arranged in two rows along the long side of the plate spaced apart. Each hump 2 forms a base 3 for the storage of a rail. The support points 3 must be made with very small tolerances to one another in order to to ensure that the rails run as straight as possible. Tolerances of, for example, only a tenth of a millimeter are required.

Figure 2 shows a detailed view of a plate 1 with a rail base 3. The rail base 3 is arranged in the hump 2 as a recess. The rail base 3 has a defined shape, which is similar to a trough. The trough bottom serves as a support 4. A rail 5 is arranged on the support 4 with the interposition of intermediate layers 6. The rail 5 is fastened by means of screws 7, which are anchored in the concrete of the plate 1 by means of dowels 8, and by means of clips 9, which are supported on the support point 3 or an angle guide plate 10 and the rail foot 11. For the correct alignment of the rail 5 in the horizontal direction, the angle guide plates 10 are arranged between the flanks of the support point 3 and the foot of the rail 5. The rail 5 is held in the desired position in the horizontal direction by means of the angle guide plates 10. The angle guide plates 10 can be standard parts which are largely identical to one another. Through the exact manufacture of the shape of the support points 3 according to the invention, an exchange or any use of the angle guide plates 10 is possible when laying a rail 5.

This standardized use of angle guide plates 10 and intermediate layers 6 is created by processing the inside of the support points 3 and, if necessary, the support 4. This processing of the concrete on the sides of the trough and the trough bottom enables the exact alignment of the rail already by the manufacture of the slab 1. The dashed line indicates that the slab 1 is first produced with an oversize in the region of the support points 3. The exact shape of the trough, which is determined by the fastening means of the rail, is generated by the grinding device according to the invention. By processing the support points 3 with the grinding device according to the invention, more or less material can be removed on the side parts of the trough and on the support 4, so that the exact alignment of the rail 5 in the horizontal and vertical direction is largely due to the individual design of the rail support point 3 is specified. With this method it is even possible to realize radii or a polygon laying of the track simply by machining the bumps 2. The plates 1 are first manufactured as standard and only individualized by the grinding process. This enables a very fast and therefore inexpensive production of a large number of plates 1 from a single type of mold. A comparison to the previous production with assembly methods significantly faster production and laying of precast panels 1 makes the use of these systems as solid carriageways even more advantageous.

The shape of the base 3 is produced according to its trough cross-sectional shape transverse to the longitudinal direction of the rail 5 by a profile roller. The profile roller, which has the desired shape in cross section corresponding to the solid line of the base 3, grinds off the concrete at the required points and prepares the base 3 for the corresponding fastening devices for the rail 5.

In Figure 3, a grinding device according to the invention is shown outlined. The grinding device is designed as a portal grinding machine. A crossmember 17 is arranged on two bearings 16 so as to be displaceable in the x direction. For the individual positioning of the grinding device 15, two cross carriages 18 are assigned to the traverse 17. The sliding carriage 18 enables exact positioning of the grinding device in the y and z directions.

A drive 19 and a pivoting device 20 are provided on the sliding carriage 18, which are connected to a profile roller 21. The profile roller 21 is driven via the drive 19. The profile roller 21 is delivered to plate 1 by means of the portal grinding machine. The special shape of the profile roller 21 creates the shape of the base 3 on the hump 2 when grinding the plate 1. By shifting the crossmember 17 in the x direction, the profile roller 21 is guided over a large number of individual support points 3 on the plate 1, thus creating the mounting surface for the rail 5. By appropriately controlling the sliding carriage 18 in the y and z directions, the support points 3 can be positioned individually on the humps 2, so that even a curve or polygon laying of the rail is possible.

In the illustration in FIG. 3, various positions of the profile roller 21 are shown, which can take place through the displacement options of the crossmember or the displacement carriage 18 and the swivel device 20.

To produce the shape-specific support points 3, it is provided that the grinding device is moved one or more times over the plate 1 essentially in the x-direction by means of its crossmember 17. The profile roller 21 is brought up to approximately the desired target dimension of the base 3. The individual delivery steps can be relatively large. This roughing of the base 3 can be done very quickly. Only when the traverse 17 is last moved in the x direction via the plate 1 is the delivery path set lower. This results in a very precise shaping of the support point 3. In order to have a profile roller 21 available for this last work step, which corresponds as exactly as possible to the desired shape, the profile roller 21 is fed to a dressing device 25. The dressing device 25 consists of a diamond-coated dressing plate, which depicts the exact shape of the support point 3 in its cross section. By placing the rotating profile roller 21 on the dressing device 25, the profile roller 21, which in comparison to the dressing device 25 consists of the softer material, is adapted to the shape of the dressing device 25. In the final finishing, ie machining a thickness of just a few tenths of a millimeter Layer on the support points 3, this cross-sectional shape of the profile roller 21 is thus imaged on the support point 3. In this way, a very precise shape is achieved.

While it was always assumed in the prior art when machining precast concrete parts that a very hard and largely wear-free tool should be used in order to enable an exact shaping of the precast concrete part, the present invention assumes that the actual tool has a relatively high level Wear is subject. However, the last machining takes place only when the tool has been brought into the desired shape again and, if necessary, has been measured again. Surprisingly, it has been found that this device according to the invention and the corresponding manufacturing method enable a much faster and more cost-effective production of precast concrete parts with extremely precise shaping at at least some locations on the precast concrete part. This is particularly necessary for slabs of solid carriageways, since a very large number of slabs are required to create slab carriageways and these are laid very quickly. The time constraint in the manufacture of solid carriageways that has existed up to now can thus be significantly improved.

The present invention is not limited to the embodiments shown. The method according to the invention can also be used to produce other prefabricated concrete parts which require extremely precisely dimensioned points, in particular if these points have a longitudinal dimension with the same cross section, which can be ground. In addition, it is alternatively possible that the precast concrete part is moved to the grinding device and not, as in the exemplary embodiment shown, the grinding device with respect to a stationary plate. The method according to the invention can also be used to create connecting parts for the individual panels which are lined up in a row. For example, the end faces of the plates that abut each other are processed. Corresponding connecting elements can thereby connect the plates to one another in a precisely positioned manner. This is also an advantage if the panels are not laid in a straight line but in a polygonal manner. The end faces of the plates 1 can also be machined accordingly in this case.

Claims

Patent claims

1. A method for producing a precise precast concrete part, in particular in the form of a threshold or a plate (1) for a slab track for rail-guided vehicles, characterized in that the precast concrete part is ground to the predetermined size at the functionally relevant points with a profile roller (21) ,

2. The method according to claim 1, characterized in that the profile roller (21) is used for roughing and finishing.

3. The method according to one or more of the preceding claims, characterized in that the profile roller (21) is dressed between the roughing and finishing.

4. The method according to one or more of the preceding claims, characterized in that the precast concrete is cured after concreting and before grinding by storage for several days.

5. The method according to one or more of the preceding claims, characterized in that the functionally relevant points are support points (3) or mounting surfaces for the mounting of the rail (5) or contact points of several precast concrete parts, which are processed.

6. The method according to one or more of the preceding claims, characterized in that the blank is stored for its processing, in particular according to its later mounting position.

7. The method according to one or more of the preceding claims, characterized in that the blank is stored stress-free for its processing.

8. The method according to one or more of the preceding claims, characterized in that the current wear of the tool is taken into account when processing the functionally relevant points.

9. The method according to one or more of the preceding claims, characterized in that the machined points are checked with regard to the actual and target dimensions.

10. The method according to one or more of the preceding claims, characterized in that the lowest base to be machined (3) of the plate (1) is used as the basis for the processing of the other bases (3) of the plate (1).

11. The method according to one or more of the preceding claims, characterized in that the blank is manufactured in circulation and in particular from fiber concrete.

12. The method according to one or more of the preceding claims, since; characterized in that the raw part is processed on a processing machine, in particular a grinding machine (15).

13. Device for producing a precise precast concrete part, in particular in the form of a threshold or a plate (1) for a slab track for rail-guided vehicles, characterized in that the device is a grinding machine (15) with a profile roller (21) for grinding the precast concrete part at functionally relevant points to a predetermined size, and wherein the profile roller (21) consists of a wear-resistant material, in particular silicon carbide.

14. The device according to the preceding claim, characterized in that the wearable material is arranged on a steel shaft.

15. The device according to one or more of the preceding claims, characterized in that a dressing device (25) is deliverable to the wearable material.

16. The device according to one or more of the preceding claims, characterized in that the dressing device (25) has a diamond coating.

17. The device according to one or more of the preceding claims, characterized in that the profile roller (21) has a diameter between 700 and 400 mm.

18. The device according to one or more of the preceding claims, characterized in that the device is associated with a measuring system for measuring the tool and / or the machined function-relevant points of the concrete component.

19. The device according to one or more of the preceding claims, d characterized in that the profile roller (21) for roughing and

Finishing of the concrete component can be used.

20. The device according to one or more of the preceding claims, characterized in that the device has a plurality of profile rollers (21), so that several functionally relevant points can be machined simultaneously.