DE8612998U1 - Disc-shaped milling tool - Google Patents

Description

. The invention relates to a disk-shaped milling tool - ·. * Rait chisels arranged on the radial circumferential surface like round shank bits or the like »for milling in particular Asphalt or concrete pavements.

For repairing cracks that have formed along the road surface and that go down to the substructure can reach, it is known that the road surfaces having cracks through a trench-like opening in the Remove the road surface. The groove thus formed in the |

The road surface is then backfilled with asphalt. The disadvantage here is that a correct |

Connection with the layers of the pavement adjacent to the groove often cannot be achieved because of the impact surfaces of the introduced asphalt with the old road surface due to insufficient mechanical Connection faults can occur, which provide a level finish to the surface of the poured asphalt prevent with the existing road surface. Around worn or damaged pavements To overtake from asphalt or concrete, it is also necessary before the new road surface is laid remove the old worn or damaged pavement. The pavement in question can for this purpose. I.

B. be broken open with a hydraulic hammer. If '"

If only a half-sided expansion or only a partial repair of a roadway is desired, it is It is customary to cut the road surface to be removed from the remaining road surface by cutting or the like remove. In the case of a butt connection of the new road surface to the still existing road surface there is always the risk of road damage at the joints due to subsidence or mechanical effects or irregularities occur on the road surface. To prevent this, it has already been suggested to form the road joints stepped. This he

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however, requires extensive work to produce the / stepped joint section of the roadway, since between vertical cuts or the like different according to the requirements of the respective road surface directing depth of lane sections special work must be removed.

The object of the invention is to create a milling tool by means of which in one operation a road surface to be overhauled or renovated can be processed in such a way that the material

"Rial of the newly introduced road surface without damage

^ fations or subsidence with the remaining pavement enters into a permanent connection.

According to the invention. the problem is solved by a rotationally symmetrical base body, which is divided into two or more sub-areas is subdivided, of which one sub-area has a maximum diameter and the other sub-areas are arranged on one or both sides of the first sub-area in such a way that the diameter these sub-areas decrease in steps in the axial direction to the first sub-area, with the first Partial area and the other partial areas distributed over the circumference chisels such as round shank chisels or the like. are arranged.

Further refinements of the invention are described in the dependent claims and in more detail below explained on the basis of the exemplary embodiments shown in the drawings. It shows

1 shows a milling tool in a side view, and 2 and transverse view in the direction A-A

E ₄ Fig. 3 further ^{designs of milling tools in 1} ^ l to 10 each a side view, and a 'transverse view.

In Fig. 1 and 2, a milling tool 40 is shown which

., consists of a base body 8, which is supported by a wheel

wreath 43 and a wheel hub 27 is formed by means of Ribs 26 are integrally connected to one another. The peripheral surface of the wheel rim 43 is in two partial surfaces 10, 11, each of which has a diameter 13, 14 different from one another. About the Perimeter of the partial surfaces 10, 11 are distributed as a chisel

| _; Pick 4 arranged. Details of the milling

Tool 40 are explained in more detail below using the example of milling tool 1.

The milling tool 1 shown in Fig. 3 and 4 consists of a base body 9, which is supported by a wheel rim 25 and a wheel hub 27 is formed, which are integrally connected to one another by means of ribs 26. the The circumferential surface of the wheel rim 25 is divided into sub-areas 10,

, 11, 12 of different diameters 13, 14, 15 divided. The partial areas 10, 11, 12 are arranged so that the partial area 10 with the largest diameter 13 at the side edge 16 of the base body 9 and the partial surface 12 with the smallest diameter 15 on the side edge 17 of the base body 9 connects. The partial area 11 with the mean diameter 14 is located in the middle of the base body 9. Due to the partial surfaces 10, 11, 12, the peripheral surface of the base body 9 is thus step-shaped educated. Round-shank chisels 4 are distributed as chisels 18 on the partial surfaces 10, 11, 12 over their circumference arranged, which are welded to the base body 9 by means of their holding pieces 5. At each holding piece 5 a metal bushing 6 is arranged in which a hard metal insert 7 with a conical tip is rotatable

is stored. To operate the milling tool 1, the wheel hub 27 is mounted on a drive shaft of a construction machine pushed on and connected to this by means of screw bolts 24. The screw bolts 24 are indicated in FIG. 4 and can e.g. B. be guided through the wheel hub 27. But it is also possible for the screw bolts 24 to lead through openings in the ribs 26 and with a flange arranged on the drive shaft associate.

When rotating the milling tool 1 around the central axis [>

19 on a road surface, a section of the road is milled in this so that a cross-section Stepped profile is created. This step enables better interlocking of the new ones to be introduced Asphalt or concrete layer with the still standing Road surface.

In order to be able to carry out steps with further steps with a basic tool, it is possible to use the milling tool 1 to be widened by an additional disk wheel 23 or two additional disk wheels 22, 23. This embodiment of a milling tool 2 is shown schematically in FIGS. Through the main body of the milling tool 1, openings 20 are formed in the ribs 26 parallel to its central axis 19. the Openings 20 can be designed as bores. Through these openings 20 screw bolts 21 are performed, by means of which the disk wheel 22, the disk wheel 23 or both disk wheels 22, 23 with connected to the base body 9> can. In Fig. 5, an embodiment of a milling tool 2 is shown in which a disk wheel 22 with a relative to the diameter 15 smaller diameter 29 is connected to the base body 9 by means of screw connections 21 which are passed through the openings 20. An additional

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borrowed connection of the base body 9 with a disk wheel 23, the partial surface 30 of which has a larger diameter 28 than the partial surface 10, is shown in FIG. 5 and 6 represented by dashed lines. Also in the milling tool 2 according to FIGS. 3 and 4 are located on the Circumferential surfaces 10, 11, 12, 30, 31 as chisels 18 round sheep chisel 4.

7 to 10 show further milling tools 32, 33 I.

shown, which are used to repair cracks that have formed along the center of the roadway. These cracks can extend to the substructure.

The milling tool 32 shown in FIGS. 7 and 8 consists of | from a base body 34 which is i

and a wheel hub 27 is formed which are integrally connected to one another by means of ribs 26. The peripheral surface of the wheel rim 25 is subdivided into partial areas 10, 11 of different diameters 13, 14. The partial areas | 10, 11 are arranged so that the side edges 16 j of the partial surface 10 with the largest diameter 13 the Connect partial areas 11 with the smaller diameters 14. It is also possible to use one of the partial surfaces 11 to be formed with a diameter smaller than the diameter 14. As a rule, however, it is useful Provide the partial areas 11 with the same diameter 14 on both sides of the partial area 10. The partial area 10 with the largest diameter 13 is in the middle of the base body 3 * 1. Through the partial areas 10, 11 Thus, the circumferential surface of the base body 34 rises in a step-like manner towards the center of the milling tool 32 educated. On the partial surfaces 10, 11 are distributed over the circumference as chisels 18, those already described above Circular chisels 4 are arranged, which are welded to the base body 34 by means of their holding pieces 5. To operate the milling tool 32, the wheel hub 27 is on

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a drive shaft of a construction machine is pushed on and by means of the screw bolts 24 indicated in FIG. 8 ^ this ^ as connected to the milling tool 1.

When the milling tool 32 rotates about the central axis 19 on a road surface, a roadway section is created in this Milled in such a way that a symmetrical cross-section, sloping from both sides towards the milling center Stair profile is created. Crack formations are completely eradicated down to the substructure. With the in the milling wheel 41 arranged in the middle, the cracks in the substructure are milled out in the middle. The two sides of the crack overlying layers such as B. Binder and base layers are arranged with the milling wheel 41 on both sides milled smaller milling wheels 42. After removing the milled plaster, conventional mastic asphalt is used the cutout is closed and, if necessary, compacted in layers. The one when using the milling tool 32 achieved steps enable better interlocking of the newly poured mastic asphalt with the remaining road surface.

In order to be able to mill out further symmetrical steps with a basic tool, it is possible to use the Milling tool 32 by additional disk wheels 35, 36 to widen symmetrically, which like the disk wheels 22, 23 are designed as milling wheels. This embodiment a milling tool 33 is shown schematically in FIGS. 9 and 10. Through the base body 34 of the Milling tool 33, the openings 20 are formed in the ribs 26 parallel to its central axis 19. Screw bolts 21 can be passed through these openings 20, by means of which both disk wheels 35, 36 can be connected to the base body 34. In Fig. 9 an embodiment of a milling tool 33 is shown, in the two disc wheels 35, 36 with one

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compared to the diameter 14 of the partial surface 11 smaller but the same diameter 37, 38 with the base body 3 ^ are connected by means of bolts 21, which are through the z. B. formed as holes openings 20 are performed. Also in the milling tool according to FIGS. 9 and 10 are located on the circumferential side Partial surfaces 10, 11, 30, 31 as chisels, preferably round shank chisels 4.

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Claims (1)

Disc-shaped milling tool with chisels, such as round shank chisels, arranged on the radial circumferential surface od. The like. For milling, in particular, asphalt or concrete pavements, characterized by a rotationally symmetrical Base body (8), which is divided into two or more partial areas (10, 11, 12, 30, 31), of which one part area (10) has a maximum diameter (13) and the other part areas (11, 12, 30, 31) are arranged on one or both sides of the partial surface (10) in such a way that the diameter (14,15) of these partial areas (11, 12, 30, 3D decrease in steps in the axial direction to the partial area (10), wherein on the partial surface (10) and the other partial surfaces (11, 12, 30, 3D over their Scope distributed chisel (18) like round shank chisel (4) or the like. Are arranged. • BDRO MANCHIN! EDUARD- <SCHM | D-} 3: rR | \ S3E s, '">' " JfOop MÜNCHEN 90 TELEX 0 23 467 CwilD'd!) ''TEl'eg'rAmMe'PAVrANS MÜNOHeN 'TELEPHONE £ Ö8BD 60 2OÖ1 TELEFAX Q3 / Q2 CÖ895 051 62 06 ,; r "2, 2. Milling tool according to claim 1, characterized in that!> ι that the diameter (14; 14, 15) in addition to the part surface (10) arranged further partial surface (11) or further partial areas (11, 12; 11, 12, 31; 11, 12, 31, 30) are each constant. 3. Milling tool according to claim 1, characterized in that the diameter (14; 14, 15) in addition to the partial area (10) arranged further partial surface ("M) or further partial surface (11, 12; 11, 12, 31; 11, 12, 31, 30) decrease in the axial direction to the partial surface (10) in such a way that the partial surfaces (11, 12, 31, 30) is designed like a truncated cone with a diameter that decreases in the axial direction from the partial surface (10) are. 4. Milling tool according to claim 1 and 2, characterized in that the base body (8) with the partial surfaces (10, 11) is formed in one piece or in several pieces. b. Milling tool according to claims 1 and 2, characterized in that that the base body (9) with the partial surfaces (10, 11, 12) is formed in one piece or in several pieces is. 6. Milling tool according to claim 1 and 2, characterized in that in the one-piece or in several pieces formed base body (34) on both sides of the partial surface (10) in each case a partial surface (11) or (11, 12) is arranged. 7. Milling tool according to claim 1 to 6, characterized in that the base body (8, 9, 34) on a drive shaft is mounted and connected to this by means of screw bolts (24). I III I It t It ·· · »· ■ (·· I t 4 ι Λ · · · · ti lit * » · · · * 8i milling tool according to claim 1 to 6, characterized . J marked that in the main body (8) parallel to 'whose central axis (19) perforations (20) are selected forms, through which the screw bolts (21) are guided, by means of which one or both sides another Disc wheel (22, 23) with circumferential chisels (18) and different diameters (13, 14, 15) Diameters (28, 29) is attached. 9. Milling tool according to claim 1 to 6, characterized in that in the base body (34) parallel to the central axis (19) of which has openings (20), by means of which on both sides of the base body (34) each has a further disk wheel (35, 36) with circumferential chisels (18) and for the diameters (13, 14) different diameters (37, 38) is attached. 10. Milling tool according to claim 9, characterized in that the diameters (37, 38) are the same size. 11. Milling tool according to claim 7 to 9, characterized in that that the openings (20) are formed in the ribs (26) which the wheel hub (27) with the integrally connect the wheel rim (25, 39) having the partial surfaces (10, 11, 12; 10, 11).