The present invention is directed to an insertion tool for an angle grinder according to the definition of the species in claim 1. The present invention is also directed to a system composed of an insertion tool with a hub and a driving device for an angle grinder according to the definition of the species in claim 11.
Publication WO 03/097299 makes known an insertion tool—which represents the general class—for an angle grinder that includes a hub with a plurality of fastening means in the form of recesses. The insertion tool can be advantageously clamped onto a driving device of the angle grinder using a keyless system, which is also known from the publication cited above.
The present invention is directed to an insertion tool for an angle grinder that has a hub with at least one fastening means for fastening the hub to a driving flange of the angle grinder.
The present invention is also directed to a system composed of an insertion tool with a hub and a driving device for an angle grinder, the hub including at least a first fastening means, and the driving device including at least a first fastening element for interacting with the first fastening means and for fastening the hub to the driving device.
It is provided that the first fastening means is located on a partial circle with a radius between 12 mm and 25 mm.
Due to the proposed dimension of the partial circle and, in particular, due to the further dimensions, embodiments and positionings proposed in the subclaims, an insertion tool can be obtained that is reliably and easily installable on an angle grinder, using a keyless system in particular, and that also enables handy use with sufficient working material. An insertion tool that is advantageously well-designed and matched to the driving flange can be obtained, and advantageous force distributions in the insertion tool and into the driving flange while working with the insertion tool can be achieved.
The means of achieving the object according to the present invention can be used with all insertion tools for angle grinders that appear suitable to one skilled in the art, such as rubber backing pads, cutting discs, rough grinding discs, grinding discs, etc. The hub can be made of a material out of which the abrasive body is made, or out of another material, such as sheet steel.
Further advantages result from the description of the drawing, below. An exemplary embodiment of the present invention is shown in the drawing. The description of the drawing contains numerous independent features, each of which independently improves the means of achieving the object according to the present invention. The means of achieving the object according to the present invention can be improved by one or more of these features without the need to add additional features from the description of the drawing.
When angle grinder 2 is viewed not from the top, as in
Hub 16 of insertion tool 12 configured as a rough grinding disc is designed to be inserted on a driving device 22 of angle grinder 2, which is shown in
These three snap-in bolts 36 are spring-loaded and can be pressed downward by an operator of angle grinder 2 by pressing on insertion tool 12. Hub 16 can now be pressed with its lower plate 34 until it reaches a base 38 of driving flange 22. As a result, fastening elements 40 configured as hooks pass through openings 42 in lower plate 34 of hub 16.
To fasten insertion tool 12 onto driving flange 22, hub 16 can now be rotated in the clockwise direction, which allows a radially innermost region 44 of lower plate 34 to be guided underneath encoding raised areas 28. At the same time, a retaining region 46 adjacent to openings 42 in lower plate 34 is slid under a slanted ramp element 48 of fastening element 40, fastening element 40 being pulled slightly upward against the force of a non-shown, preloaded spring. An exact description of driving flange 22, spring-loaded snap-in bolt 36 and fastening elements 40 is provided in publication WO 03/097299 described initially.
When insertion tool 12 is rotated further in the clockwise direction, retaining region 46 is slid under a retaining element 50 oriented parallel to base 38 of driving flange 22 that presses hub 16 onto base 38 with the aid of the preloaded, not-shown spring. When a fastening position is reached, snap-in bolts 36 are aligned with pot-shaped recesses 52 in hub 16 and engage ino these recesses 52 by snapping upward. Recesses 52 are designed as deformations of lower plate 34; they are shown in
Hub 16 also includes three identically configured openings 42 as the second fastening means. These second fastening means are configured in the shape of two parallel slots oriented in tangential direction 30. The slots are substantially right-angled and abut each other along part of one of their long sides. Openings 42 include a first retaining region 62 formed by the radially inward slot with a radial width 64 of 3.9 mm. In a releasing region 66 formed by the two slots, opening 42 has a radial width 68 of 7.1 mm. In a third region 70 which also belongs to retaining region 66, radial width 72 of opening 42 is 3.4 mm. In tangential direction 30, each of the three openings 42 extends across an angular range 74 of approximately 60°. Openings 42 also include blocking elements 76 designed as bulges, each of which abuts the radially inner slot and extends into releasing region 66. Blocking elements 76, in turn, include a stop 78 provided to limit a releasing motion of fastening element 40 in opening 42.
Due to the fact that openings 42 are formed by two right-angled slots, a particularly stable retention of hub 16 on driving device 22 in the axial direction can be achieved using fastening elements 40 that are simple and economical to produce. In addition, with the dimensions indicated, a laterally-reversed installation of insertion tool 12 onto an identical driving flange without encoding raised areas 28 can be effectively prevented, since fastening element 40 cannot be inserted through a laterally-reversed opening 42 if it has the dimensions indicated below.
To release hub 16 from driving device 22 shown in
In its radially inward region, hub 16 is designed with a well-shaped recess 84 with a well depth 86 of approximately 6 mm and an inner diameter 92 of 47 mm. An inner well wall 88 is thereby formed, with openings 42 being located at minimum distance 90 of approximately 2 mm from inner well wall 88. As a result of this relatively radially far outward positioning of openings 42 in hub 16, a stable axial fixing of hub 16 on driving device 22 via retaining elements 50 can be obtained.
When snap-in bolts 36 designed as fastening elements engage in recesses 52, snap-in bolts 36—which have an outer diameter 94 of 5.5 mm—are located in recesses 52 with a play of 0.5 mm. This relatively large amount of play makes it possible for snap-in bolts 36 to also engage in recesses 52 when snap-in bolts 36 or recesses 52 are very dirty. As a result, a secure fixing of insertion tool 12 in tangential direction 30 can be ensured, even when insertion tool 12 is very dirty.
Due to the large amount of play—which serves to provide operational reliability—between snap-in bolts 36 and recesses 52, hub 16 cannot be retained in a centered position on driving device 22 by snap-in bolts 36. Centering of this type, which is necessary, is achieved by the dimensions of centering opening 26 and centering collar 24, the play of which relative to each other is less—by a factor of approximately 17—than the play between snap-in bolts 36 and recesses 52. Inner radius 96 of centering collar 26 is 11.1 mm, while the outer radius 98 of centering collar 24 is 11.115 mm. Since centering collar 24 and centering opening 26 are circular in design, the play between centering collar 24 and centering opening 26 is 0.03 mm.
Due to the relatively large amount of play between snap-in bolts 36 and recesses 52, the contact surface between snap-in bolts 36 and recesses 52 attainable via elastic deformation can be very small during operation of insertion tool 12. So that the resultant wear of snap-in bolts 36 remains minimal, snap-in bolts 36 are made of a hardened steel, while recesses 52 in hub 16 are made of an unhardened metal, e.g., unhardened steel sheet. During operation of insertion tool 12, snap-in bolts 36 can extend into recesses 52 and deform them slightly, so that a sufficiently large contact surface between snap-in bolts 36 and recess 52 results, which results in low wear of snap-in bolts 36 even when insertion tool 12 undergoes strong vibration.
Number | Date | Country | Kind |
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10360248.8 | Dec 2003 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP04/52876 | 11/9/2004 | WO | 1/13/2006 |