Machine for machining and deflashing tires

Information

  • Patent Grant
  • 6655438
  • Patent Number
    6,655,438
  • Date Filed
    Thursday, April 25, 2002
    22 years ago
  • Date Issued
    Tuesday, December 2, 2003
    20 years ago
Abstract
A machine for machining and deflashing tire treads, having a frame, a drum for supporting the tire and rotating it about its axis, a cylindrical cutting tool and means for orienting the tool in various directions with respect to the tire, including means allowing rotation of the tire to be reversed and means for arranging the tool to work in two substantially symmetrical positions relative to the tire, a first position for cutting proper and a second position for deflashing, each of said positions corresponding to an opposite direction of rotation of the tire.
Description




BACKGROUND OF THE INVENTION




1. Technical Field of the Intention




The present invention relates to a device for machining viscoelastic products: more precisely, it relates to a machine for machining and deflashing rubber products such as tires.




2. The Related Art




Tires are known to comprise a tread consisting of an outer layer of rubber-based mixtures, of greater or lesser thickness, in which are molded various grooves and tread patterns intended, inter alia, to improve the vehicle's grip relative to the ground.




In certain cases, it is necessary to machine the outer surface of the tire: for example, to prepare for retreading of a worn tire or, indeed, to obtain a “worn” tire from a new tire, with a view to performing certain tests on the rigid belt, or on the carcass, without being hampered by the very considerable heating associated with the thickness of the rubber of the new tread during the tests.




In the first case (retreading), tires are often machined by abrasion (see for example International Publication No. WO 00/15388), but this process causes superficial heating which it is sometimes desirable to avoid. Moreover, a good surface state is sometimes required; a cutting process is then used. In general, the tire is made to turn about its axis and is moved towards the tool by translational movement of part of the frame (see for example U.S. Pat. No. 4,036,275).




The cutting tools used are generally cylindrical, that is to say, the cutting edge of the blade is circular (see for example U.S. Pat. No. 3,426,828 or U.S. Pat. No. 4,036,275) and the cut material passes inside the cylindrical tool and is discharged in the form of a strip.




When a patterned tire tread is machined by a cutting process, the formation of flash is noted to the rear of the tool at the edges of the grooves in the tire. Until now, this flash did not constitute a particular problem, but, confronted with increased quality requirements and the increasing severity of tests, it has become necessary to remove this flash in certain cases.




The invention relates to a machine for machining and for deflashing tire treads after a cutting machining operation which allows the same machine to be used for cutting and deflashing without having to remove the tire.




SUMMARY OF THE INVENTION




According to the invention, a machine for machining and deflashing tire treads comprises a frame, a drum for supporting the tire and rotating it about its axis, a cylindrical cutting tool and means for orienting the tool in various directions with respect to the tire, and further comprises means allowing rotation of the tire to be reversed and means for arranging the tool to work in two substantially symmetrical positions relative to the tire, a first position for cutting proper and a second position for deflashing, each of said positions corresponding to an opposite direction of rotation of the tire.




The machine according to the invention thus has the advantage of ensuring deflashing of the tire while retaining excellent machining precision. This is a substantial advantage over a machine which would require turning the tire round on its axis and causing it to turn in the reverse direction in front of the same tool, because removing and replacing the tire on its drum would involve loss of tire machining precision.




In a preferred variant, the tool comprises two circular cutting edges, each capable of occupying one of the two symmetrical positions.




Preferably, in the first position, the tool exhibits a cutting angle alpha and the tire an appropriate direction of rotation and, in the second position, the tool exhibits a cutting angle minus alpha and the tire the opposite direction of rotation to the above.




In another preferred variant, the cutting edge of the tool comprises at least one notch, that is to say, a portion having a lower axial length. This allows automatic division of the strip of cut material into shorter pieces and the prevention of jamming.




Of course, the machine according to the invention may be used in the conventional manner, that is to say, with a single machining stage, without then switching tool position and reversing tire rotation This is the case, for example, when the tire is being completely stripped of tread and there will not therefore be any flash to remove.











BRIEF DESCRIPTION OF THE DRAWINGS




An example of an embodiment of the improved machine for machining and deflashing tire treads according to the invention will be described, in non-limiting manner, with reference to the attached drawings, in which:





FIG. 1

is a schematic view of a tire machining and deflashing machine according to the invention;





FIGS. 2



a


and


2




b


show schematically the formation of flash during machining of the tread of a tire;





FIG. 3

is a view of the tool holder of a machine according to the invention, in the machining position;





FIG. 4

is a view similar to

FIG. 3

, in which the tool holder is in the deflashing position;





FIG. 5

is a view from above of an embodiment of a cylindrical tool;





FIG. 6

is a view from the side of the tool of

FIG. 5

; and





FIG. 7

is a view from the side of another embodiment of a cylindrical tool.











DESCRIPTION OF EXEMPLARY EMBODIMENT





FIG. 1

is a highly schematic view of a machine for machining tire treads according to the invention. The machine comprises a first fixed frame


1


supporting a drum (not shown) on which is mounted a tire


2


. The machine also comprises a mobile frame


3


supporting a tool holder


4


. The frame


3


is mounted on a fixed base


5


by means of two pairs of horizontal rails


6


and


7


. The rails


6


are oriented perpendicularly to the axis of rotation


8


of the tire and permit translational movement of the frame


3


towards or away from the tire


2


. The rails


7


are oriented parallel to the axis of rotation


8


of the tire


2


and permit translational displacement of the frame


3


parallel to the axis of rotation of the tire


2


. The combination of these two translational movements allows the cutting tool to follow all the conventional tire profiles. The frame


3


also allows vertical displacement of the tool holder


4


, due to conventional means which are not shown. The machine additionally comprises means (not shown) of setting the tire


2


in rotation, of reversing its direction of rotation and of controlling the displacements of the mobile frame


3


and the vertical position of the tool holder


4


. Such means are also conventional.




The tool holder


4


is intended to hold a cutting tool comprising two cylindrical cutting tools


19


and


20


.

FIG. 1

shows the tool


19


in position for machining the tire


2


. The tool holder


4


may swing vertically about the horizontal axis


25


in order, as described below, to bring the cutting edge of the tool


20


into contact with the tire


2


.





FIGS. 2



a


and


2




b


show schematically the formation of flash


11


when the cutting edge of a cutting tool


12


arrives on a level with a groove


13


in the tread


14


of the tire.

FIG. 2



a


shows a cutting tool moving in the direction of arrow A relative to a groove


13


in the tread of the tire. As the groove


13


is still at a distance from the cutting tool


12


, the latter easily severs the strip


15


from the surface of the tread


14


. On the other hand,

FIG. 2



b


shows that, when the cutting tool


12


passes thereover, the edge of the groove


13


bends under the action of said tool


12


and moves out of the way without being cut, giving rise to flash


11


. The plasticity of the material no longer offers sufficient resistance to the tool to ensure a clean cut. When a very good surface state is desirable, it is necessary to remove this flash. The deflashing operation could be performed manually, if there is only a little deflashing required, or by turning the tire


2


round on its drum and making it turn in the opposite direction in front of the same cutting tool, which would allow the flash to be picked up from the opposite direction and severed. However, it will be understood that this process requires time for removing and replacing the tire and that it causes offsets or misalignments which, even when slight, detract from the precision of the surface state of the machined tread.




According to the invention, the tool holder


4


allows a cutting tool to be presented in two symmetrical positions relative to the tire.




In a preferred variant of the invention illustrated in

FIGS. 3 and 4

, two tools


19


and


20


are used, each comprising a circular cutting edge


21


and


22


and mounted opposite one another. These tools are fixed in a support


18


driven in rotation about its axis


26


, in a ball cage


23


, by a geared motor unit


24


. Rotation of the cutting tools about their axis


26


facilitates machining and deflashing of the tire. It also increases the service life of the cutting edges between two sharpening operations.




The tool holder assembly


4


is mounted rotationally about a horizontal axis


25


substantially parallel with that of the tire, which allows adjustment (due to means which are not shown) of the cutting angle α or −α of the tool


19


or


20


. The cutting angle α is defined as the angle between the line normal to the tread at the point of contact and the axis of rotation


26


of the tools


19


and


20


.





FIG. 3

shows the tool


19


in position for machining the tread


14


of the tire


2


(cutting edge


21


in action), while

FIG. 4

shows the tool


20


in the deflashing position (cutting edge


22


in action). According to the invention, between the two stages the tool holder


4


has been swung about the axis


25


, the vertical and horizontal positions of the tool holder


4


have, if necessary, been adjusted relative to the tread


14


of the tire


2


, and the direction of rotation of the tire


2


has been reversed (arrows F and F′). The cutting angle is then −α.




It will be seen that, in addition to the substantial advantage of the invention, i.e. the fact that it is not necessary to turn the tire around on its drum, an important advantage of this variant resides in the fact that, by virtue of the two cutting edges of the cutting tool, the tool is set very rapidly and very easily in action, and moreover with maximum precision. This results in an extremely precise tread surface state.




According to the invention, the two positions of the tool (shown in

FIGS. 3 and 4

) are symmetrical relative to the tire, i.e., in the two stages, small and substantially equal cutting angles α and −α are used. It will be noted, however, that the point of application of the cutting tool on the surface to be machined may be slightly different. Without entering into detail about technology which is well known, the assembly of mechanical means described above allows extremely precise adjustment of the tool position.




The cutting tools


19


and


20


may be cylindrical tools with a circular cutting edge, as described in U.S. Pat. No. 4,036,275, the disclosure of which is hereby incorporated herein by reference.





FIGS. 5 and 6

show a preferred variant of a cutting tool according to the invention. The tool


30


is shown in a view from above in FIG.


5


and from the side in FIG.


6


. It comprises a cutting edge


31


having a plurality of notches


32


, that is to say, a lower axial height, i.e., zones having a shorter axial length (see FIG.


6


). The notches are preferably disposed in regular manner all round the cutting edge of the tool. The notches may be obtained simply by machining into the cylindrical surface of the tool situated on the same side as the cutting edge longitudinal grooves which open in the cutting edge in the form of said notches. In

FIG. 6

, it may be seen that the cutting edge of the tool is disposed externally and thus the grooves are themselves also effected externally.




In operation, the notches


32


allow the cut rubber strip to be divided into short portions and thus prevent a jam from forming in the cutting path.




The tool diameter may be of the order of 150 mm for example.




With a speed of tire rotation of the order of 100 to 500 rev/min, a diameter of the order of 1 m and a speed of tool rotation of the order of 55 rev/min, portions are obtained which are approximately 50 cm in length, instead of several meters.





FIG. 7

shows a second variant


40


of a cutting tool according to the invention. In this variant, it may be seen that the grooves


43


are helical instead of axial. Each notch


42


thus has inclined edges instead of normal edges, as is the case with the tool


30


. This effectively provides the cutting edge


41


of the tool


40


with a leading edge and a trailing edge, which may facilitate severing of the cut strips.



Claims
  • 1. A machine for machining and deflashing tire treads, comprising a frame, a drum for supporting the tire and rotating it about its axis, a cylindrical cutting tool and means for orienting the tool in various directions with respect to the tire, and further comprising means for allowing rotation of said tire to be reversed, and means for arranging said tool to work in two substantially symmetrical positions relative to the tire, a first position for cutting proper and a second position for deflashing, each of said positions corresponding to an opposite direction of rotation of the tire.
  • 2. A machine for machining and deflashing tire treads according to claim 1, in which said cutting tool comprises two circular cutting edges, each capable of occupying one of the two symmetrical positions.
  • 3. A machine for machining and deflashing tire treads according to claim 2, in which, in the first position, the tool exhibits a cutting angle alpha and the tire an appropriate first direction of rotation and, in the second position, the tool exhibits a cutting angle minus alpha and the tire the opposite direction of rotation to the first direction.
  • 4. A machine for machining and deflashing tire treads according to claim 2, in which each cutting edge of the tool comprises at least one notch.
  • 5. A machine for machining and deflashing tire treads according to claim 4, in which said at least one notch is formed by a groove in the cylindrical surface of the cutting tool, said groove having a lower axial height than that of said cutting edge.
Priority Claims (1)
Number Date Country Kind
01 05782 Apr 2001 FR
US Referenced Citations (11)
Number Name Date Kind
3426828 Neilsen Feb 1969 A
3953915 Fawcett et al. May 1976 A
3977131 Searle et al. Aug 1976 A
3980120 Fawcett et al. Sep 1976 A
4009499 Casler et al. Mar 1977 A
4036275 Branick Jul 1977 A
4112630 Brown, Jr. Sep 1978 A
4116256 Morris et al. Sep 1978 A
4486255 Crommelynck et al. Dec 1984 A
4663889 Strand et al. May 1987 A
5054971 Kieninger et al. Oct 1991 A
Foreign Referenced Citations (1)
Number Date Country
0015388 Mar 2000 WO