Title of Invention

A METHOD FOR INDEXING A ROTATING TOOL AND A TOOL FOR MACHINING

Abstract 1. A method of indexing a rotating tool used in machining, in which method the tool is rotated around its axis (C) in a spindle (4) of a machine tool; and at least one cutting part (3) comprised by the tool is indexed relative to a body (1) of the tool in such a manner that the cutting part (3) has at least a first position and a second position , characterized by locking the indexed cutting part (3) immobile relative to the body (1) of the tool by means of a pressure medium operated actuator (7) comprised by the tool.
Full Text FORM 2
THE PATENTS ACT, 197 0 (39 of 1970)
COMPLETE SPECIFICATION (See Section 10, rule 13)
A METHOD FOR INDEXING A ROTATING TOOL , AND A TOOL FOR MACHINING
MANDREL OY of TUOMIOKIRKONKATU 36 A, FI-33100 TAMPERE, FINLAND, FINNISH Company
The following specification particularly describes the
nature of the invention and the manner in which it is to be
performed : -
GRANTED
19-07-2006
ORIGINAL 717/MUMNP/2004

A METHOD FOR INDEXING A ROTATING TOOL AND, A TOOL FOR MACHINING
FIELD OF THE INVENTION
[0001] The invention relates to a method of indexing a rotating tool
used in machining, in which method: the tool is rotated around its axis in a
5 spindle of a machine tool; and at least one cutting part comprised by the tool is
indexed relative to a body of the tool in such a manner that the cutting part has
at least a first position and a second position.
[0002] The invention further relates to a tool for machining, the tool comprising at, least a body, at least one cutting part, and means for indexing 10 the cutting part relative to the body into at least a first position and a second position.
BACKGROUND OF THE INVENTION
[0003] Different machine tools are used in machining, such as mill-ing machines, horizontal boring and milling machines and drilling machines.
15 Lathes may also comprise rotating tools. Machine tools comprise a spindle, in
which a tool can be arranged, which can be made to rotate around its axis by
rotating the spindle. The tool comprises a body having fastening means for
fastening the tool to the spindle. The tool further comprises at least one cutting
part having a cutting edge for detaching material from an object being ma-
20 chined. The cutting part typically comprises an insert, which can be replaced when required. The cutting part may comprise an insert holder for fastening the insert. Conventionally, the cutting part is preset by moving the insert holder relative to the body of the tool into an accurately predetermined position, after which it is locked immobile. The insert holder usually comprises a mechanical
25 locking, usually a screw locking, for holding the cutting part in the set position. Consequently, such a tool has only one fixed measure that can no longer be changed in the machine tool. For example, a special boring tool has to exist for each hole to be bored and having a different diameter. The problem herein is that the number of tools becomes large. However, there is not always suffi-
30 ciently space in the tool magazines of machine tools for all different tools, not to mention reserve tools. This presents a significant drawback particularly in automatic machine tools intended for unmanned drive. Furthermore, much time is taken by change of tools when machining with a tool having a special form, since a special tool, set to one measure, has to be retrieved for each
35 measure machined, which naturally impairs the performance of machining.


[0004] As a solution to the above problem, a tool for machining has been developed, wherein the cutting part can be moved relative to the body of the tool by means of an electric actuator. However, one of the drawbacks is that the electric conductor has to be led to the rotating tool through the spindle. 5 in addition, the machine tool has to comprise a special separate control appa-ratus for controlling the actuator. Consequently, an electrically controlled tool is subject to significant changes in conventional machine tools. Furthermore, an electrically controlled tool is susceptible to malfunction under demanding ma¬chine shop circumstances. A further drawback of an electrically adjustable tool 10 is its high price.
BRIEF DESCRIPTION OF THE INVENTION
[0005] The object of the present invention is to provide a new and improved method and tool for machining.
[0006] The method of the invention is characterized by locking the 15 indexed cutting part immobile relative to the body of the tool by means of a pressure medium operated actuator comprised by the tool.
[0007] The tool of the invention is characterized in that the tool
comprises at least one pressure medium operated actuator for locking the cu-
ting part into said indexed positions, and at least one conduit for leading pres-
20 sure medium to said actuator.
[0008] The essential idea of the invention is that the tool has one or
more cutting parts, at least one of which can be indexed into at least two posi-
tions. The indexed cutting part is locked immobile during machining by using
the pressure, medium operated actuator in the tool. The pressure medium,
25 such as for instance cutting fluid, can be led to the actuator from the spindle of
the machine tool along conduits comprised by the tool.
[0009] An advantage of the invention is that the cutting part of the
tool can be indexed and locked into predetermined positions with normal func-
tions of the machine tools and without electric or the like external means. Ac-
30 cordingly, the tool according to the invention can be arranged in a conventional
machine tool without any special accessories or essential variations. In addi-
tion, a pressure medium operated actuator endures well blows and vibration.
Furthermore, such an actuator can be used to relatively easily create suffi-
ciently strong fastening forces, rendering the tool solid and dimensionally accu-
35 rate.

[0010] The essential idea of an embodiment of the invention is that the actuator is pressure fluid operated. As pressure fluid, cutting fluid is used, which can be led from conduits in the spindle to the tool and further to the ac-tuator. The components existing in a machine tool and associated with the 5 feed and control of cutting fluid can thus be utilized for locking the cutting part.
[0011] The essential idea of an embodiment of the invention is that the movement of the spindle of the machine tool is utilized in indexing the cut-ting part. The tool may comprise means based on centrifugal force or moment of inertia, which, by the action of the rotating movement of the spindle, gener-10 ate a force that can be used for indexing the cutting part.
[0012] The essential idea of an embodiment of the invention is that the tool comprises a pressure medium operated device for indexing the cutting part. Said device can be operated with flushing medium.
BRIEF DESCRIPTION OF THE FIGURES
15 [0013] The invention is described in detail in the attached drawings,
in which
Figure 1 is a schematic side view of a; boring tool according to the invention, with the cutting part in a first position,
Figure 2 is a schematic side view of the boring tool of Figure 1 with 20 the cutting part in a second position,
Figure 3 schematically shows the principle of an alternative locking
construction,
Figure 4 schematically shows the principle of still another alternative
locking construction,
25 Figure 5 is a schematic side view of a drilling tool according to the
invention with the cutting part in a first (position,
Figure 6 is a schematic side view of the tool of Figure 5 with the cut-ting part in a second position,
| Figure 7 is a schematic side view of another drilling tool according to 30 the invention,
Figure 8 is a schematic sectional view of a milling tool according to
the invention, and

Figure 9 schematically shows the principle of a tool according to the
invention.
35 [0014] For the sake of clarity, the figures show the invention in a

simplified manner. Like parts are den6ted by like references.
DETAILED DESCRIPTION OF THE INVENTION
[0015] Figure 1 shows a boring tool comprising a body 1, a fasten-ing part 2 at one end of the body 1, and a cutting part 3 at the other end of the 5 body 1. There may be one or several cutting parts 3. The fastening part 2 may comprise a taper or other suitable means for fastening the tool to a spindle 4 in a machine tool. Furthermore, the fastening part 2 may be a separate piece de- tachable from and attachable to the body 1. Figure 2 shows the principle of an alternative fastening part 2. On the other hand, the fastening part 2 may refer
10 to a contact surface in the body 1 of the tool, to which one or more pieces can be fastened for fastening the tool to the spindle 4 of the machine tool. When the spindle 4 is rotated, the tool, arranged in the spindle 4 rotates around its longitudinal axis C. The cutting part 3 may comprise an elongated insert holder 5 and an insert 10 fastened thereto. The insert! 10 is an interchangeable part
15 made from a highly durable material and comprising at least one cutting edge. Alternatively, the cutting edge may be provided directly in the insert holder 5 or the like. The insert holder 5 is arranged transversely to the body 1 and its fas-tening is arranged such that, when required, the insert holder 5 can move in the radial direction A of the tool. The' insert holder 5 may be arranged to be
20 controlled and supported by guide surfaces or the like. Figure 1 shows the cut-ting part 3 in a first, i.e. inner position,, and Figure 2 shows the cutting part in a second, i.e. outer,position. Accordingly, the cutting part 3 has two positions, between which the cutting part 3 can be shifted when it is arranged in the spin-dle 4 of the machine tool. The mutual position of the cutting part 3 and the
25 body 1 can be affected by means of the rotating movement of the spindle 4, and a spring element 6 and an actuator 7. When the spindle 41 is rotated, the cutting part 3 is subjected to a centrifugal force tending to move the cutting part 3 in the radial direction A of the tool away from the body 1. In Figure 1, the cut-ting part 3 is drawn by means of one or more draw-springs 6 into the inner po-
30 silion and locked immobile by moans of the actuator 7 in such a monnor that
the cutting part 3 retains its inner position in spite of the machining forces and the rotation of the tool. When the locking is released for the duration of index-ing, the cutting part 3 moves into the outer position shown in Figure 2, by the
action of centrifugal force. The cutting part 3 can be locked to this outer posi-
35 tion by means of the actuator 7. The cutting part 3 can be moved back to the

inner position by releasing the locking achieved by the actuator 7 and by stop-ping the spindle 4, whereby the cutting part 3 is not subjected to centrifugal force, and the spring element 6 is able to pull the cutting part 3 to the inner po-sition. The cutting part 3 is then locked by means of the actuator 7, and ma-5 chining can be started. The tool may comprise fixed or adjustable contact sur- faces, against which the cutting part 3 settles tightly in the first and sepond po-sitions, respectively. The tool according to Figures 1 and 2 can be arranged for two different diameters to be machined, whereby fewer tools than previously can be loaded into the tool magazine of the machine tool. In addition, indexing
10 the cutting part 3 for different diameters is very fast compared with a situation where a conventional tool is replaced for each diameter. When the portion 'of tool replacement times relative to machining is small, good performance is achieved.
[0016] In the solution shown in Figures 1 and 2, cutting part index-
15 ing is arranged to be accomplished by rotating the spindle 4. Accordingly, cut¬ting part 3 indexing can be accomplished by using normal machining move¬ments of the machine tool, and no special devices are required. Furthermore, commands regarding movements required in indexing can be easily added to the programs of numerically controlled machine tools. Consequently, the tool
20 according to the invention is suitable for use in conventional machine tools without any changes.
[0017] The actuator 7 may be a pressure medium operated cylinder, whose piston or cylinder is arranged to press against the shaft of the insert holder 5 and cause the friction required in the locking between the cutting part
25 3 and the actuator 7. Alternatively, a pressure medium operated motor or an-other pressure medium operated device can be used for generating the re-quired fastening force. The actuator 7 can be operated by means of the pres-sure medium used in flushing the tool, the tool and the spindle 4 already com-prising conduits 8 required for leading pressure medium to the actuator 7.
30 Flushing refers to cooling and lubricating the cutting part 3, and to chip re-moval. The medium typically used for flushing is cutting fluid, but it can also be another fluid or gas, e.g. water or pressurized air. In other words, the actuator 7 can be controlled by controlling the normal flushing of the machine tool. The necessary control commands can be easily added to programs run in control
35 units 22 of numerically controlled machine tools In the tool, the flushing con- duit 8 can be branched such that a special conduit 40 leads to cutting part

flushing and another conduit to the actuator 7. During machining, cutting fluid
is fed, whereby the cutting part 3 obtains the required flushing and, at the
same time, the actuator 7 locks the cutting part 3 in its position. During index-
ing, however, cuttipg fluid is not fed at all.
5 . [0018] In some cases, the tool can be constructed such that the cut-
ting part 3 can be indexed into more than two different positions. In this case, the tool may comprise means for preventing the movement of the cutting part 3 in one direction, but allowing the stepwise movement of the cutting part 3 in another direction. Such a tool comprising several indexable positions can re-
10 place several conventional tools having a fixed setting.
[0019] Figure 3 shows, highly simplified, an arrangement based on
mechanical shape locking for locking a cutting part 3 into indexed positions.
For the locking, the shaft of an insert holder 5 is provided with slots 11a to 11c.
An actuator 7 may comprise a hydraulic motor 12 arranged to drive a rack bar
15 14 by means of a pinion gear 13, and further a locking piece 15 at the end of the rack bar 14.'In the situation shown in Figure 3, the cutting part 3 is in the innermost position, where it is supported against a supporting surface 16. When the locking piece 15 is released from slot 11a, and the tool is rotated around its axis C by means of a spindle 4, the cutting part 3 is subjected to
20 centrifugal force, which moves the cutting part 3 further at the next slot 11b, after which the cutting part 3 can again be locked by pushing the locking piece 15 into slot 11b. The cutting part 3 shown in Figure 3 can be indexed into a third position, allowing the cutting part 3 to be locked by means of slot 11c.
[0020] Figure 4 shows another alternative locking mechanism for
25 locking a cutting part 3 into indexed positions. For the locking, two pressure spaces 17 and 18, into which pressure medium pressure can be led from con-duits 19 and 20, are provided around the shaft'of an insert holder 5. In addi-tion, the shaft of the insert holder 5 is provided with a shoulder 21 for separat-ing the pressure spaces 17 and 18. The pressure surfaces of the shoulder 21
30 on the side of the pressure spaces 17 and 18 are substantially equally large. When a substantially equal pressure fluid pressure is led to the pressure spaces 17 and 18, the forces acting on the shoulder 21 are equal, allowing the cutting part 3 to be locked hydraulically in the desired positions.
[0021] The construction shown in Figure 4 can also be applied by
35 moving the cutting part 3 by means of pressure medium, not by means of the rotating movement of a spindle 4. In this case, leading pressure from a conduit

19 to the first pressure space 17 and releasing pressure via a pressure conduit
20 from the second pressure space ,18 allows the cutting part 3 to be indexed
into a first position. When the cutting part 3 is in the first position, the shoulder
21 is at least partly against the end of the second pressure space 18. When
5 the culling part 3 is indexed into a second position, pressure medium pressure
is led from Ihe conduit 20 to the second pressure space 18, and, correspond-ingly, pressure liquid is released along the conduit 19 from the first pressure space 17, whereby the shoulder 21 moves towards the end of the first pres-sure space 17. In this solution, both indexing and locking take place by means
10 of a pressure medium operated actuator 7. The actuator 7 can be operated by controlling the feed of cutting fluid. Instead of the construction shown in Figure 4, two or more separate hydraulic cylinders can be used for indexing and/or locking the cutting part 3.
[0022] Figure 5 shows a drilling tool for making holes provided with
15 a countersinking. The tool comprises a body 11 It may also comprise a fasten-ing part 2, from which it can be directly or by means of suitable means fas-tened to a spindle 4 of a machine tool. The front part of the bpdy 1 comprises a fixed cutting part 23 having an elongated spiral drill or the like. Furthermore, a substantially sleeve-like indexable countersinking cutting part 25 is arranged
20 around the body 1 of the tool. When (desired, the indexable cutting part 25 can be indexed into the rearmost position shown in Figure 5, and into the foremost position shown in Figure 6. Indexing allows the same tool to be used for slant-ing drilling holes having different depths. The cutting part 25 comprises one or more cutting edges 29. The inner surface of the indexable countersinking cut-
25 ting part 26 may be provided with one or more slanting guide grooves 26 and tho outer surfaco of the body 1 with countorparts 27 that fit in said guide grooves 26. When the spindle 4 starts to be rotated with a sudden movement or when the spindle 4 is abruptly stopped, a movement difference is generated between the body 1 and the indexable cutting part 25 because of the different
30 moments of incrtia of the pieces. Said movement difforence and the slanting guide groove 26 cause the indexable cutting part 25 to move in the axial direc-tion E of the tool, guided by the guide groove 26. Figure 6 shows the foremost position of the indexable cutting part 25. Rotation of the spindle 4 with an abrupt movement in the opposite direction results, by the action of moments of
35 inertia, in the generation of a movement difference that makes the cutting part 25 move back into the innermost position shown in Figure 5. Instead of the

guide grooves 26, other structures can naturally also be used, enabling the movement of the indexable cutting part 25, by the action of forces of inertia, in the axial direction of the tool. In accordance with the invention, axial movement of the indexable cutting part 25 is prevented by using a pressure medium op-5 erated actuator 7 arranged in the tool. The locking principle of the actuator 7 can be accordant with some of the above-described principles.
[0023] Figure 7 shows a drilling tool comprising a body 1, a fasten-ing part 2, a fixed cutting part 23, and an indexable cutting part 25. In this case, the cutting part 25 is tubular and arranged around the fixed cutting part
10 23. If the intention is to drill holes having a larger diameter D2 the cutting part 25 is indexed into its front position, whereby the hole to be machined gets a diameter corresponding to the ring cutting part 25. The tool may comprise a mechanism corresponding to the solution of Figure 5 for converting the move-ment difference, resulting from the moments of inertia, into an axial movement
15 of the tool. Soine of the above-described principles can be applied to locking
the cutting part 25.
[0024] Figure 8 shows a tool used in milling. Two or more cutting parts 3 are arranged in a front surface 1a of a body 1 of the tool on a prede¬termined circle relative to the longitudinal axis C of the tool. Each cutting part 3
20 comprises an insert holder 5 arranged by means of an axle 30 such that it is able to rotate around an axis G. One end of the axle 30 is provided with a power transmission element 31 for affecting the turning of the axle 30. The power transmission element 31 may comprise a latch mechanism, a ratchet mechanism or the like, whereby the axle 30 is arranged to turn in one direction
25 only. In addition, the power transmission element 31 positions the cutting part 3 in exactly the correct position. Furthermore, in connection with each cutting part 3 is an actuator 7 for locking the cutting part 3 immobile relative to the body 1. The insert holder 5 comprises at least two inserts 10a and 10b or cor-responding cutting edges, which can be turned in different positions by index-
30 ing the cutting part 3. In Figure 8, the outermost inserts 10a are indexed for machining. When the first inserts 10a are worn, the second inserts 10b can be indexed in place thereof. The momeVit of inertia can again be utilized in the indexing, i.e. by rotating the spindle 4 abruptly, a movement difference is gen-erated between the body 1 and the cutting parts 3, and it can be utilized to
35 make the cutting parts 3 turn around the axles 30 from one position into an-other. Alternatively, the cutting parts 3 can be indexed by means of a pressure


medium operated indexing device. In this case, the tool may comprise a hy-draulic motor arranged to turn the axle 30.
[0025] Figure 9 is a simplified figure of another arrangement based on mechanical shape locking for indexing a cutting part 3 and locking it into the 5 desired positions. For locking and indexing, the shaft of an insert holder 5 is provided with two. or, more slots 11a and 11b. The slots 11a and 11b are formed wedged, i.e. pushing a wedged Ipcking piece 15a, 15b into the wedged slot 11a, 11b by means of an actuator 7a, 7b results in that the locking piece 15a, 15b causes the insert holder 5 to move in direction A. The locking piece
10 15a, 15b thus indexes first the cutting part and then locks it in place. For the indexing, the distance between the slots 11a and 11b in direction A is arranged to deviate from the distance between the locking pieces 15a and fl5b in direc-tion A. In the situation shown in Figure 9, the cutting part 3 is in a first ppsition, the locking piece 15a provided with a wedged end being pushed into slot 11a,
15 whereby it has forced the cutting part 3 in direction A into the position shown in the figure. Indexing into a second position takes place by the first locking piece 15a being pulled from the first slot 11a, after which the second actuator 7b starts to pushithe second locking piece 15b into the second slot 11b. Since the centre axle of the second slot 11b and the centre axle of the second locking
20 piece 15b are at a distance from each other in direction A, pushing the wedged second locking piece 15b into the second slot 11b causes the insert holder 5 to be indexed. The wedged form thus causes what is called self-centring, and at the same time shape locking, too. There may be several indexable positions, and there may be a special slot, locking piece and actuator for each indexable
25 position. The actuator 7a, 7b may comprise a hydraulic motor 12a, 12b ar- ranged by means of a pinion gear 13a, 13b to drive a rack bar 14a, 14b, and further the locking piece 15a, 15b at the end of the rack bar 14.
[0026] Let it be stated that other mechanisms' and components known per se in the art can also be used to achieve the force required in the
30 indexing. Consequently, the elements used for the indexing may comprise e.g. pinion gears, rack bars, eccentric discs, etc.
[0027] The drawings and the related description are only intended to illustrate the inventive idea. The details of the invention may vary within the scope of the claims.
35 .

We Claim:
1. A method of indexing a rotating tool used in machining, in which method the tool is rotated around its axis (C) in a spindle (4) of a machine tool; and at least one cutting part (3) comprised by the tool is indexed relative to a body (1) of the tool in such a manner that the cutting part (3) has at least a first position and a second position , characterized by locking the indexed cutting part (3) immobile relative to the body (1) of the tool by means of a pressure medium operated actuator (7) comprised by the tool.
2. A method as claimed in claim 1, wherein by indexing the cutting part (3) by using the movements of the spindle (4) of the machine tool.
3. A method as claimed in claim 1, wherein by indexing the cutting part (3) by using the pressure medium operated actuator (7) comprised by the tool.
4. A method as claimed in any one of the preceding claims, wherein by directing, during the locking the pressure medium pressure used in flushing the cutting part (3) to the actuator (7).
5. A method as claimed in claim 2, wherein by utilizing the moments of inertia of the cutting part (3) and the body (1) in the indexing.
6. A method as claimed in claim 2, wherein by utilizing the centrifugal force directed to the cutting part (3) during rotation of the tool in the indexing.
7. A method as claimed in any one of the preceding claims, wherein by locking the movement of the cutting part (3) in the radial direction (A) relative to the body (1) of the tool by means of the actuator (7).

8. A method as claimed in any one of claims 1 to 6, wherein by locking the movement of the cutting part (3) in the direction (E) of the longitudinal axis of the tool by means of an actuator (9).
9. A method as claimed in any one of claims 1 to 6, wherein by locking the rotation of the cutting part (3) relative to its axle (30) by means of the actuator
(7).
10. A tool for machining, as claimed in preceding claims comprising at least a

body (1), at least one cutting part (3), and means for indexing the cutting part
(3) relative to the body (1) into at least a first position and a second position,
wherein that the tool further comprises at least one pressure medium
operated actuator (7) for locking the cutting part (3) into said indexed
positions, and at least one conduit (8) for leading pressure medium to said
actuator (7).
11. A tool as claimed in claim 10, wherein the body (1) of the tool comprises a fastening part (2) adaptable to a spindle (4) of a machine tool, and at least one conduit (8) extending from the fastening part (2) to the actuator (7), and along which conduit (8) medium used in flushing the tool is arranged to be led from the spindle (4) of me machine tool to the actuator (7).
12. A tool as claimed in claim 10 or 11, wherein the actuator (7) is hydraulically operated and arranged to be used by means of cutting fluid of the machine tool.
13. A tool as claimed in any one of claims 10 to 12, wherein the cutting part (3) comprises an insert holder (5), that at least one cutting edge is arranged in the insert holder (5), and that the actuator (7) is arranged to press against the insert holder (5) and lock the cutting part (3) immobile relative to the body (1) by means of friction.

14. A tool as claimed in any one of claims 10 to 12, wherein the cutting part (3) comprises an insert holder (5), that at least one cutting edge is arranged in the insert holder (5), and that the actuator (7) is arranged to be locked in the insert holder (5) by shape locking and to prevent a mutual movement of the cutting part (3) and the body (1).
15. A tool as claimed in any one claims 10 to 12, wherein the cutting part (3) comprises an insert holder (5), that at least one cutting edge is arranged in the insert holder (5), and that a first pressure space (17) and a second pressure space (18) are arranged around the insert holder (5), that the insert holder (5) comprises a shoulder (21) for separating said pressure spaces (17,18), that the pressure spaces (17,18) are connected to conduits (19, 20) for leading pressure medium into the pressure spaces (17,18), and that the movement of the insert holder (5) is arranged to be prevented by directing an equally strong force effect to the shoulder (21) from the side of the first pressure space (17) and the second pressure space (18).
16. A tool as claimed in any one of claims 10 to 15, wherein the tool comprises means for indexing the cutting part (3) by means of pressure medium.
17. A tool as claimed in claim 16, wherein the indexing means comprise at least a pressure medium operated first actuator (12a) and a pressure medium operated second actuator (12b), that the first actuator (12a) is arranged to move a first locking piece (15a), and the second actuator (12b) is arranged to move a second locking piece (15b ), that the locking pieces (15a, 15b) are provided with wedged portions, that the locking pieces (15a, 15b) are placed at a first distance form each other, that the cutting part (3) comprises an insert holder (5), in which at least one cutting edge is arranged, that the insert holder (5) has at least a first slot (11a) and a second slot (lib) at a second distance from each other, that the slots (11a, 11b) are formed wedge-like that said first distance and second distance are unequal, and that pushing the

Documents:

717-mumnp-2004-cancelled pages(19-07-2006).pdf

717-mumnp-2004-claims(granted)-(17-07-2006).pdf

717-mumnp-2004-correspondence(29-03-2007).pdf

717-mumnp-2004-correspondence(ipo)-(14-03-2007).pdf

717-mumnp-2004-drawing(19-06-2006).pdf

717-mumnp-2004-form 19(13-12-2004).pdf

717-mumnp-2004-form 1a(13-12-2004).pdf

717-mumnp-2004-form 2(granted)-(17-07-2006).pdf

717-mumnp-2004-form 3(13-12-2004).pdf

717-mumnp-2004-form 3(19-07-2006).pdf

717-mumnp-2004-form 5(13-12-2004).pdf

717-mumnp-2004-form-pct-isa-210(13-12-2004).pdf

717-mumnp-2004-other documents(13-12-2004).pdf

717-mumnp-2004-power of attorney (09-02-2005).pdf

abstract1.jpg


Patent Number 206327
Indian Patent Application Number 717/MUMNP/2004
PG Journal Number 42/2008
Publication Date 17-Oct-2008
Grant Date 24-Apr-2007
Date of Filing 13-Dec-2004
Name of Patentee MANDREL OY
Applicant Address TUOMIOKIRKONKATU 36A, FI-33100 TAMPERE, FINLAND.
Inventors:
# Inventor's Name Inventor's Address
1 MR. KALLE PELTONEN RUOVEDENKATU 9 B 37, FI - 33720 TAMPERE, FINLAND.
2 MR. MARKUS REINIKKA NAYTTAMONKATU 4 E 39, FI-33720 TAMPERE, FINLAND.
PCT International Classification Number B23Q 16/08
PCT International Application Number PCT/FI03/00518
PCT International Filing date 2003-06-26
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 20021289 2002-06-28 Finland