TOOLING FOR THE MACHINING OF MULTI-STAGE DISKS WITH PECM, ASSEMBLY AND ELECTROCHEMICAL MACHINING MAC

专利摘要:
Tooling (10) for producing cells of a multi-stage disk (1) by electrochemical machining. The tooling includes first and second coaxial disc-axis rings (20) configured to serve as cathodes, each ring having an inner periphery having a plurality of radial machining projections. The first and second rings (20) are rigidly attached to each other. Process for producing cavities of a multi-stage disk by electrochemical machining using such a tool
公开号:FR3042138A1
申请号:FR1559541
申请日:2015-10-07
公开日:2017-04-14
发明作者:Janvier Lecomte；Mickael Rancic；Sophie Tallon；Juri Kraft；Andreas Grutzmacher
申请人:SNECMA SAS；Pemtec AB；PEMTEC Inc；
IPC主号:

专利说明:

FIELD OF THE INVENTION
The present invention relates to a tool for producing multi-step disc cells by electrochemical machining, an assembly and a machine comprising such a tool, and a method using such tooling.
STATE OF THE PRIOR ART Multi-stage disk machining is generally done by broaching or milling then racking for the largest diameter stage, and by milling and then racking (excluding broaching) to machine the lowest diameter stage. . For each stage, several machining operations are necessary in particular a deburring operation is necessary after each broaching or milling operation. These technical solutions have the disadvantage of having a cost of operations and a high completion time, as well as a risk of breakage of the milling tools.
Another known technique to overcome these disadvantages is to use pulsed electrochemical machining (PECM). The document FR 3,006,925 describes a device and a method using this technical solution for producing cells on a single-stage piece.
PRESENTATION OF THE INVENTION
Also, the objective of the invention is to overcome the drawbacks of the previous methods and to make it possible to machine the different stages of a multi-stage disk in a relatively simple manner, in a relatively short time and by using a tool and a moderate cost machine.
This objective is achieved firstly by means of tooling for producing cells of a multi-stage disk by electrochemical machining, comprising at least first and second coaxial rings along a disk axis, configured to serve as cathodes, each ring having an inner periphery having a plurality of radial machining projections, the first and second rings being rigidly attached to each other.
By "fixed rigidly to one another", it is understood that the first and second rings are fixed so that when the tool moves, the first and second rings move simultaneously and identically. The shape of the radial machining projections, in axial view along the disk axis, corresponds to the shape of the cells to be made on the multistage disk. Furthermore, the inner diameter of the first ring is approximately equal to the outer diameter of a first stage of the disk, and the inner diameter of the second ring is approximately equal to the outer diameter of a second stage of the disk. Therefore, when the tool moves along the multi-stage disk axis, the first ring serving as a cathode makes it possible to make the cells of a first stage of the disk by electrochemical machining, and the second ring serving as a cathode makes it possible to make the cells of a second stage of the disk by electrochemical machining. The tooling makes it possible to machine the cells of each stage of the multi-stage disk by two successive or simultaneous electrochemical machining sequences, advantageously produced by means of the single tooling previously defined.
In some embodiments, the radial projections have, in axial view along the disk axis, a mushroom shape.
During machining, according to the PECM method, an electrolyte is injected which flows along said mushroom-shaped protrusions; simultaneously, an electric current of an anode (in this case the multi-stage disk) is circulated to the cathode; the passage of this current pulls metal atoms to the portion of the disk located in front of the cathode, so that the cells of each stage of the multi-stage disk have, after machining, the mushroom shape defined by the projections of the crown . Furthermore, the radial projections may have a mushroom shape whose dimensions differ between the first and the second ring. In addition, the radial projections are not limited to this form and may be different depending on the desired shape of the cells of each stage of the multistage disc after machining.
In some embodiments, the tooling further includes a cover in which the rings are attached, said cover being arranged around the rings and configured to prevent radial projections of the trickling electrolyte around the projections.
The cover is an outer envelope of the tool, containing the disk to be machined, the crowns and the electrolyte dripping along the crowns. Moreover, the crowns being fixed on an inner periphery of the hood, when the latter moves, the crowns move simultaneously. Furthermore, the cover has a plurality of passages to allow the injection and evacuation of the electrolyte.
In some embodiments, the cover comprises at least two parts electrically insulated from each other by an insulating element, on which are fixed respectively the first and the second ring.
Thanks to this, the tooling makes it possible to machine the first and second stages of the disc with different electrical parameters, and generally not at the same time. The insulating element is arranged to be interposed between the two bonnet parts, and to be located in an area between the first ring and the second ring along the disk axis. In one embodiment, when one of the rings is being machined, so electrically powered, another crown is not electrically powered. Thus, unwanted machining of certain areas of the disc is avoided.
In some embodiments, the tooling further comprises at least two movable guards integral with said cover, comprising fluid injection passages for injecting an electrolyte on the projections, said two movable guards respectively being adjacent to said first and second rings.
The at least two movable guards are generally fixed on the inner periphery of the cover, and have on their inner periphery a plurality of radial projections of identical shape to that of the first and second rings respectively. As the tool moves, the crowns move so that one of them mills a stage of the disc, and the insulating protector adjacent to said crown also moves while penetrating into the newly machined cell. The movable protector thus makes it possible to prevent electrolyte projections on already machined cell portions, thus avoiding undesirable machining of said cell portions.
The present disclosure also relates to an assembly comprising the tooling, the multi-stage disc, and at least one fixed protector configured to be fixed on the disc and to protect the disc from the electrolyte.
The fixed protector is a non-conductive member for protecting the disc from electrolyte, avoiding unwanted machining of surfaces adjacent to the disc stages to be machined. The fixed protector may further allow the evacuation of the electrolyte and the dissolved material after machining by directing the electrolyte to the hood exhaust passages.
The present disclosure also relates to an electrochemical machining machine comprising a support allowing the attachment of a multi-stage disk, the tooling, an actuator capable of operating relative movements of the tooling relative to the disk fixed on the support. the disk being at least partly inside the tooling; an electrolyte circuit and an electric circuit, the machine being configured to allow machining of a first stage of the disk with the aid of the first ring, and machining of a second stage of the disk with the aid of the second ring by electrochemical machining, during said movements.
The present disclosure also relates to a method for producing cells of a multi-stage disk by electrochemical machining using the tooling, the method comprising the following steps: a) Positioning the tool such that a first of said at least two rings in the vicinity of a first stage of the disk to be machined b) Machining the first stage of the disk by electrochemical machining by moving the tooling relative to the disk along the disk axis. c) Position the tool so that a second of said at least two rings is in the vicinity of a second stage of the disk to be machined. d) Machining the second stage of the disk by electrochemical machining by moving the tooling relative to the disk along the disk axis.
This method allows the realization of all these steps without the need to change tools. This generates a saving of time of realization.
In some embodiments, the method further comprises the following steps: - Cut off the power supply and electrolyte of the second ring, when the first ring is being machined during step b). - Cut the power supply and electrolyte of the first ring, when the second ring is being machined during step d).
These steps make it possible to avoid unwanted machining of certain areas of the disk, when one of the rings is being machined.
In some embodiments, at the machining step b) and / or d), the relative movement of the tool relative to the disc is a helical movement about the disc axis. BRIEF DESCRIPTION OF THE DRAWINGS The invention and its advantages will be better understood on reading the detailed description given below of various embodiments of the invention given as non-limiting examples. This description refers to the pages of appended figures, in which: - Figure 1 shows a partial perspective view of a multi-stage disk. FIGS. 2A and 2B are simplified representations of a disk, respectively before machining the cells (FIG. 2A), and after machining the cells (FIG. 2B). - Figure 3 shows a sectional view of the tooling for producing cells of a multi-stage disk. - Figure 4 shows in more detail a portion of a crown and an insulating protector. - Figure 5 shows schematically the electrochemical machining machine.
DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS
FIG. 1 represents a perspective view of a multi-stage disk after machining, here comprising a lower diameter stage IA, and a larger diameter stage IB, each stage having a plurality of cells 2. the structure of a disk of this type, it is understood that it is difficult to achieve the cells of a floor without damaging the other floor by the usual techniques (pinning, milling).
FIGS. 2A and 2B are simplified representations of a stage of a disc 1 before machining cavities 2 (FIG. 2A), and after machining cavities 2 (FIG. 2B), by a known method using an electrochemical machining method PECM ("Pulsed Electrical Chemical Machining"). The ring 20, serving as a cathode, is traversed by a pulsed current, and a pressurized electrolyte circulates between the ring 20 and the disc 1 to be machined. Initially, the ring 20 is in the high position, that is to say above the disk 1 (Figure 2A). The ring 20 is then translated towards the disc 1 along the axis of the latter, adopting a helical path with respect to the latter. When the ring is at the disk, successive pulses of current are triggered in the electrolyte. As the ring 20 serves as the cathode, and the disk 1 as anode, an ionic dissolution occurs. After machining, the ring 20 is in the low position, that is to say below the disk 1 (Figure 2B).
This machining principle is used by a tool 10, according to the invention, which is illustrated in FIG. 3. This tooling makes it possible to successively machine the IB stage of greater diameter of the disk 1, and the stage IA 1 is a sectional view of one half of the tool 10, which is arranged axisymmetrically about the axis of the rings (X axis). The rings 20 and the disk 1 are also arranged axisymmetrically about the same axis X. The tool 10 is shown disposed around the disk 1, and configured to move relative to the latter along the axis X. The tooling 10 comprises in particular a cover 30, also arranged axisymmetrically about the axis X, and enveloping the disk 1. A first and a second ring 20 are fixed on an inner periphery of the cover 30. Therefore, when the tooling is in motion, moving the cover 30 causes a simultaneous movement of the two rings 20. The first ring thus makes it possible to machine the first stage IA of the disc 1, and the second ring makes it possible to machine the second stage IB of the disc 1.
The cover 30 has, over its entire periphery, a plurality of injection passages 36 through which the tool is supplied with electrolyte, and a plurality of discharge passages 38 through which the electrolyte is discharged. Each evacuation passage 38 has a groove 38a and an evacuation bore 38b. The groove 38a is disposed in a direction parallel to the axis X of the tool, the discharge bore 38b is disposed in a radial direction perpendicular to the axis X. The flow of the electrolyte is represented by arrows on FIG. 3. The cover 30 has a first part 32 and a second part 34. The parts 32 and 34 are electrically insulated from each other by an insulating element 50, having an annular shape, and being interposed between said parts 32 and 34. The first ring being fixed on the first hood portion 32, and the second ring being fixed on the second hood portion 34, the two rings are therefore electrically insulated from each other, thanks to the insulating element 50. Thus, when one of the two rings is being machined, and therefore supplied with current, the other ring may not be supplied with current, avoiding in this case unwanted machining of certain zo The tooling 10 further comprises two movable guards 40, also fixed on the inner periphery of the cover 30. Therefore, when the tool is moving, the movement of the cover 30 causes a simultaneous movement of the two protectors. As shown in FIG. 4, the guards have a shape identical to the rings 20, in an X-axis view of the tool, namely an annular shape, and having a plurality of radial protrusion projections 44 on their inner periphery. The movable guards 40 are respectively adjacent to the rings 20, and are located above them, along the X axis of the tool. As tooling moves, moving guards and crowns move simultaneously in one block. Thus, the assembly formed by the rings 20 and the movable guards 40 form an annular piece having a plurality of radial projections on its inner periphery. These radial projections have the shape and dimensions of the cells to be machined on each stage of the disc 1.
Furthermore, the movable guards 40 comprise a plurality of fluid injection passages 42, each having a radial passage portion 42a, and an axial passage portion 42b, communicating with each other. The radial passage portion 42a is disposed in a direction perpendicular to the X axis of the tool, the axial passage portion 42b is disposed in a direction parallel to the X axis. The fluid injection passages 42 are arranged so as to feed each radial projection protector 44, each axial passage portion 42b being disposed so as to open on each projection 22 of the rings 20, respectively adjacent to the radial projections 44 of the movable protectors 40, as shown in Figure 4. The Radial passage portions 42a are arranged so as to open, respectively, on the injection passages 36 of the cap 30. Consequently, when a crown is being machined, it is supplied with electrolyte from the injection passages. 36 of the cover 30, and via the fluid injection passages 42. The electrolyte can then flow around the projections 22 of the ring, before being evacuated. In addition, when a crown being machined moves along the X axis, the insulating protector 40 adjacent thereto moves simultaneously penetrating the cavities of the disc 1 which has just been machined. Thus, the insulating protector 40 makes it possible to protect the portions of cells that have just been machined by preventing the electrolyte from dripping on these portions, and thus to avoid excessive machining of these portions, thus preserving the quality of the machining of the parts. alveoli.
A fixed protector 60 is also disposed on the outer periphery of the disc 1, between the two stages of the disc 1. The protector 60 forms an annular piece around the disc 1. It can be composed of two parts fixed together after being placed in position on the disc, in order to facilitate its installation and its fixing around the outer periphery of the disk 1. The means of attachment of these two parts may be a latch lever or clamping ring or any other equivalent means. The protector 60, which may be an electrical insulator, makes it possible to protect the areas of the disk 1 that must not be machined, by preventing the electrolyte from dripping on these zones. Furthermore, the fixed protector 60 may include a projection 62 for directing the electrolyte to a discharge passage 38 of the cover 30, thus facilitating the evacuation of the electrolyte and the dissolved material. A clamping ring 62a makes it possible to position and hold the elements 60 and 62 together. Seals 60a are also arranged around the protector 60, so as to ensure contact sealing between the cover 30 and the protector 60. The assembly consisting of the tool 10, the multi-stage disk 1 and the fixed protector 60 may also comprise an upper fixed protector 64, protecting an upper part of disc 1, located above the lower diameter stage IA, being fixed thereto, and a lower fixed protector 66, protecting a lower part of the disc 1, located under the larger diameter stage IB, being fixed around the disc 1, in the same way as the protector 60. These different fixed protectors can protect areas of the disc 1 which must not not be machined, by preventing the electrolyte from dripping on these areas.
FIG. 5 represents an electrochemical machining machine 100 comprising an actuator 110, which may be a cylinder with a vertical axis, capable of displacing the tooling 10 axially along an axis X of the tooling, with respect to the multi-stage disk.
An electrolyte circuit 120, having a reservoir 122, makes it possible to supply the electrolyte rings 20 via a supply circuit 121, and to evacuate the electrolyte via a discharge circuit 125.
This circuit 120 comprises in particular a selection valve 124, which can pass from a first position in which the first ring only is electrolyte fed, to a second position in which the second ring only is electrolyte fed.
As a result, in the supply circuit 121 the electrolyte is pumped from the tank 122 by a pump 123; it is then oriented by the selection valve 124 either to the injection passages 36 of the upper protector 40 or to those of the lower protector 40, depending on whether it is desired to machine the upper stage IA or the lower stage IB. The electrolyte then flows through the fluid injection passages 42 of the protector 40 used, then flows over the projections 22 of the ring 20 and the stage of the disk to be machined (stage IA or IB as the case may be), which gradually realizes the machining of this floor. The electrolyte is finally discharged through an evacuation passage 38 of the cover (during the machining of the stage IA), or by a lower area of the tool 10 located under the stage of larger diameter IB (when of the machining of stage IB) (evacuation circuit 125).
An electrical circuit 130 furthermore makes it possible to supply the rings 20 with electric current. This circuit 130 comprises an electrical switch 132 which can pass from a first position in which the first ring only is supplied with current by a current source 135, to a second position in which the second ring only is supplied with current.
Thus, the machine 100 is configured to allow the machining of the first stage IA of the disc 1 with the aid of the first ring, and the machining of the second stage IB with the aid of the second ring. The machining of the disc happens in the following way.
The disc 1 is first placed on a support 140 consisting of a turntable, allowing the disc to rotate about the axis X. Thus, when the tool 10 is moved in translation along the axis X in progress machining by the cylinder 110, it follows a relative helical movement with respect to the disk 1, to obtain the desired shape of the cells.
Initially, the tool 10 is positioned so that the second ring is in the vicinity of the larger diameter stage IB of the disk to be machined. To do this, the second ring is placed at a distance of 0.01 to 0.2 mm above the upper surface of the stage IB, along the axis X. The machining of the stage IB is then realized by simultaneously controlling the following actions: The machine 100 moves the tool 10 along the X axis by the actuator 110; the disc 1 is rotated by the turntable 140; and the second ring is supplied with current and electrolyte. These combined actions result in the electrochemical machining of stage IB. During this machining operation, the supply of the first ring electrolyte and current is cut off. The machining of the cells of stage IB is completed when the second ring has been moved below the lower surface of stage IB along the axis X. The supply of the second ring electrolyte and current is then cut off.
In a second step, the tool 10 is positioned so that the first ring is in the vicinity of the stage IA. To do this, the first ring is placed at a distance of 0.01 to 0.2 mm above the upper surface of the first stage IA, along the X axis.
As during the first machining phase, the machine 100 then moves the tool 10 along the axis X by the actuator 110, the first ring being at the same time supplied with current and electrolyte, so that the machining electrochemical stage IA can be performed. During the machining of the stage IA by the first ring, the supply of the second ring electrolyte and current is cut off. The machining of the cells of the stage IA is completed when the first ring has been moved below a lower surface of the stage IA along the axis X. The supply of the first ring electrolyte and current is then cut off. The machining of the stages of the multi-stage disk 1 is thus completed.
Although the present invention has been described with reference to specific exemplary embodiments, it is obvious that modifications and changes can be made to these examples without departing from the general scope of the invention as defined by the claims. In particular, individual features of the various embodiments illustrated / mentioned can be combined in additional embodiments. Therefore, the description and drawings should be considered in an illustrative rather than restrictive sense.
It is also obvious that all the features described with reference to a method can be transposed, alone or in combination, to a tool, and conversely, all the features described with reference to a tool are transposable, alone or in combination, to a method.

权利要求:
Claims (10)
[1" id="c-fr-0001]
1. Tooling (10) for producing cavities of a multi-stage disk (1) by electrochemical machining, characterized in that it comprises at least first and second coaxial rings (20) along a disk axis, configured for use as cathodes, each ring having an inner periphery having a plurality of radial machining projections (22), the first and second rings (20) being rigidly attached to each other.
[2" id="c-fr-0002]
2. Tooling (10) for producing cells of a disk (1) multi-stage electrochemical machining according to claim 1, wherein the radial projections have, in axial view along the disc axis, a mushroom shape.
[3" id="c-fr-0003]
3. Tooling (10) for producing cells of an electrochemically machined multistage disk (1) according to claim 1 or 2, further comprising a cover (30) in which the crowns are fixed, said cover being arranged around crowns and configured to prevent radial projections of a trickling electrolyte around the projections.
[4" id="c-fr-0004]
4. Tooling (10) for producing cells of an electrochemically machined multi-stage disk (1) according to any one of Claims 1 to 3, in which the cover (30) comprises at least two electrically insulated parts. one of the other by an insulating element (50), on which are fixed respectively the first and the second ring.
[5" id="c-fr-0005]
5. Tooling (10) for producing cells of an electrochemically machined multi-stage disk (1) according to any one of claims 1 to 4, further comprising at least two movable protectors (40) integral with said hood (30). ), having fluid injection passages (42) for injecting an electrolyte onto the projections (22), said two movable guards (40) being respectively adjacent to said first and second rings (20).
[6" id="c-fr-0006]
6. An assembly comprising the tooling (10) according to any one of claims 1 to 5, the disk (1) multi-stage, and at least one fixed protector (60) configured to be fixed on the disk (1) and protect the disc (1) from the electrolyte.
[7" id="c-fr-0007]
7. An electrochemical machining machine (100) comprising a support (140) for attaching a multi-stage disk (1), the tool (10) according to any one of claims 1 to 5, an actuator ( 110) capable of making relative movements of the tool (10) relative to the disk (1) fixed on the support (140), the disk being at least partly inside the tool (10); an electrolyte circuit (120) and an electrical circuit (130); the machine (100) being configured to allow machining of a first stage (IA) of the disc (1) by means of the first ring, and machining of a second stage (IB) of the disc (1) to using the second ring, by electrochemical machining, during said displacements.
[8" id="c-fr-0008]
8. A method of producing cells of a multi-stage disk by electrochemical machining using the tooling (10) according to any one of claims 1 to 5, the method comprising the following steps: a) positioning the tooling ( 10) such that a first of said at least two rings (20) is in the vicinity of a first stage (IB) of the disk to be machined. b) Machining the first stage (IB) of the disk by electrochemical machining by moving the tooling relative to the disk along the disk axis. c) Positioning the tool (10) so that a second of said at least two rings (20) is in the vicinity of a second stage (IA) of the disk to be machined. d) Machining the second stage (IA) of the disk by electrochemical machining by moving the tooling relative to the disk along the disk axis.
[9" id="c-fr-0009]
9. A method of producing cells of a multi-stage disk by electrochemical machining according to claim 8, further comprising the following steps: - Cut off the power supply and electrolyte of the second ring, when the first ring is in machining course during step b). - Cut the power supply and electrolyte of the first ring, when the second ring is being machined during step d).
[10" id="c-fr-0010]
10. A method for producing cells of a multi-stage disk by electrochemical machining according to claim 8 or 9, wherein, in the machining step b) and / or d), the relative movement of the tooling relative to the disk is a helical movement around the disk axis (1).

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法律状态:
2016-10-05| PLFP| Fee payment|Year of fee payment: 2 |

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2017-04-14| PLSC| Search report ready|Effective date: 20170414 |

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2017-09-21| PLFP| Fee payment|Year of fee payment: 3 |

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2018-09-14| CD| Change of name or company name|Owner name: SAFRAN AIRCRAFT ENGINES, FR Effective date: 20180809 Owner name: PEMTEC, FR Effective date: 20180809 |

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2018-09-19| PLFP| Fee payment|Year of fee payment: 4 |

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2019-09-19| PLFP| Fee payment|Year of fee payment: 5 |

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2020-09-17| PLFP| Fee payment|Year of fee payment: 6 |

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2021-09-22| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1559541A|FR3042138B1|2015-10-07|2015-10-07|TOOLING FOR THE MACHINING OF MULTI-STAGE DISKS WITH PECM, ASSEMBLY AND ELECTROCHEMICAL MACHINING MACHINE COMPRISING THE TOOLS, AND METHOD USING THE TOOLS|

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FR1559541|2015-10-07|FR1559541A| FR3042138B1|2015-10-07|2015-10-07|TOOLING FOR THE MACHINING OF MULTI-STAGE DISKS WITH PECM, ASSEMBLY AND ELECTROCHEMICAL MACHINING MACHINE COMPRISING THE TOOLS, AND METHOD USING THE TOOLS|

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CN201680065686.XA| CN108430683B|2015-10-07|2016-10-07|Tool for machining grooves with PECM in a multi-stage disk, electrochemical machining assembly and machine comprising such a tool, and method for using such a tool|

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RU2018115892A| RU2726533C2|2015-10-07|2016-10-07|Tool for making multistage disc grooves by a re-milling method, a unit and an electrochemical processing machine containing said tool, and a method using said tool|

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CA3001255A| CA3001255A1|2015-10-07|2016-10-07|Tool for machining wells in multi-stage discs by pecm, electrochemical machining assembly and machine including said tool, and method using said tool|

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US15/766,533| US10507540B2|2015-10-07|2016-10-07|Tool for machining wells in multi-stage discs by PECM, electrochemical machining assembly and machine including said tool, and method using said tool|

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PCT/FR2016/052600| WO2017060651A1|2015-10-07|2016-10-07|Tool for machining wells in multi-stage discs by pecm, electrochemical machining assembly and machine including said tool, and method using said tool|

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JP2018537730A| JP6843871B2|2015-10-07|2016-10-07|Tools for machining slots on multi-stage discs with PECM, electrolytic assembly, and machines containing the tools, and methods of using the tools.|

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BR112018006992-2A| BR112018006992A2|2015-10-07|2016-10-07|tooling and method for making slots, assembly, and machine for electrochemical machining|

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EP16794371.1A| EP3359323B1|2015-10-07|2016-10-07|Tool for machining wells in multi-stage discs by pecm, electrochemical machining assembly and machine including said tool, and method using said tool|