JP2009173956A - Electrode holder for discharge surface treatment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electrode holder for the discharge surface treatment capable of depositing a uniform film and enhancing the quality of the discharge surface treatment by stabilizing the discharge between an electrode 3 and a part Wa to be treated of a workpiece W. <P>SOLUTION: The electrode holder includes a holder body 7 having a butting part 13 capable of butting the electrode 3 to its fore end side and fixing members 19, 23 for fixing the electrode 3 to the butting part 13 of the holder body 7. A working liquid feeding passage 27 for feeding a working liquid L from a working liquid feed source 25 is formed in the holder body 7. A working liquid jetting hole 31 for jetting the working liquid L toward the fore end side of the electrode 3 from the inner side of the electrode 3 is formed in the fixing member 19, and the working liquid jetting hole 31 communicates with the working liquid feed passage 27. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an electrode holder for a discharge surface treatment that holds a hollow electrode used when performing a discharge surface treatment on a frame-shaped target portion of a workpiece.

In recent years, various developments have been made on discharge surface treatment using discharge energy (see Patent Document 1 and Patent Document 2). For example, for a ring-shaped processed part in a workpiece such as a bubble sheet part in an engine cylinder head. When performing the discharge surface treatment, a rod-shaped electrode formed from a powder of metal or the like, or a hollow cylindrical electrode formed from a powder of metal or the like and corresponding to the shape of the part to be processed in the workpiece is used. And when performing discharge surface treatment using a rod-shaped electrode, the electrode is moved in an electrically insulating working fluid while moving the electrode relatively in the circumferential direction along an annular portion to be processed in the workpiece. A pulsed discharge is generated between the workpiece and the workpiece in the workpiece, and the discharge energy causes the electrode material (including the reactants of the electrode material) to adhere to the annular workpiece in the workpiece. A film such as a wear film is gradually formed. In addition, when performing discharge surface treatment using a hollow cylindrical electrode, the electrode axis and the workpiece ring are not moved relative to the circumferential direction of the workpiece along the workpiece ring. In a state where the center of the to-be-processed part is aligned, a pulsed discharge is generated between the electrode and the ring-shaped to-be-processed part in the workpiece in the electrically insulating working fluid, and the discharge energy of the electrode A film is formed at a time by adhering a material to an annular part to be processed in a workpiece.
JP 2004-76036 A JP 2004-277803 A

  By the way, in the case where the discharge surface treatment is performed using the rod-shaped electrode, as described above, the electrode is moved relative to the circumferential direction along the portion to be processed in the workpiece, and the ring in the workpiece is discharged by the discharge energy. Since the coating is gradually formed on the part to be treated, there is a problem that the treatment time of the discharge surface treatment becomes long and it is difficult to increase the productivity (working efficiency).

  On the other hand, in the case of performing discharge surface treatment using a hollow cylindrical electrode, as described above, the discharge energy is obtained with the axial center of the electrode aligned with the center of the ring-shaped portion to be processed. Since the coating is formed on the ring-shaped processed portion of the workpiece at a time, the processing time of the discharge surface treatment can be shortened and the productivity can be improved, but the following problems arise. In other words, the hollow cylindrical electrode is larger than the rod-shaped electrode and does not move in the circumferential direction relative to the workpiece in the work during discharge. In other words, there is a problem that it is difficult to form a uniform film due to the occurrence of concentrated electric discharge.

  Therefore, even when the discharge surface treatment is performed on the portion to be processed in the frame shape of the workpiece using the hollow electrode, the present invention collects sludge or the like between the electrode and the portion to be processed in the workpiece. It is an object of the present invention to provide an electrode holder for discharge surface treatment with a novel configuration that can be made difficult.

  A feature of the present invention is that for discharge surface treatment that holds a hollow (including hollow cylindrical) electrode that is used when performing discharge surface treatment on a frame-shaped (including annular) workpiece in a workpiece. In the electrode holder, the holder main body having a butting portion capable of abutting the electrode on the tip side, and having a machining liquid supply passage for supplying a machining liquid from a machining liquid supply source therein, A machining liquid ejection hole is formed in the center of the abutting portion of the holder body so as to be detachable, communicates with the machining liquid supply passage, and ejects the machining liquid from the inside of the electrode toward the tip side of the electrode. And a fixing member that fixes the electrode to the abutting portion of the holder body.

  According to the feature of the present invention, the hollow electrode is abutted against the abutting portion of the holder body, and the electrode is fixed to the abutting portion of the holder body by the fixing member. Thereby, the hollow electrode can be held by the electrode holder.

  After the hollow electrode is held by the electrode holder, the electrode is placed in an electrically insulating working fluid in a state where the axial center of the electrode is aligned with the center of the frame-shaped target portion of the workpiece. A pulsed discharge is generated between the workpiece and the frame-shaped target part of the workpiece. Thereby, the material of the electrode can be adhered to the frame-shaped target portion of the workpiece by the discharge energy, and a film can be formed.

  Here, when the machining liquid is appropriately supplied from the machining liquid supply source to the machining liquid supply passage during the discharge surface treatment, the machining liquid is directed from the inside of the electrode toward the tip side of the electrode through the machining liquid ejection hole. Can be ejected. Thereby, it is possible to promote the flow of the machining fluid between the electrode and the portion to be processed in the workpiece, and when performing discharge surface treatment on the frame-shaped portion to be processed in the workpiece using the hollow electrode Even so, sludge or the like generated by the discharge can be made difficult to accumulate between the electrode and the portion to be processed in the workpiece.

  According to the present invention, sludge or the like generated by discharge during discharge surface treatment is generated even when the discharge surface treatment is performed on the portion to be processed in a frame shape of the workpiece using a hollow electrode. Between the electrode and the workpiece in the workpiece, the discharge between the electrode and the workpiece in the workpiece can be stabilized, and a uniform film can be formed. Quality can be improved.

  An embodiment of the present invention will be described with reference to FIGS.

  Here, FIG. 1 is a longitudinal sectional view of an electrode holder according to an embodiment of the present invention, FIG. 2 is a view taken along line II-II in FIG. 4, and FIG. 3 is taken along line III-III in FIG. FIG. 4 is an enlarged view taken along the line IV-IV in FIG. 1, and FIG. 5A is a view showing a state in which the electrode is pushed out from the abutting portion by a pushing bolt into the gas discharge passage. (B) is a figure which shows the arrow part VB in FIG.5 (b).

  As shown in FIG. 1 to FIG. 4, the electrode holder 1 for discharge surface treatment according to the embodiment of the present invention is against an annular workpiece Wa in a workpiece W such as a bubble sheet portion in an engine cylinder head. It holds the hollow cylindrical electrode 3 used when performing the discharge surface treatment, and is detachably attached to the treatment head 5 in the discharge surface treatment apparatus. And the specific structure of the electrode holder 1 which concerns on embodiment of this invention is as follows. In the embodiment of the present invention, the electrode 3 is formed by compression-molding a stellite alloy powder, and is compressed from a metal powder, an alloy powder, a ceramic powder, or a mixed powder thereof. Any material that is molded or injection molded may be used.

  That is, the electrode holder 1 according to the embodiment of the present invention includes a holder body 7, and the holder body 7 is a cylindrical first holder body 9 that is detachably provided on the processing head 5. And a cylindrical second holder body 11 which is integrally provided at the tip of the first holder body 9 and has an outer diameter larger than the outer diameter of the first holder body 9. The second holder main body 11 has a concave abutting portion 13 that can be abutted with the electrode 3 inserted in the distal end side, and the center of the abutting portion 13 of the second holder main body 11. Is formed with a screw hole 15. Furthermore, a male screw portion 17 is formed on the outer peripheral surface of the second holder body 11.

  A fixing screw 19 is detachably screwed into the screw hole 15 of the second holder body 11, and the electrode 3 is attached to the abutting portion 13 of the second holder body 11 on the fixing screw 19. An electrode presser 23 that is pressed to the side through the elastic force of the O-ring 21 is inserted and provided. Here, in the embodiment of the present invention, the fixing screw 19 and the electrode presser 23 are used as a fixing member for fixing the electrode 3 to the abutting portion 13 of the second holder body 11. Instead of the screw 19 and the electrode retainer 23, another fixing member that fixes the electrode 3 to the abutting portion 13 of the second holder body 11 by the action of magnetic force may be used.

  A processing liquid for supplying the processing liquid (processing oil in the embodiment of the present invention) L from the first holding body 9 to the second holding body 11 from the processing liquid supply source 25 such as a pump. A supply passage 27 is formed, and the machining fluid supply passage 27 is connected to the machining fluid supply source 25 via a connection pipe 29. The machining fluid supply passage 27 extends in the axial direction (the axial direction of the electrode holder 1) and communicates with the screw hole 15 of the second holder body 11. The fixing screw 19 is formed with a machining liquid ejection hole 31 through which the machining liquid L is ejected from the inner side of the electrode 3 toward the tip end side of the electrode 3. It extends in the direction and can communicate with the machining liquid supply passage 27 through the screw hole 15 of the second holder body 11.

  A plurality of (four in the embodiment of the present invention) side processing liquids that eject the processing liquid L from the outside of the electrode 3 toward the distal end side of the electrode 3 on the outer peripheral surface of the second holder body 11. The ejection grooves (side machining fluid ejection passages) 33 are formed at equal intervals in the circumferential direction, and each side machining fluid ejection groove 33 extends in the axial direction and is connected to the machining fluid supply passage 27 via the communication passage 35. Communicated. Further, in order to eject the machining liquid L from each side machining liquid ejection groove 33 along the outer peripheral surface of the electrode 3, the tip side portion 33a of the groove bottom of each side machining liquid ejection groove 33 is formed on the axis side (electrode It is inclined toward the axial center side of the holder 1, in other words, toward the axial center side of the second holder body 11. A cup-type guide cap 37 that guides the machining liquid L in the side machining liquid ejection groove 33 toward the distal end of the second holder body 11 is detachably screwed onto the male thread portion 17 of the second holder body 11. An insertion hole 39 through which the first holder main body 9 can be inserted is formed in the center of the top portion of the guide cap 37. An O-ring 41 for sealing is interposed between the top portion of the guide cap 37 and the tip portion (tip surface) of the second holder body 11.

  Here, instead of forming the side machining liquid ejection groove 33 on the outer peripheral surface of the second holder body 11, a side machining liquid ejection hole (not shown) is provided as a side machining liquid ejection passage in the second holder body 11. May be formed.

  In the second holder body 11, a plurality of gas discharge passages 43 for discharging the gas G generated by the discharge from the inside of the electrode 3 to the outside of the holder body 7 are formed through at equal intervals, Each gas discharge passage 43 extends in the axial direction, and the tip of each gas discharge passage 43 is opened to the abutting portion 13 side of the second holder body 11. Further, a plurality of communication grooves 45 are formed at the distal end portion (tip surface) of the second holder body 11, and each communication groove 45 projects from the distal end of the corresponding gas discharge passage 43 toward the axial center side. is there. The electrode retainer 15 is formed with a pair of gas vent holes 47 symmetrically, and the pair of gas vent holes 47 can communicate with the plurality of gas discharge passages 43 via the plurality of communication grooves 45. . Further, each gas discharge passage 43 is formed with a female screw portion 51 for an extrusion bolt to which an extrusion bolt 49 used when the electrode 3 is extruded from the abutting portion 13 of the second holder body 11 can be screwed. Yes.

  Then, the effect | action and effect of embodiment of this invention are demonstrated.

  The hollow cylindrical electrode 3 is abutted against the abutting portion 13 of the second holder body 11. Then, by tightening the fixing screw 19 while being screwed into the screw hole 15 of the second holder main body 11, the electrode presser 23 inserted through the fixing screw 19 causes the electrode 3 to move to the abutting portion 13 side of the second holder main body 11. The O-ring 21 is pressed through the elastic force. Thereby, the electrode 3 can be fixed to the abutting portion 13 of the second holder body 11, and the hollow cylindrical electrode 3 can be held by the electrode holder 1.

  After the hollow cylindrical electrode 3 is held by the electrode holder 1, the processing tank (not shown) in the discharge surface treatment apparatus is aligned with the axial center of the electrode 3 and the center of the annular portion Wa to be processed in the workpiece W aligned. ), A pulsed discharge is generated between the electrode 3 and the workpiece Wa in the workpiece W in the electrically insulating working fluid (not shown). As a result, the material of the electrode 3 (including the reaction material of the material of the electrode 3) is attached to the annular workpiece Wa in the workpiece W by the discharge energy, and a film (not shown) such as a wear-resistant film is formed at a time. Form.

  Here, when the machining liquid L is appropriately supplied from the machining liquid supply source 25 to the machining liquid supply passage 27 during the discharge surface treatment, the machining liquid is processed from the inside of the electrode 3 toward the tip side of the electrode 3 through the machining liquid ejection hole 31. While the liquid L is ejected, the machining liquid L can be ejected from the outside of the electrode 3 toward the distal end side of the electrode 3 through the plurality of side machining liquid ejection grooves 33. Thereby, the distribution of the machining liquid L between the electrode 3 and the annular workpiece to be processed Wa in the workpiece W can be promoted, and the workpiece 3 is annularly formed in the workpiece W using the hollow cylindrical electrode 3. Even when the discharge surface treatment is performed, sludge and the like generated by the discharge can be hardly accumulated between the electrode 3 and the portion Wa to be processed in the workpiece W.

  Further, the gas G generated by the discharge is discharged from the inside of the electrode 3 to the outside of the holder main body 7 through the plurality of gas discharge passages 43. Specifically, the gas G generated by the discharge flows into the plurality of gas discharge passages 43 from the pair of gas vent holes 47 through the plurality of communication grooves 45, and the plurality of gas discharge passages 43 pass through the second holder body 11. And is discharged from the gas discharge passage 43 to the outside of the holder body 7. Thereby, even when the discharge surface treatment is performed on the workpiece Wa in a ring shape of the workpiece W using the hollow cylindrical electrode 3, the gas G generated by the discharge is not easily accumulated inside the electrode 3. .

  Further, after the end of the discharge surface treatment or the interruption of the discharge surface treatment, the fixing screw 19 is loosened and removed from the screw hole 15 of the second holder body 11 as shown in FIG. Then, each push bolt 49 is tightened while being screwed into the female screw portion 51 for the push bolt of the corresponding gas discharge passage 43, and the electrode 3 is pushed from the abutting portion 13 of the second holder body 11 by each push bolt 49. put out. Thereby, the electrode 3 can be removed from the electrode holder 1 and the electrode 3 can be replaced or discarded.

  As described above, according to the embodiment of the present invention, even when the discharge surface treatment is performed on the workpiece Wa in a ring shape in the workpiece W using the hollow cylindrical electrode 3, the discharge surface treatment is performed. Since sludge and the like generated by the discharge can hardly be accumulated between the electrode 3 and the portion to be processed Wa in the workpiece W, the discharge between the electrode 3 and the annular portion to be processed Wa in the workpiece W can be stabilized. Thus, a uniform film can be formed, and the quality of the discharge surface treatment can be improved.

  Further, even when the discharge surface treatment is performed on the workpiece Wa in a ring shape in the workpiece W using the hollow cylindrical electrode 3, the gas G generated by the discharge is discharged from the electrode 3 during the discharge surface treatment. Since it becomes difficult to accumulate inside, the rapid increase of the internal pressure of the electrode 3 can be sufficiently suppressed, the electrode 3 can be prevented from being damaged, and the life of the electrode 3 can be extended.

  The present invention is not limited to the description of the above-described embodiment, and can be implemented in various other aspects. Further, the scope of rights encompassed by the present invention is not limited to these embodiments.

It is a longitudinal cross-sectional view of the electrode holder for discharge surface treatment which concerns on embodiment of this invention. It is the figure along the II-II line in FIG. FIG. 5 is a view taken along line III-III in FIG. 4. It is an enlarged view along the IV-IV line in FIG. FIG. 5A is a view showing a state in which the electrode is pushed out from the abutting portion by the pushing bolt into the gas discharge passage, and FIG. 5B is a view showing the portion VB as viewed in FIG. 5B. .

Explanation of symbols

W Work Wa To-be-processed part 1 Electrode holder for discharge surface treatment 3 Electrode 7 Holder body 9 First holder body 11 Second holder body 13 Abutting part 15 Screw hole 17 Male thread part 25 Working fluid supply source 27 Processing Liquid supply passage 29 Connection pipe 31 Machining liquid ejection hole 33 Side machining liquid ejection groove 37 Guide cap 39 Insertion hole

Claims (4)

In the electrode holder for the discharge surface treatment that holds the hollow electrode used when performing the discharge surface treatment on the frame-shaped target part in the workpiece,
A holder body having a butting portion capable of butting the electrode on the tip side;
A fixing member for fixing the electrode to the abutting portion of the holder body,
A machining liquid supply passage is formed in the holder body for supplying a machining liquid from a machining liquid supply source, and the machining liquid is ejected from the inner side of the electrode toward the distal end side of the electrode. An electrode holder for discharge surface treatment, wherein a hole is formed, and the machining liquid ejection hole can communicate with the machining liquid supply passage.   A side machining liquid ejection passage for ejecting a machining liquid from the outside of the electrode toward the tip end side of the electrode is formed in the holder body, and the side machining liquid ejection passage communicates with the machining liquid supply passage. The electrode holder for discharge surface treatment according to claim 1. The side machining liquid ejection passage is a side machining liquid ejection groove formed on the outer peripheral surface of the holder body and extending in the axial direction,
3. The discharge surface treatment according to claim 2, wherein a guide cap is provided on the outer peripheral surface of the holder main body to guide the machining liquid in the side machining liquid ejection groove toward the distal end of the holder main body. Electrode holder. A screw hole is formed at the center of the abutting portion of the holder body,
The fixing member includes a fixing screw that is removably screwed into the screw hole of the holder main body, a fixing screw that is inserted through the fixing screw, and the electrode that contacts the abutting portion of the holder main body. It consists of an electrode presser that presses toward
The electrode holder for discharge surface treatment according to any one of claims 1 to 3, wherein the machining liquid supply passage communicates with the screw hole.

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