US3853734A

US3853734A - Fluid system for honing and plating apparatus

Info

Publication number: US3853734A
Application number: US00355216A
Authority: US
Inventors: M Ellis; A Czubak
Original assignee: Micromatic Ind Inc
Current assignee: Micromatic Ind Inc
Priority date: 1971-08-16
Filing date: 1973-04-27
Publication date: 1974-12-10
Anticipated expiration: 1991-12-10

Abstract

Plating and honing apparatus embodying a closed fluid circuit for the circulation of liquid electrolyte and/or coolant during plating and/or honing.

Description

United States Patent [1 1 {111 3,853,734 Ellis et a1. 5] Dec. 10, 1974 FLUID SYSTEM FOR HONING AND [56] References Cited PLATING APPARATUS UNITED STATES PATENTS [75] Inventors: Myron P. Ellis, Royal Oak; Albin S. 3,022,232 2/1962 Bailey et a1. 204/217 UX Czubak, Detroit, both of Mich. 3,076,754 2/1963 Evans 204/275 X 73 A' :M' t'Idt' 1.,Dt't, sslgnee i 3 c n us "es, nc 6 ml Primary Examiner-John H. Mack Assistant Examiner-W. I. Solomon Flled! p 27, 1973 Attorney, Agent, or FirmMalc0lm R. McKinnon [21] Appl. No.: 355,216

Related US. Application Data [57]. ABSTRACT [63] Continuation of Sen 172,007 Aug 16, 1971 Piatmg and honlng apparatus embodying a closed fluid abandoned circuit for the circulation of liquid electrolyte and/0r coolant during plating and/or honing. [52] U.S. Cl 204/212, 51/5, 204/217,

204/224 R, 204/275, 204/D1G. 10 7 Claims 3 Drawing Figures [51] Int. Cl C23b 5/68 [58] Field of Search 204/212, 217, 224 R, 275,

204/DIG. 10, 224 M; 51/5, 34 R FLUID SYSTEM FOR HONING AND PLATING APPARATUS This is a continuation of application Ser. No. 172,007, filed Aug. 16, 1971, and now-abandoned.

BRIEF SUMMARY OF THE INVENTION contact unprotected machinery and/or the human operators thereof. US. Pat. No. 3,390,068 issued to M. P. Ellis on June 25, I968 discloses a workpiece fixture enclosure by which the splash and spray of electrolytic solution may be kept from contacting surrounding equipment and from contacting the human operators of plating and honing equipment.

An object of the present invention is to overcome disadvantages inherent in prior plating and honing apparatus of the indicated character and to provide improved apparatus for circulating honing and plating solutions in a closed circuit during honing and/or plating opera- IIOI'IS.

Another object of the present invention is to provide an improved fluid circuit for plating and honing solutions which permits the use of a minimum of fluid and which affords improved distribution and/or controlled distribution of the solution both during the honing operations and/or plating operations.

Another object of the invention is to provide improved plating and honing apparatus incorporating improved fluid circuitry which is economical and commercially feasible to manufacture and assemble. durable, efficient. reliable in operation. and which functions to protect the operators of the apparatus and nearby machinery from adverse effects generated by contact with plating and honing solutions.

Another object of the invention is to provide improved plating and honing apparatus embodying improved fluid circuitry effective to maintain the plating and/or honing solution in a closed circuit which includes the honing and/or plating tooling, the workpiece and the supporting fixtures.

The above as well as other objects and advantages of the present invention will become apparent from the following description, the appended claims and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic, elevational view of a honing and plating machine embodying the present invention;

FIG. 2 is a cross-sectional view of the structure illustrated in FIG. 1, taken on the line 22 thereof; and

FIG. 3 is a fragmentary, enlarged elevational view of a portion of the structure illustrated in FIG. 1.

DETAILED DESCRIPTION Referring to the drawings, the present invention is illustrated embodied in apparatus for honing and plating stepped or semi-blind end and straight cylindrical bores of a workpiece although it will be understood that the present invention is applicable to other uses. FIG. 1 illustrates a honing machine, generally designated 10, having a reciprocating quill 12 to which a honing and plating tool, generally designated 14, is drivably connected for reciprocation with the quill l2 and rotation relative to the quill 12. A work holding fixture I6 is provided which is mounted beneath the tool 14 as illustrated in FIG. 1 and supports a workpiece 18 in axial alignment with the tool 14.

Details of an electrochemical honing machine of a type in which the present invention may be incorporated are more fully disclosed in U.S. Pat. No. 3,390,068 issued to M. P. Ellis et al. on June 25, 1968. It will be understood that a wide variety of honing tools may be mounted to the reciprocating quill 12 for both reciprocating and rotational movement in any manner well known in the art.

As shown in FIG. 1, the honing and plating tool 14 is positioned relative to the workpiece 18 for combined plating and honing, the workpiece 18 being disposed in a fixed position relative to the fixture 16 forming a part of the machine 10. The illustrated workpiece 18 has a stepped bore 20 in which the lower portion of the bore is partially closed, as at 22. Such a bore may be described generally as a modified blind bore but it will be understood that the present invention may also be utilized with straight cylindrical bores.

The combined honing and'plating tool 14 comprises a tool support 24 which includes a plurality of honing stones 26, four of such stones 26 being illustrated although any desired number of such honing stones may be utilized. The stones 26 are mountedrelative'to the tool support 24 so that they may be adjusted radially outwardly or inwardly relative to the axis of rotation of the tool support in any manner well known in the art whereby the stones may be moved toward and away from the bore surface 28 which is to be plated and honed. One means for moving the honing stones 26 and for supporting them on the tool support 24 is more fully disclosed in the aforementioned Ellis patent and in US. Pat. No. 26,499 issued to J. H. Greening on Dec. 3, 1968. It will be understood that any other suitable means may be employed to support and move the honing stones.

In the embodiment of the invention illustrated, the tool support 24 includes an integral flange 25 which is secured to the quill 12 by a retaining ring 27 whereby the tool support reciprocates with the quill l2, and the tool support 24 is supported for rotation within the quill 12 by bearings such as 29.

Surrounding the honing tool support 24 is a sleeve member 30 which is also adapted to project into the bore 20. The sleeve 30 is provided with longitudinally extending slots 32'adapted to receive the honing stones 26 so that upon radial adjustment, the stones may protrude through the slots 32 and into engagement with the bore surface 28 with any desired surface pressure or they may be retracted out of engagement with the surface 28. The inside diameter of the sleeve member 30 affords sufficient clearance between the sleeve and the honing tool support 24 to permit reciprocation or relative movement of the tool support relative to the sleeve member 30. The outside diameter of the sleeve member is of a selected size to afford a small clearance with the wall surface 28 of the bore 20 in the workpiece l8.

As schematically shown in FIG. 1, the quill 12 is adapted to be reciprocated by a conventional piston and cylinder unit 34 mounted on the machine while the sleeve member 30 is adapted to be releasably clamped to the quill 12 through the agency of conventional piston and

cylinder units

36 and 38 for selective reciprocation with the tool support 24. The pistons of the piston and

cylinder units

36 and 38 are connected to a flange 39 provided on a bearing collar 40 which supports the sleeve 30 while the cylinders of the piston and cylinder units are connected to opposite ends of an outwardly projecting arm 37 fixed to the quill 12. A rotatable drive mechanism, generally designated 41, is also provided for simultaneously rotating the tool support 24 and the sleeve 30. The rotatable drive mechanism 41 is comprised of a driving cage 42 which may be rotated about the axis of the quill 12 by any suitable rotating driving mechanism such as a splined gear drive (not shown). The cage 42 includes angularly spaced, vertically extending driving members, such as 44 and 46, the lower end portions of which are fixed to an integral flange 48 provided on the sleeve 30, as by bolts 50, while the upper end portions of the

driving members

44 and 46 are driven by the aforementioned driving mechanism. The driving

members

44 and 46 define longitudinally extending slots 52 and 54, respectively, in which are mounted rollers, such as 56 and 58, the

rollers

56 and 58 in turn being fixed to the tool support 24. With such a construction, rotation of the

drive members

44 and 46 imparts simultaneous rotation to both the tool support 24 and the sleeve 30, the sleeve 30 being supported for rotation by bearings 60 and 62 carried by the bearing collar 40. In addition, the tool support 24 is permitted to be reciprocated independently of the sleeve 30 through the agency of the piston and cylinder unit 34 and the sleeve 30 is permitted to be reciprocated with the tool support 24 by actuating the piston and

cylinder units

36 and 38 so that the arm 37, the flange 48 of the sleeve 30 and the bearing collar 40 are clamped together for reciprocation with the quill 12. Thus, such a construction either permits the rotating tool support 24 to move vertically relative to the simultaneously rotating but longitudinally stationary sleeve 30 within the range afforded by the length of the slots 32, or both the tool support and sleeve 30 may be simultaneously reciprocated.

The lower end of the collar 40 is insulated from the fixture 16 by an insulator 64 made at any suitable electrically non-conductive material, the insulator 64 remaining stationary relative to the fixture 16 while permitting rotational and reciprocable movement of the sleeve member 30.

As is well known, it is necessary during plating to provide an electrolyte or plating solution in the area between the tool and the work surface to be plated. As shown in FIG. 1, the flow path or circuit by which plating solution may be circulated, includes a reservoir 66 of electrolytic solution which is pumped by means of a pump 68 through a conduit 70 to a port 72 in the fixture 16 and thereafter through a passage 74 into the lower end 76 at the semi-blind bore 20. The plating solution is free to flow through the enlarged radial bore portion 77 and through the annular space formed by the outer diameter of the sleeve member 30 and the bore surface 28 of the workpiece to a passageway 78 provided at the upper end of the fixture 16. The plating solution flows from the passageway 78 through a conduit 80 which returns the plating solution to the reservoir 66. In order to prevent reverse flow through the system, a check valve 82 is provided in the conduit 70 and a pressure gauge 84 may be provided if desired.

In order to seal the plating solution within the system a seal 86 is provided at the upper end of the fixture 16 for engagement with the outside diameter of the rotating sleeve member 30. Another seal 88 is provided which is located between the inner diameter of the sleeve member and the outer diameter of the tool support 24. As previously mentioned. the tool support 24 reciprocates relative to the sleeve 30 during operation of the machine 10. In the preferred embodiment of the invention illustrated, the internal diameter of the seal 86 is slightly larger than the outside diameter of the sleeve 30 and the inside diameter of the sea] 88 is slightly larger than the outside diameter of the tool sup port 24 whereby a slight clearance is provided between the inner surface of the seal 86 and the outer surface of the sleeve 30 and a slight clearance is also provided between the inner surface of the seal 88 and the outer surface of the tool support 24 so that a small amount of liquid is permitted to flow past the seals, such liquid acting as a fluid bearing thereby greatly increasing the life of the seals 86 and 88. By way of example, 0.001 to 0.002 inches clearance may be provided between the inside surface of the seal 86 and the outside surface of the sleeve 30 and the same amount of clearance may be provided between the inside surface of the seal 88 and the outside surface of the tool holder 24. Such a construction provides a controlled flow of liquid past the seals 86 and 88, the liquid flowing past the seal 86 being returned to the reservoir 66 through a passageway 87 provided in the collar 40 and communicating with a conduit 89 leading to the reservoir 66, while the fluid flowing past the seal 88 is returned to the reservoir 66 through a passageway 91 provided in the sleeve 30, the passageway 91 communicating with an internal annular groove 93 provided in the coliar 40 and having conventional O-ring seals 95 and 97 on opposite sides thereof. The groove 93 communicates with a passageway 99 defined by the collar 40, the passageway 99 in turn being connected to the conduit 89 leading to the reservoir 66. It will be understood that the seals 86 and 88 may be fluid tight, if desired, thereby eliminating the necessity of providing the secondary return passageways 87, 89, 91, 93 and 99 and the O-ring seals 95 and 97. It will also be understood that the seals 86 and 88 may be carried by the sleeve 30 and tool support 24, respectively, rather than the collar 40 and sleeve 30, respectively. A static seal also is provided between the stationary fixture 16 and the upper surface of the workpiece 18 while the lower portion of the workpiece is sealed relative to the supporting fixture by means of the seal 92.

The fluid circuit above described for the circulation of electrolytic fluid makes it possible to use a minimum amount of fluid to achieve its working purpose. Moreover, as is well known in the art, it is often necessary to use electrolytic solutions containing chemicals which can be extremely corrosive and detrimental to surrounding apparatus and dangerous to the operators of honing machines. By utilizing the closed circuit, possible exposure to the electrolytic solution is reduced to a minimum thereby materially increasing the safety factors incorporated in the apparatus and reducing the chances that the operators will come in contact with the electrolytic solution.

The plating solution acts to form an electrically conductive path between the electrically conductive sleeve member 30 and the electrically conductive workpiece 18. As shown in FIG. 1, a power supply 94 of direct current is provided adjacent the honing machine and is provided with positive and negative output terminals 96 and 98. The power supply unit functions to supply direct electric current of a selected magnitude to the work environment. The positive output terminal 96 is connected by a conductor 100 to a brush take-off unit 102 by means of which the electric current may be transmitted between the power source and the sleeve member 30 during rotation of the latter. From the sleeve member, the current flows through the electrolyte to the workpiece 18 which is electrically conductive material. A conductor 104 between the workpiece and the negative terminal of the power supply unit completes the electrical circuit.

Thus far the invention has been described in connection with operations on a workpiece with a modified blind bore. It will be understood, however, that the invention may be employed to either hone or plate an open ended or straight cylindrical bore in a workpiece. In this instance, the fixture may be provided with an enlarged inlet passageway to eliminate any restriction to the free flow of plating solution into the bore of the workpiece during the plating and honing process.

In operation, the apparatus 10 is employed for honing and electroplating by first retracting the quill 12 to gether with the honing-plating tool 14 to its uppermost position. A workpiece 18 is then positioned in the fixture I6 so that the workpiece bore 20 is in axial alignment with the axis of rotation of the tool 14. With the honing stones 26 retracted within the slots 32 of the sleeve member 30, the tool support 24 and sleeve member are moved as a unit vertically downward until the lower end of the sleeve 30 is located at a position near the lower end of the modified stepped bore as shown in FIGS. 1 and 2, after which the sleeve 30 is unclamped from the quill 12 by releasing the piston and

cylinder units

36 and 38.

With the combined honing and plating tool 14 in this position, the flow of plating solution is initiated to cause fluid flow between the outer surface of the sleeve member 30 and the bore surface 28 of the workpiece. Thereafter, the honing stones are brought into engagement with the surface 28 and the tool support 24 is reciprocated by the piston and cylinder unit 34 and both the tool support 24 and sleeve 30 are rotated through the agency of the drive mechanism 41 to cause an abrading action to take place between the honing stones and the work surface. After a desired degree of abrading has taken place, the work surface will be sufficiently clean and be prepared for the subsequent platcircuit previously described and particularly between the sleeve member 30 which acts as an anode, through the electrolyte to the workpiece which acts as a cathode. As is well known, this causes a depositing of the plating material on the surface 28 of the workpiece. After a sufficient period of time and sufficient depositing and honing of plating material on the work surface 28 of the workpiece, the electrical current flow may be terminated. If desired, honing maybe continued after the flow of electrical current is terminated.

From the foregoing description, it will be seen there has been provided a closed circuit system for directing and containing the flow of electrolytic solution which system protects not only the surrounding surfaces of the apparatus and nearby equipment but also the operators of honing and plating equipment without requiring special guards or covers for protection against splash and spray.

While preferred embodiments of the invention have been illustrated and described, it will be understood that various changes and modifications may be made without departing from the spirit of the invention.

What is claimed is:

1. In plating and honing apparatus for plating metal on and removing metal from the surface defining a bore in an electrically conductive workpiece, the combination comprising first means adapted to hold a workpiece in a stationary position, a plating and honing tool including a tool support and a sleeve surrounding said tool support, said tool support and said sleeve being adapted to be inserted in the bore defined by said surface, sealing means between said tool support and said sleeve means mounting said plating and honing tool for reciprocation and rotation relative to said surface, a reservoir for electrolytic fluid, fluid pressure generating means, and fluid conduit means for moving electrolytic fluid under pressure from said reservoir through said bore and to and from said first means and said sealing means and back to said reservoir through a closed passage defined by said surface and said tool.

2. In a honing and plating apparatus for removing and plating metal on a surface defining a bore in an electrically conducting workpiece, the combination comprising fixture means adapted to engage and hold a workpiece, plating and honing tool means including a tool support and a sleeve surrounding said tool support, said tool support and said sleeve being adapted to be inserted in said bore, sealing means between said tool support and said sleeve, means holding said plating and honing tool means for reciprocation and rotation relative to said workpiece, fluid passage means in said fixture means and in said holding means, a reservoir for electrolytic fluid, liquid pressure generating means, and fluid conduit means for delivering liquid from said reservoir to one of said passages and to said bore and from said bore to the other end of said passage and back to said reservoir whereby such liquid is maintained in a closed fluid circuit under pressure.

3. In a honing and plating apparatus for removing and plating metal on a surface defining a bore in an electrically conducting workpiece the combination comprising fixture means adapted to engage and hold a workpiece, said fixture means having a passage in communication with the bore defined by said workpiece, a combined plating and honing tool including a tool support and a sleeve surrounding said tool support, means for holding said plating and honing tool for selective reciprocation and rotation relative to said workpiece surface, said holding means having a passage in communication with the bore defined by said workpiece, a reservoir for electrolytic liquid, and means including a pump for delivering liquid from said reservoir to one of said passages and to said bore and from said bore to the other of said passages and back to said reservoir whereby such liquid is maintained in a closed fluid circuit under pressure.

4. The combination as set forth in claim 3 including sealing means between said fixture means and said sleeve.

5. The combination as set forth in claim 3 including sealing means between said tool support sleeve.

6. The combination as set forth in claim 3 including

Claims

6. The combination as set forth in claim 3 including first sealing means between said fixture means and said sleeve and second sealing means between said tool support and said sleeve.

7. The combination as set forth in claim 3 including first sealing means between said fixture means and said sleeve and second sealing means between said tool support and said sleeve, said second sealing means adapted to permit a controlled amount of liquid to flow between said tool support and said sleeve to provide a fluid bearing, and closed fluid circuit means for delivering liquid flowing past said second sealing means to said reservoir.