Title of Invention	A METHOD OF CASE HARDENING A MEDIUM CARBON ALLOY CHAIN PIN AND A CHAIN PIN PRODUCED BY A PROCESS
Abstract	The present invention relates to the case hardening, tempering and coating of a medium carbon alloy chain pin. A medium carbon alloy chain pin is provided and is case hardened to a selected radial depth. The case hardened chain pin is quenched and then I tempered to introduce a gradient from the surface of the chain pin inwardly in carbon content and hardness. The chain pin is then coated with an electro less nickel and fluorinated carbon co-deposition to increase surface hardness.

Title of Invention

A METHOD OF CASE HARDENING A MEDIUM CARBON ALLOY CHAIN PIN AND A CHAIN PIN PRODUCED BY A PROCESS

Abstract

The present invention relates to the case hardening, tempering and coating of a medium carbon alloy chain pin. A medium carbon alloy chain pin is provided and is case hardened to a selected radial depth. The case hardened chain pin is quenched and then I tempered to introduce a gradient from the surface of the chain pin inwardly in carbon content and hardness. The chain pin is then coated with an electro less nickel and fluorinated carbon co-deposition to increase surface hardness.

Full Text	The present invention relates generally to a method of case hardening a medium carbon alloy chain pin and, more particularly, to toiler chain pins that are carburized and otherwise heat treated to allow for subsequent coating of a hardened electroless nickel enhanced with a fluorinated carbon as a co-deposit without the sacrifice of requisite metallurgical properties of the roller chain pin. As will be described in more detail in the detailed description of the present invention, roller chain is normally made up of five components. These components include alternating inside and outside links. The inside links are press fit over bushings and are usually called roller links. The outside links are typically press fit over pins and hence are typically called pin links. Cylindrical rollers are provided outside the bushings leaving the rollers free to turn for a rolling action as the roller chain enters and exists the driving sprockets. Typically, all high quality components of roller chain, including pins, bushings and rollers, are carburized or case hardened Link plates are thru-hardened. The carburizing process allows the outside of the pans to be transformed to a hard, wear resistant surface whereas the inner core retains the tough and ductile properties of the metal to absorb normal shock loading. In most applications, this combination provides the necessary engineered balance between wear resistance, durability and strength. In efforts to improve the overall perfonnance of roller chain, including improvements in wear life, galling resistance and overall lubricity of the roller chain pins various types of coalings were reviewed. After reviewing the constraints of the design of the roller chain product, performance and manufacturing techniques available, the use of electroless nickel as an autocataiytic deposition was settled on as most desirable to provide corrosion protection on carbon and alloy steel roller chain pins. This was found to be superior to electroplating because of potential for embrittlement in electroplating. Further, tooting treatments such as titanium nitride were viewed as inappropriate due to the manner of application and the labor intensive requirements. Further, flame spraying and ion implantation have similar undesirable restrictions on roller chain manufacture. Further, a co-deposit of a material to provide lubricity was also desirable. Various components such as silicon carbide, fluorinated carbon and polytetrafiuoroelhylene were all reviewed. It was decided that the poiylelrafiuoroelhylene or other similar proprietary coalings available today were best suited as a co-deposit with the electroless nickel for the roller chain pins. The major problem faced in the electroless nickel operation is the need to harden the electroless nickel fluorinated carbon co-deposition at temperatures in the neighborhood of 600-750o F to achieve maximum hardness and wear resistance. As most roller chain pins are tempered at 300-350° F, such subsequent hardening of the electroless nickel coating would result in a reduction of the pin core hardness and strength. SUMMARY OF THE INVENTION It is an object of the present invention to provide a roller chain and a method of manufacturing the roller chain with a roller chain pin that is capable of being coated in a co-deposition operation including eiectroless nickel and a selected fluorinated carbon component without loss of desirable roller chain pin metallurgical properties. As stated above, roller chain is normally made of five components. These components include outside or pin links joined by cylindrical pins, inside or roller link plates joined by cylindrical bushings, the pins themselves extending between openings in outside links and the bushings themselves extending between openings in the inside links. The cylindrical rollers themselves are provided which rotate about the bushings. Such roller chain is typically made of carbon or various alloy steels, and various coatings such as plating, eiectroless nickel and hard chroming, bluing, epoxy coating and even passivation (stainless steels as chain components) have been used on various types of roller chain for particular applications. It is desirable to improve the wear life, galling resistance and lubricity of the roller chain pins themselves by the use of special coatings. An ideal coating would include the wear resistance and corrosion protection provided by an eiectroless nickel autocatalytic deposition, with improved lubricity. Co-depositions usually utilized with the eiectroless nickel operation include fluorinated carbons and polytetrafluoroethylene. In preparing the roller chain pin for the eiectroless nickel co-deposition process, it is necessary to prepare the pin for the ultimate hardening of the eiectroless nickel operation that typically occurs at 700-750° F. The inventive preparation includes the carburizing of a medium carbon alloy chain pin of an alloy from 0.40% to 0.45% carbon by exposing the chain pin to a carburizing atmosphere. The chain pin is thereby case hardened to a radial depth of from 7% to 10% of its diameter inwardly from its outside surface. The chain pin is then typically direct quenched in oil and then tempered to introduce a gradient from the surface of the chain pin inwardly in carbon content from about 0.80% to about 0.40% and in hardness from a surface hardness of about 50 HRC to about 45 HRC at the inward percentage maximum depth of the case hardening. The thusly case hardened and prepared roller chain pin can then be coated with a coaling such as electroless nickel co-deposited with a polytetrafluroethylene or similar lubricity adding compound and subsequently hardening such surface coating by heating operation at about 600-750° F. The prepared roller chain will maintain its necessary strength and ductility while achieving a surface hardness of from 52-56 HRC with attendant lubricity properties of the fluorinated carbon co-composition material. Accordingly, the present invention provides a method of case hardening a medium carbon alloy chain pin comprising the steps of: providing a medium carbon alloy chain pin of 0.40% to 0.45% C, case hardening said chain pin by exposing said chain pin to carburizing atmosphere thereby case hardening said chain pin to a radial depth of 7% to 10% of its diameter, tempering said case hardened chain pin to introduce a gradient ftom the surface of the chain pin inwardly in carbon content of about 0.85% at the surface to about 0.40% and in hardness from about 50 HRC to about 45 HRC, and coating said pin with a hardening coating that increases the surface hardness to 52 to 56 HRC. Accordingly, the present invention also provides a chain pin produced by a process comprising the steps of providing a medium carbon alloy chain pin of 0.40% to 0.45%C, case hardening said chain pin by exposing said chain pin to a carburizing atmosphere thereby case hardening said chain pin to a radial depth of 7% to 10% of its diameter, tempering said case hardened chain pin to introduce a gradient from the surface of the chain pin inwardly in carbon content of about 0.85% at the surface to about 0.40%) and in hardness from about 50 HRC to about 45 HRC, and coating said chain pin with a hardening coating that increases the surface hardness to 52 to 56 HRC. With reference to the accompanying drawing, in which Figure I is a perspective view and partial cross section of a roller chain showing appropriate components. DETAILED DESCRIPTION OF THE INVENTION Referring now to Figure 1 of the drawing, a roller chain is shown generally at 10. The roller chain is comprised of alternate outside links 12 and inside links 14. Outside links 12 include openings into which the ends of pins 16 extend and are crimped in place. In certain applications of roller chain, the ends of pins 16 can extend further beyond outside links 12 and be held in place by cotter pins. Inside links 14 include openings into which bushings 18 are press fit. Cylindrical rollers 20 extend about bushings 18 and are free to rotate as the pin enters and exits the appropriate drive sprockets. A usual material for such roller chain components is medium carbon steel, such as type AISI 8642. However, various other steels or stainless steels can be used depending on the application. Pins 16 are usually sheared from selected wire or rod stock. Due to the requirement for the roller chain pins to be subsequently electroless nickel with co-deposit coated with subsequent hardening at temperatures of 600-750o F, it is generally desirable to begin with a roller chain pin material of medium carbon steel, such as AISI 8642. Such steel contains from 0.40% to 0.45% carbon. The medium carbon pins are case hardened and subsequently tempered to provide a substrate with a rich carbon surface and a gradient decreasing in carbon hardness from the surface. The carburizing itself is usually performed in a gas carburizing operation preferably at a carbon atmosphere of 0.85% at 1700° F for about two hours. This provides case hardening of the roller chain pin to a radial depth of from 7% to 10% of its diameter inwardly from its outside surface. After such carburizing, the roller chain pin is usually direct quenched in oil. The case hardened chain pin is then tempered at usually from 700-750° F for a period of about one hour. Such tempering introduces a gradient from the surface of the roller chain pin inwardly in carbon content from about 0.85% at the outer surface of the pin to about 0.40% at the inward depth of the case hardening. Further, the surface hardness of the roller chain pin decreases over a similar percentage of depth from about 50 HRC at the surface to about 45 HRC at the depth of the case hardening effect. Such prepared roller chain pins are then coated in a co-deposition process usually of electroless nickel and poiytetrafluoroe thylane or a WEAR-COTE PLUS® operation available from the WEAR-COTE International, Inc. of Rock Island, Illinois. Such WEAR-COTE PLUS® operation is described in U.S. Patent No, 4,830,889. The electroless nickel co-deposition with fluorinated carbon operation is followed by a heating operation at from 600-750° F. The resulting pins have a relatively hard surface of from 52 to 56 HRC with attendant lubricity property due to the co-deposited fluorinated carbon. Such specially prepared pins could be coupled with variously selected bushings to provide improved wear life at normal or even elevated roller chain service temperamres of up to 475° F. A specific example of the method of the present invention will now be set forth. EXAMPLE 1 Medium carbon roller chain pins of AISI 8642 steel containing from 0.40% to 0,45% carbon were selected in a size of 1.005 in. length by 0.2355 in diameter. These pins were case hardened in a carburizing atmosphere with a carbon potential of 0.85% at 1700° F for one hour and 50 minutes. The case hardened pins were then direct quenched in oil. The depth of case hardening was from 0.18 to 0.22 in. which is 7.6% to 9.3% of the diameter. The roller chain pins were then tempered at 700° F for one hour. The resulting surface hardness was 50 HRC and the hardness at a depth of about 10% diameter was 46 HRC. The pins were then subjected to a co-deposition operation of electroless nickel and polytetrafluoroethlene and subsequently heated at 700° F for one hour. This resulted in roller chain pins of a surface hardness of from 52 to 56 HRC. When assembled in to roller chain, the static chain tensile strength was still higher then the requisite 8500 lbs. minimum required for such standard size roller chain with case hardened pins. WE CLAIM: 1. A method of case hardening a medium carbon alloy chain pin comprising the steps of: providing a medium carbon alloy chain pin of 0.40% to 0.45% C, case hardening said chain pin by exposing said chain pin to carburizing atmosphere thereby case hardening said chain pin to a radial depth of 7% to 10% of its diameter, tempering said case hardened chain pin to introduce a gradient from the surface of the chain pin inwardly in carbon content of about 0.85% at the surface to about 0.40% and in hardness from about 50 HRC to about 45 HRC, and coating said pin with a hardening coating that increases the surface hardness to 52 to 56 HRC. 2. The method as claimed in claim 1, wherein the carburizing step is performed in an atmosphere with a carbon potential of about 0.85%, at a temperature of about 1700o"F for a period of about one hour and 50 minutes. 3. The method as claimed in claim 1, wherein the tempering is at about 700°F for about one hour. 4. The method as claimed in claim I, wherein said hardening coating comprises an electroless nickel and polytetrafluoroethylene following by a heating at about 750oF for about one hour. 5. The method as claimed in claim 1, wherein said chain pin is direct quenched in oil after the case hardening. 6. A cham pin produced by the method as claimed in any of the preceding claims. 7. A method of case hardening a medium carbon alloy chain pin substantially as herein described and exemplified.

Full Text

The present invention relates generally to a method of case hardening a medium carbon alloy chain pin and, more particularly, to toiler chain pins that are carburized and otherwise heat treated to allow for subsequent coating of a hardened electroless nickel enhanced with a fluorinated carbon as a co-deposit without the sacrifice of requisite metallurgical properties of the roller chain pin.
As will be described in more detail in the detailed description of the present invention, roller chain is normally made up of five components. These components include alternating inside and outside links. The inside links are press fit over bushings and are usually called roller links. The outside links are typically press fit over pins and hence are typically called pin links. Cylindrical rollers are provided outside the bushings leaving the rollers free to turn for a rolling action as the roller chain enters and exists the driving sprockets.
Typically, all high quality components of roller chain, including pins, bushings and rollers, are carburized or case hardened Link plates are thru-hardened. The carburizing process allows the outside of the pans to be transformed to a hard, wear resistant surface whereas the inner core retains the tough and ductile properties of the metal to absorb normal shock loading. In most applications, this combination provides the necessary engineered balance between wear resistance, durability and strength. In efforts to improve the overall perfonnance of roller chain, including improvements in wear life, galling resistance and

overall lubricity of the roller chain pins various types of coalings were reviewed. After reviewing the constraints of the design of the roller chain product, performance and manufacturing techniques available, the use of electroless nickel as an autocataiytic deposition was settled on as most desirable to provide corrosion protection on carbon and alloy steel roller chain pins. This was found to be superior to electroplating because of potential for embrittlement in electroplating. Further, tooting treatments such as titanium nitride were viewed as inappropriate due to the manner of application and the labor intensive requirements. Further, flame spraying and ion implantation have similar undesirable restrictions on roller chain manufacture.
Further, a co-deposit of a material to provide lubricity was also desirable. Various components such as silicon carbide, fluorinated carbon and polytetrafiuoroelhylene were all reviewed. It was decided that the poiylelrafiuoroelhylene or other similar proprietary coalings available today were best suited as a co-deposit with the electroless nickel for the roller chain pins.
The major problem faced in the electroless nickel operation is the need to harden the electroless nickel fluorinated carbon co-deposition at temperatures in the neighborhood of 600-750o F to achieve maximum hardness and wear resistance. As most roller chain pins are tempered at 300-350° F, such subsequent hardening of the electroless nickel coating would result in a reduction of the pin core hardness and strength.

SUMMARY OF THE INVENTION
It is an object of the present invention to provide a roller chain and a method of manufacturing the roller chain with a roller chain pin that is capable of being coated in a co-deposition operation including eiectroless nickel and a selected fluorinated carbon component without loss of desirable roller chain pin metallurgical properties.
As stated above, roller chain is normally made of five components. These components include outside or pin links joined by cylindrical pins, inside or roller link plates joined by cylindrical bushings, the pins themselves extending between openings in outside links and the bushings themselves extending between openings in the inside links. The cylindrical rollers themselves are provided which rotate about the bushings. Such roller chain is typically made of carbon or various alloy steels, and various coatings such as plating, eiectroless nickel and hard chroming, bluing, epoxy coating and even passivation (stainless steels as chain components) have been used on various types of roller chain for particular applications. It is desirable to improve the wear life, galling resistance and lubricity of the roller chain pins themselves by the use of special coatings. An ideal coating would include the wear resistance and corrosion protection provided by an eiectroless nickel autocatalytic deposition, with improved lubricity. Co-depositions usually utilized with the eiectroless nickel operation include fluorinated carbons and polytetrafluoroethylene.
In preparing the roller chain pin for the eiectroless nickel co-deposition process, it is necessary to prepare the pin for the ultimate hardening of the eiectroless nickel operation that typically occurs at 700-750° F. The inventive preparation includes the carburizing of a medium carbon alloy chain pin of an alloy from 0.40% to 0.45% carbon by exposing the

chain pin to a carburizing atmosphere. The chain pin is thereby case hardened to a radial depth of from 7% to 10% of its diameter inwardly from its outside surface. The chain pin is then typically direct quenched in oil and then tempered to introduce a gradient from the surface of the chain pin inwardly in carbon content from about 0.80% to about 0.40% and in hardness from a surface hardness of about 50 HRC to about 45 HRC at the inward percentage maximum depth of the case hardening. The thusly case hardened and prepared roller chain pin can then be coated with a coaling such as electroless nickel co-deposited with a polytetrafluroethylene or similar lubricity adding compound and subsequently hardening such surface coating by heating operation at about 600-750° F. The prepared roller chain will maintain its necessary strength and ductility while achieving a surface hardness of from 52-56 HRC with attendant lubricity properties of the fluorinated carbon co-composition material.

Accordingly, the present invention provides a method of case hardening a medium carbon alloy chain pin comprising the steps of: providing a medium carbon alloy chain pin of 0.40% to 0.45% C, case hardening said chain pin by exposing said chain pin to carburizing atmosphere thereby case hardening said chain pin to a radial depth of 7% to 10% of its diameter, tempering said case hardened chain pin to introduce a gradient ftom the surface of the chain pin inwardly in carbon content of about 0.85% at the surface to about 0.40% and in hardness from about 50 HRC to about 45 HRC, and coating said pin with a hardening coating that increases the surface hardness to 52 to 56 HRC.
Accordingly, the present invention also provides a chain pin produced by a process comprising the steps of providing a medium carbon alloy chain pin of 0.40% to 0.45%C, case hardening said chain pin by exposing said chain pin to a carburizing atmosphere thereby case hardening said chain pin to a radial depth of 7% to 10% of its diameter, tempering said case hardened chain pin to introduce a gradient from the surface of the chain pin inwardly in carbon content of about 0.85% at the surface to about 0.40%) and in hardness from about 50 HRC to about 45 HRC, and coating said chain pin with a hardening coating that increases the surface hardness to 52 to 56 HRC.
With reference to the accompanying drawing, in which
Figure I is a perspective view and partial cross section of a roller chain showing appropriate components.
DETAILED DESCRIPTION OF THE INVENTION
Referring now to Figure 1 of the drawing, a roller chain is shown generally at 10. The roller chain is comprised of alternate outside links 12 and inside links 14. Outside links 12 include openings into which the ends of pins 16 extend and are crimped in place. In certain applications of roller chain, the ends of pins 16 can extend further beyond outside

links 12 and be held in place by cotter pins. Inside links 14 include openings into which bushings 18 are press fit. Cylindrical rollers 20 extend about bushings 18 and are free to rotate as the pin enters and exits the appropriate drive sprockets. A usual material for such roller chain components is medium carbon steel, such as type AISI 8642. However, various other steels or stainless steels can be used depending on the application. Pins 16 are usually sheared from selected wire or rod stock.
Due to the requirement for the roller chain pins to be subsequently electroless nickel with co-deposit coated with subsequent hardening at temperatures of 600-750o F, it is generally desirable to begin with a roller chain pin material of medium carbon steel, such as AISI 8642. Such steel contains from 0.40% to 0.45% carbon. The medium carbon pins are case hardened and subsequently tempered to provide a substrate with a rich carbon surface and a gradient decreasing in carbon hardness from the surface. The carburizing itself is usually performed in a gas carburizing operation preferably at a carbon atmosphere of 0.85% at 1700° F for about two hours. This provides case hardening of the roller chain pin to a radial depth of from 7% to 10% of its diameter inwardly from its outside surface. After such carburizing, the roller chain pin is usually direct quenched in oil. The case hardened chain pin is then tempered at usually from 700-750° F for a period of about one hour. Such tempering introduces a gradient from the surface of the roller chain pin inwardly in carbon content from about 0.85% at the outer surface of the pin to about 0.40% at the inward depth of the case hardening. Further, the surface hardness of the roller chain pin decreases over a similar percentage of depth from about 50 HRC at the surface to about 45 HRC at the depth of the case hardening effect.

Such prepared roller chain pins are then coated in a co-deposition process usually of electroless nickel and poiytetrafluoroe thylane or a WEAR-COTE PLUS® operation available from the WEAR-COTE International, Inc. of Rock Island, Illinois. Such WEAR-COTE PLUS® operation is described in U.S. Patent No, 4,830,889. The electroless nickel co-deposition with fluorinated carbon operation is followed by a heating operation at from 600-750° F. The resulting pins have a relatively hard surface of from 52 to 56 HRC with attendant lubricity property due to the co-deposited fluorinated carbon.
Such specially prepared pins could be coupled with variously selected bushings to provide improved wear life at normal or even elevated roller chain service temperamres of up to 475° F.
A specific example of the method of the present invention will now be set forth. EXAMPLE 1
Medium carbon roller chain pins of AISI 8642 steel containing from 0.40% to 0,45% carbon were selected in a size of 1.005 in. length by 0.2355 in diameter. These pins were case hardened in a carburizing atmosphere with a carbon potential of 0.85% at 1700° F for one hour and 50 minutes. The case hardened pins were then direct quenched in oil. The depth of case hardening was from 0.18 to 0.22 in. which is 7.6% to 9.3% of the diameter. The roller chain pins were then tempered at 700° F for one hour. The resulting surface hardness was 50 HRC and the hardness at a depth of about 10% diameter was 46 HRC. The pins were then subjected to a co-deposition operation of electroless nickel and polytetrafluoroethlene and subsequently heated at 700° F for one hour. This resulted in roller chain pins of a surface hardness of from 52 to 56 HRC. When assembled in to roller

chain, the static chain tensile strength was still higher then the requisite 8500 lbs. minimum required for such standard size roller chain with case hardened pins.

WE CLAIM:
1. A method of case hardening a medium carbon alloy chain pin comprising the steps of: providing a medium carbon alloy chain pin of 0.40% to 0.45% C, case hardening said chain pin by exposing said chain pin to carburizing atmosphere thereby case hardening said chain pin to a radial depth of 7% to 10% of its diameter, tempering said case hardened chain pin to introduce a gradient from the surface of the chain pin inwardly in carbon content of about 0.85% at the surface to about 0.40% and in hardness from about 50 HRC to about 45 HRC, and coating said pin with a hardening coating that increases the surface hardness to 52 to 56 HRC.
2. The method as claimed in claim 1, wherein the carburizing step is performed in an atmosphere with a carbon potential of about 0.85%, at a temperature of about 1700o"F for a period of about one hour and 50 minutes.
3. The method as claimed in claim 1, wherein the tempering is at about 700°F for about one hour.
4. The method as claimed in claim I, wherein said hardening coating comprises an electroless nickel and polytetrafluoroethylene following by a heating at about 750oF for about one hour.
5. The method as claimed in claim 1, wherein said chain pin is direct quenched in oil after the case hardening.
6. A cham pin produced by the method as claimed in any of the preceding claims.

7. A method of case hardening a medium carbon alloy chain pin substantially as herein described and exemplified.

Documents:

1054-mas-1998 abstract-duplicate.pdf

1054-mas-1998 abstract.pdf

1054-mas-1998 claims-duplicate.pdf

1054-mas-1998 claims.pdf

1054-mas-1998 correspondence-others.pdf

1054-mas-1998 correspondence-po.pdf

1054-mas-1998 description (complete)-duplicate.pdf

1054-mas-1998 description (complete).pdf

1054-mas-1998 drawings-duplicate.pdf

1054-mas-1998 drawings.pdf

1054-mas-1998 form-19.pdf

1054-mas-1998 form-2.pdf

1054-mas-1998 form-26.pdf

1054-mas-1998 form-4.pdf

1054-mas-1998 form-6.pdf

1054-mas-1998 others.pdf

1054-mas-1998 petition.pdf

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Patent Number

198267

Indian Patent Application Number

1054/MAS/1998

PG Journal Number

20/2006

Publication Date

19-May-2006

Grant Date

16-Jan-2006

Date of Filing

15-May-1998

Name of Patentee

M/S. AMSTED INDUSTRIES INCORPORATED

Applicant Address

44TH FLOOR, BOULEVARD TOWERS SOUTH, 205 NORTH MICHIGAN AVENUE, CHICAGO,ILLINOIS 60601,

Inventors:

#	Inventor's Name	Inventor's Address
1	ROBERT T DUERIGEN	633 CLOSSEY DRIVE, INDIANAPOLIS, INDIANA 46227-2525,
2	ANDREW J BINFORD	7555 CRICKWOOD LANE, INDIANAPOLIS, INDIANA 46268,

PCT International Classification Number

F16G 013/06

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	08/917, 307	1997-08-25	U.S.A.