Apparatus and method for machining of hard metals with reduced detrimental white layer effect
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B23B-001/00
B23Q-011/10
출원번호
US-0502835
(2003-01-21)
등록번호
US-8220370
(2012-07-17)
우선권정보
US-10/066830 (2002-02-04)
국제출원번호
PCT/US03/01682
(2003-01-21)
§371/§102 date
20040917
(20040917)
국제공개번호
WO03/066916
(2003-08-14)
발명자
/ 주소
Zurecki, Zbigniew
Ghosh, Ranajit
Frey, John Herbert
Taylor, James Bryan
출원인 / 주소
Air Products & Chemicals, Inc.
대리인 / 주소
Caesar Rivise Bernstein Cohen & Pokotilow, Ltd
인용정보
피인용 횟수 :
0인용 특허 :
60
초록▼
An apparatus and a method are disclosed for reducing a thickness of a thermomechanically-affected layer on an as-machined surface of a hard metal workpiece being machined by a hard cutting tool exerting a thermomechanical load on a surface of the workpiece. The method involves reducing the thermomec
An apparatus and a method are disclosed for reducing a thickness of a thermomechanically-affected layer on an as-machined surface of a hard metal workpiece being machined by a hard cutting tool exerting a thermomechanical load on a surface of the workpiece. The method involves reducing the thermomechanical load on the surface of the workpiece, and the apparatus includes a means for reducing the thermomechanical load on the surface of the workpiece.
대표청구항▼
1. A method for reducing a thickness of a thermomechanically-affected layer, including a white layer (WL) and a dark layer (DL), on and under an as-machined surface of a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, being machined by a hard cutting tool, having an
1. A method for reducing a thickness of a thermomechanically-affected layer, including a white layer (WL) and a dark layer (DL), on and under an as-machined surface of a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, being machined by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, comprising: reducing the thermomechanical load being exerted on the surface of the hard metal workpiece by the hard cutting tool,wherein the step of reducing the thermomechanical load comprises one or a combination of at least two of the following:(a) cooling the hard cutting tool with a first precisely aimed jet or spray of an inert, water-free coolant having an initial temperature in a range of about −250° C. to about +25° C.;(b) cooling the as-machined surface of the hard metal workpiece with at least one of the first precisely aimed jet or spray and a second precisely aimed jet or spray of the inert, water-free coolant or an other inert, water-free coolant having an initial temperature in a range of about −250° C. to about +25° C.; and(c) reducing a cutting force component in a direction normal to the as-machined surface of the hard metal workpiece when at least a portion of the thermomechanical load is a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece. 2. A method as in claim 1, wherein at least one of the first and second jet or spray of the inert, water-free coolant or the other inert, water-free coolant comprises at least one stream containing a cryogenic fluid or at least one ice particle having a temperature less than −75° C. 3. A method as in claim 1, wherein the cutting tool has an inclination angle, and wherein the component of the cutting force is reduced by making the inclination angle more positive. 4. A method as in claim 1, wherein the cutting tool has a rake angle, and wherein the component of the cutting force is reduced by making the rake angle more positive. 5. A method as in claim 1, wherein the hard cutting tool has a hardness and a resistance to cracking, and wherein cooling the hard cutting tool with the first precisely aimed jet or spray of the inert, water-free coolant results in an increase in the hardness or an increase in the resistance to cracking. 6. A method as in claim 1, wherein the hard metal workpiece comprises an iron-containing alloy. 7. A method as in claim 1, wherein the hard cutting tool is made at least in part of a material selected from a group containing a ceramic compound; a ceramic-ceramic composite; a ceramic-metal composite; a diamond-like, metal-free material; an alumina-based ceramic; a cubic boron nitride-based ceramic material; a tungsten carbide-based material; and a cermet-type material. 8. A method for reducing a thickness of a thermomechanically-affected layer, including a white layer (WL) and a dark layer (DL), on and under an as-machined surface of a hard metal workpiece, having an edge hardness exceeding 42 Rockwell on Scale C, being machined by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool initially having a first temperature prior to contacting the surface of the hard metal workpiece, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, at least a portion of the thermomechanical load being a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, comprising the steps of: cooling the hard cutting tool to a second temperature lower than the first temperature before the hard cutting tool contacts the surface of the hard metal workpiece or while the hard metal workpiece is being machined by the hard cutting tool; andreducing the component of the cutting force. 9. A method for mitigating a detrimental effect of a thermomechanical load in a machined surface of a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vicker, the hard cutting tool machining the hard metal workpiece, thereby forming the machined surface, comprising cooling the machined surface by a cooling means having an initial temperature in a range of about −250° C. to about +25° C. 10. A method as in claim 9, wherein the cooling means comprises at least one stream containing a cryogenic fluid or at least one ice particle having a temperature less than −75° C. 11. A method as in claim 9, wherein the cooling means comprises at least one inert, water-free coolant. 12. A method as in claim 9, wherein the hard metal workpiece comprises an iron-containing alloy. 13. A method as in claim 9, wherein the hard cutting tool is made at least in part of a material selected from a group containing a ceramic compound; a ceramic-ceramic composite; a ceramic-metal composite; a diamond-like, metal-free material; an alumina-based ceramic; a cubic boron nitride-based ceramic material; a tungsten carbide-based material; and a cermet-type material. 14. A method for mitigating a detrimental effect of a thermomechanical load in a machined surface of a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool machining the hard metal workpiece, thereby forming the machined surface, wherein at least a portion of the thermomechanical load is a component of a cutting force, the component being applied in a direction normal to the surface of the workpiece, comprising the steps of: cooling the machined surface by a cooling means having an initial temperature in a range of about −250° C. to about +25° C.; andreducing the component of the cutting force. 15. A method as claim 14 wherein the hard cutting tool has an inclination angle, and wherein the component of the cutting force is reduced by making the inclination angle more positive and the cooling means comprises at least one stream containing a cryogenic fluid or at least one ice particle having a temperature less than −75° C. 16. A method for mitigating a detrimental effect of a thermomechanical load in a machined surface of a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool machining the hard metal workpiece, thereby forming the machined surface, wherein at least a portion of the thermomechanical load is a component of the cutting force, the component being applied in a direction normal to the surface of the workpiece, comprising the steps of: cooling the machined surface by a cooling means having an initial temperature in a range of about −250° C. to about +25° C.;cooling the hard cutting tool simultaneously by the cooling means; andreducing the component of the cutting force. 17. A method as in claim 16, wherein the hard cutting tool has an inclination angle, and wherein the component of the cutting force is reduced by making the inclination angle more positive and the cooling means comprises at least one stream containing a cryogenic fluid with at least one ice particle having a temperature less than −75° C. 18. A method for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a thickness of a thermomechanically-affected layer, including a white layer (WL) and a dark layer (DL), on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined with a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool initially having a first temperature prior to contacting the surface of the hard metal workpiece, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, comprising cooling the hard cutting tool to a second temperature lower than the first temperature before the hard cutting tool contacts the surface of the hard metal workpiece or while the hard metal workpiece is being machined. 19. An after-machined workpiece having been machined by a method for machining a hard metal workpiece, whereby a thickness of a thermomechanically-affected layer on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined with a hard cutting tool initially having a first temperature prior to contacting the surface of the hard metal workpiece, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, the method comprising cooling the hard cutting tool to a second temperature lower than the first temperature before the hard cutting tool contacts the surface of the hard metal workpiece or while the hard metal workpiece is being machined, the after-machined workpiece comprising: an after-machined surface having at least one of a lesser amount of surface residual tensile stress, a greater amount of surface residual compressive stress, a thinner thickness of the thermomechanically-affected layer, and a greater amount of microhardness compared to an other after-machined surface of an other hard metal workpiece machined by dry cutting, the other hard metal workpiece having an other amount of surface residual tensile stress, an other amount of surface residual compressive stress, an other thickness of an other thermomechanically-affected layer, and an other microhardness. 20. A method for machining a hard metal workpiece, whereby a detrimental effect of a thermomechanical load is mitigated in a machined surface of the hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool forming the machined surface of the hard metal workpiece, comprising cooling the machined surface by a cooling means having an initial temperature in a range of about −250° C. to about +25° C. 21. An after-machined workpiece having been machined by a method for machining a hard metal workpiece, whereby a detrimental effect of a thermomechanical load is mitigated in a machined surface of the hard metal workpiece, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool forming the machined surface of the hard metal workpiece, the method comprising cooling the machined surface by a cooling means having an initial temperature in a range of about −250° C. to about +25° C., the after-machined workpiece comprising: an after-machined surface having at least one of a lesser amount of surface residual tensile stress, a greater amount of surface residual compressive stress, a thinner thickness of the thermomechanically-affected layer, and a greater amount of microhardness compared to an other after-machined surface of an other hard metal workpiece machined by dry cutting, the other hard metal workpiece having an other amount of surface residual tensile stress, an other amount of surface residual compressive stress, an other thickness of an other thermomechanically-affected layer, and an other microhardness. 22. A method for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a thickness of a thermomechanically-affected layer on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined with a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, at least a portion of the thermomechanical load being a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, comprising reducing the component of the cutting force. 23. An after-machined workpiece having been machined by a method for machining a hard metal workpiece, whereby a thickness of a thermomechanically-affected layer on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined with a hard cutting tool, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, at least a portion of the thermomechanical load being a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, the method comprising reducing the component of the cutting force, the after-machined workpiece comprising: an after-machined surface having at least one of a lesser amount of surface residual tensile stress, a greater amount of surface residual compressive stress, a thinner thickness of the thermomechanically-affected layer, and a greater amount of microhardness compared to an other after-machined surface of an other hard metal workpiece machined by dry cutting, the other hard metal workpiece having an other amount of surface residual tensile stress, an other amount of surface residual compressive stress, an other thickness of an other thermomechanically-affected layer, and an other microhardness. 24. A method for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a thickness of a thermomechanically-affected layer, including a white layer (WL) and a dark layer (DL), on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined with a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool initially having a first temperature prior to contacting the surface of the hard metal workpiece, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, at least a portion of the thermomechanical load being a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, comprising the steps of: cooling the hard cutting tool to a second temperature lower than the first temperature before the hard cutting tool contacts the surface of the hard metal workpiece or while the hard metal workpiece is being machined; andreducing the component of the cutting force. 25. A method for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a detrimental effect of a thermomechanical load is mitigated in a machined surface of the hard metal workpiece, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool forming the machined surface of the hard metal workpiece, comprising the steps of: cooling the machined surface by a cooling means having an initial temperature in a range of about −250° C. to about +25° C.; andcooling the hard cutting tool simultaneously by the cooling means. 26. A method for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a detrimental effect of a thermomechanical load is mitigated in a machined surface of the hard metal workpiece, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool forming the machined surface of the hard metal workpiece, wherein at least a portion of the thermomechanical load is a component of a cutting force, the component being applied in a direction normal to the surface of the workpiece, comprising the steps of: cooling the machined surface by a cooling means having an initial temperature in a range of about −250° C. to about +25° C.; andreducing the component of the cutting force. 27. An apparatus for reducing a thickness of a thermomechanically-affected layer, including a white layer (WL) and a dark layer (DL), on and under an as-machined surface of a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, being machined by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, comprising: a means for reducing the thermomechanical load being exerted on the surface of the hard metal workpiece by the hard cutting tool,wherein the means for reducing the thermomechanical load comprises one or a combination of at least two of the following:(a) a means for cooling the hard cutting tool with a first precisely aimed jet or spray of an inert, water-free coolant having an initial temperature in a range of about −250° C. to about +25° C.;(b) a means for cooling the as-machined surface of the hard metal workpiece with at least one of the first precisely aimed jet or spray and a second precisely aimed jet or spray of the inert, water-free coolant or an other inert, water-free coolant having an initial temperature in a range of about −250° C. to about +25° C.; and(c) a means (B-O-C of CT) for reducing a cutting force component in a direction normal to the as-machined surface of the hard metal workpiece when at least a portion of the thermomechanical load is a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece. 28. An apparatus as in claim 27, wherein the hard metal workpiece comprises an iron-containing alloy. 29. An apparatus as in claim 27, wherein the hard cutting tool is made at least in part of a material selected from a group containing a ceramic compound; a ceramic-ceramic composite; a ceramic-metal composite; a diamond-like, metal-free material; an alumina-based ceramic; a cubic boron nitride-based ceramic material; a tungsten carbide-based material; and a cermet-type material. 30. An apparatus for reducing a thickness of a thermomechanically-affected layer on an as-machined surface of a hard metal workpiece having a surface hardness exceeding 42 Rockwell on Scale C, being machined by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool initially having a first temperature prior to contacting the surface of the hard metal workpiece, the hard cutting tool exerting a thermomechanical load on a surface of the workpiece, at least a portion of the thermomechanical load being a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, comprising: a means for cooling the hard cutting tool to a second temperature lower than the first temperature before the hard cutting tool contacts the surface of the hard metal workpiece or while the hard metal workpiece is being machined; anda means for reducing the component of the cutting force. 31. An apparatus for mitigating a detrimental effect of a thermomechanical load in a machined surface of a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool machining the hard metal workpiece, thereby forming the machined surface, comprising a means for cooling the machined surface by at least one stream of a coolant having an initial temperature in a range of about −250° C. to about +25° C. 32. An apparatus as in claim 31, wherein the at least one stream contains a cryogenic fluid or at least one ice particle having a temperature less than −75° C. 33. An apparatus as in claim 31, wherein the stream contains at least one inert, water-free coolant. 34. An apparatus for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a thickness of a thermomechanically-affected layer, including a white layer (WL) and a dark layer (DL), on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool initially having a first temperature prior to contacting the surface of the hard metal workpiece, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, comprising a means for cooling the hard cutting tool to a second temperature lower than the first temperature before the hard cutting tool contacts the surface of the hard metal workpiece or while the hard metal workpiece is being machined. 35. An after-machined workpiece having been machined by an apparatus for machining a hard metal workpiece, whereby a thickness of a thermomechanically-affected layer on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined by a hard cutting tool initially having a first temperature prior to contacting the surface of the hard metal workpiece, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, the apparatus comprising a means for cooling the cutting tool to a second temperature lower than the first temperature before the cutting tool contacts the surface of the hard metal workpiece or while the hard metal workpiece is being machined, the after-machined workpiece comprising: an after-machined surface having at least one of a lesser amount of surface residual tensile stress, a greater amount of surface residual compressive stress, a thinner thickness of the thermomechanically-affected layer, and a greater amount of microhardness compared to an other after-machined surface of an other hard metal workpiece machined by dry cutting, the other hard metal workpiece having an other amount of surface residual tensile stress, an other amount of surface residual compressive stress, an other thickness of an other thermomechanically-affected layer, and an other microhardness. 36. An after-machined workpiece having been machined by an apparatus for machining a hard metal workpiece, whereby a detrimental effect of a thermomechanical load is mitigated in a machined surface of the hard metal workpiece, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool forming the machined surface of the hard metal workpiece, the apparatus comprising a means for cooling the machined surface by a stream of a fluid having an initial temperature in a range of about −250° C. to about +25° C., the after-machined workpiece comprising: an after-machined surface having at least one of a lesser amount of surface residual tensile stress, a greater amount of surface residual compressive stress, a thinner thickness of the thermomechanically-affected layer, and a greater amount of microhardness compared to an other after-machined surface of an other hard metal workpiece machined by dry cutting, the other hard metal workpiece having an other amount of surface residual tensile stress, an other amount of surface residual compressive stress, an other thickness of an other thermomechanically-affected layer, and an other microhardness. 37. An apparatus for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a thickness of a thermomechanically-affected layer on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting toll exerting a thermomechanical load on a surface of the hard metal workpiece, at least a portion of the thermomechanical load being a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, comprising a means for reducing the component of the cutting force. 38. An after-machined workpiece having been machined by an apparatus for machining a hard metal workpiece, whereby a thickness of a thermomechanically-affected layer on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined by a hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, at least a portion of the thermomechanical load being a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, the apparatus comprising a means for reducing the component of the cutting force, the after-machined workpiece comprising: an after-machined surface having at least one of a lesser amount of surface residual tensile stress, a greater amount of surface residual compressive stress, a thinner thickness of the thermomechanically-affected layer, and a greater amount of microhardness compared to an other after-machined surface of an other hard metal workpiece machined by dry cutting, the other hard metal workpiece having an other amount of surface residual tensile stress, an other amount of surface residual compressive stress, an other thickness of an other thermomechanically-affected layer, and an other microhardness. 39. An apparatus for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a thickness of a thermomechanically-affected layer, including a white layer (WL) and a dark layer (DL), on an as-machined surface of the hard metal workpiece is reduced, the hard metal workpiece being machined by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool initially having a first temperature prior to contacting the surface of the hard metal workpiece, the hard cutting tool exerting a thermomechanical load on a surface of the hard metal workpiece, at least a portion of the thermomechanical load being a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, comprising: a means for cooling the hard cutting tool to a second temperature lower than the first temperature before the hard cutting tool contacts the surface of the hard metal workpiece or while the hard metal workpiece is being machined; anda means for reducing the component of the cutting force. 40. An apparatus for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a detrimental effect of a thermomechanical load is mitigated in a machined surface of the hard metal workpiece, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool forming the machined surface of the hard metal workpiece, comprising: a means for spraying the machined surface with at least one stream of a fluid having an initial temperature in a range of about −250° C. to about +25° C.; anda means for spraying at least one other stream of the fluid simultaneously on the hard cutting tool. 41. An apparatus for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a detrimental effect of a thermomechanical load is mitigated in a machined surface of the hard metal workpiece, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting toll forming the machined surface of the hard metal workpiece, wherein at least a portion of the thermomechanical load is a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, comprising: a means for spraying the machined surface with at least one stream of a fluid having an initial temperature in a range of about −250° C. to about +25° C.; anda means for reducing the component of the cutting force. 42. An apparatus for machining a hard metal workpiece, having a surface hardness exceeding 42 Rockwell on Scale C, whereby a detrimental effect of a thermomechanical load is mitigated in a machined surface of the hard metal workpiece, the thermomechanical load being exerted on a surface of the hard metal workpiece by a hard cutting tool, having an edge hardness exceeding 1500 Vickers, the hard cutting tool forming the machined surface of the hard metal workpiece, wherein at least a portion of the thermomechanical load is a component of a cutting force, the component being applied in a direction normal to the surface of the hard metal workpiece, comprising: a means for spraying the machined surface with at least one stream of a fluid having an initial temperature in a range of about −250° C. to about +25° C.;a means for spraying at least one other stream of the fluid simultaneously on the hard cutting tool; anda means for reducing the component of the cutting force.
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