IPC분류정보
| 국가/구분 |
United States(US) Patent
등록
|
| 국제특허분류(IPC7판) |
|
| 출원번호 |
US-0052364
(2001-11-09)
|
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발명자
/ 주소 |
- Conway, Christopher J.
- Rogers, Fred
- MacKenzie, Darrin H.
- Demers, Douglass A.
- Adams, Stewart Trent
- Jones, Joseph P.
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| 출원인 / 주소 |
- Thermal Dynamics Corporation
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| 대리인 / 주소 |
Harness, Dickey & Pierce, P.L.C.
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| 인용정보 |
피인용 횟수 :
27 인용 특허 :
48 |
초록
▼
A quick disconnect for use in a plasma arc torch is provided that comprises a plug housing and a mating socket housing, a locking ring disposed around the plug housing secures the plug housing to the socket housing. A negative lead gas carrying pin is disposed within the plug housing, and a mating m
A quick disconnect for use in a plasma arc torch is provided that comprises a plug housing and a mating socket housing, a locking ring disposed around the plug housing secures the plug housing to the socket housing. A negative lead gas carrying pin is disposed within the plug housing, and a mating main power socket is disposed within the socket housing for the purpose of conducting both gas and electricity from a power supply to a plasma arc torch. Further, the negative lead gas carrying pin and mating main power socket are positioned off-center in order to provide additional volume for a plurality of signal conductors disposed within each housing, along with a pilot return conductor. Additionally, both the plug housing and the socket housing define a D-configuration in order to properly align the housings and conductors disposed therein, among other novel features of the present invention.
대표청구항
▼
A quick disconnect for use in a plasma arc torch is provided that comprises a plug housing and a mating socket housing, a locking ring disposed around the plug housing secures the plug housing to the socket housing. A negative lead gas carrying pin is disposed within the plug housing, and a mating m
A quick disconnect for use in a plasma arc torch is provided that comprises a plug housing and a mating socket housing, a locking ring disposed around the plug housing secures the plug housing to the socket housing. A negative lead gas carrying pin is disposed within the plug housing, and a mating main power socket is disposed within the socket housing for the purpose of conducting both gas and electricity from a power supply to a plasma arc torch. Further, the negative lead gas carrying pin and mating main power socket are positioned off-center in order to provide additional volume for a plurality of signal conductors disposed within each housing, along with a pilot return conductor. Additionally, both the plug housing and the socket housing define a D-configuration in order to properly align the housings and conductors disposed therein, among other novel features of the present invention. ocity of the tool electrode. 4. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 3, wherein the parameters include: a spark gap between the tool electrode and the workpiece, arithmetically determined based on the machining conditions for the workpiece; and a machined-surface length extending from a machined surface being machined at a tip end of the tool electrode to a top surface of the workpiece, wherein said jump-up quantity estimating module estimates an optimal jump-up quantity for the tool electrode based on the shape information of the tool electrode, the spark gap, and the machined-surface length. 5. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 3, wherein the parameters include kinematic viscosity of the processing liquid, and said jumping velocity estimating module estimates the jumping velocity of the tool electrode required, at a minimum, based on the kinematic viscosity of the processing liquid. 6. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 3, wherein the parameters include: a spark gap between the tool electrode and the workpiece; a machined-surface length extending from a machined surface being machined at a tip end of the tool electrode to a top surface of the workpiece; an outer peripheral length of the tool electrode at the top surface of the workpiece; a machining area defined at the tip end of the tool electrode; kinematic viscosity of the processing liquid; and a constant indicating a ratio between an inertia force and a viscous force of the processing liquid, wherein the constant is set to a value greater than "10" depending on the jumping velocity of the tool electrode estimated by said jumping velocity estimating module, said jump-up quantity estimating module estimates, arithmetically, an optimum jump-up quantity for the tool electrode based on the parameters in accordance with ju=d·h·L/S, and said jumping velocity estimating module estimates, arithmetically, the jumping velocity of the tool electrode required, at a minimum, based on the parameters in accordance with jmp=Re·L·n/S. 7. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 3, wherein the parameters include: a spark gap between the tool electrode and the workpiece; a machined-surface length extending from a machined surface being machined at a tip end of the tool electrode to a top surface of the workpiece; an outer peripheral length of the tool electrode at the top surface of the workpiece; a tip end width of the tool electrode; kinematic viscosity of the processing liquid; and a constant indicating a ratio between an inertia force and a viscous force of the processing liquid, wherein the constant is set to a value greater than "10" depending on the jumping velocity of the tool electrode estimated by said jumping velocity estimating module, and the tool electrode has a rib-like shape, said jump-up quantity estimating module estimates, arithmetically, an optimum jump-up quantity for the tool electrode based on the parameters in accordance with ju=2d·h/w, while said jumping velocity estimating module estimates, arithmetically, the jumping velocity of the tool electrode required, at a minimum, based on the parameters in accordance with jmp=2Re·n/w. 8. A jump control apparatus for an electric discharge shaping/profiling machine for machining a workpiece by applying a pulse voltage across a tool electrode mounted at one end of a main spindle and the workpiece disposed in opposition to the tool electrode with a processing liquid intervening therebetween, the apparatus comprising: a feed control unit for controlling a feed quantity of a main spindle to control a vertical position of a tool electrode relative to a workpiece; a jump condition estimating unit for estimating jump conditions for effectuating jump motion of the tool electrode for discharging sludge from between the tool electrode and the workpiece in a machining process performed on the workpiece, the jump conditions estimated being input to said feed control unit; an input unit for inputting machining conditions considering the jump conditions in precedence to a machining process to be performed on the workpiece; and a numerical control unit for determining, arithmetically, parameters depending on the machining conditions and input to said jump condition estimating unit, wherein said jump condition estimating unit estimates the jump conditions based on the parameters in precedence to machining of the workpiece. 9. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 8, further comprising machining stage detecting means for detecting machining stages of the workpiece based on movement of the main spindle, wherein the machining conditions include a plurality of preset values which differ depending on the machining stages, and said numerical control unit arithmetically determines the parameters based on the machining conditions corresponding to the machining stages, respectively. 10. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 8, wherein the parameters include shape information concerning the tool electrode, and wherein said jump condition estimating unit includes: a jump-up quantity estimating module estimating jump-up quantity of the tool electrode; and a jumping velocity estimating module estimating jumping velocity of the tool electrode. 11. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 10, wherein the parameters include: a spark gap between the tool electrode and the workpiece, arithmetically determined based on the machining conditions for the workpiece; and a machined-surface length extending from a machined surface being machined at a tip end of the tool electrode to a top surface of the workpiece, wherein said jump-up quantity estimating module estimates an optimal jump-up quantity for the tool electrode based on the shape information of the tool electrode, the spark gap, and the machined-surface length. 12. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 10, wherein the parameters include kinematic viscosity of the processing liquid, and said jumping velocity estimating module estimates the jumping velocity of the tool electrode required, at a minimum, based on the kinematic viscosity of the processing liquid. 13. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 10, wherein the parameters include: a spark gap between the tool electrode and the workpiece; a machined-surface length extending from a machined surface being machined at a tip end of the tool electrode to a top surface of the workpiece; an outer peripheral length of the tool electrode at the top surface of the workpiece; a machining area defined at the tip end of the tool electrode; kinematic viscosity of the processing liquid; and a constant indicating a ratio between an inertia force and a viscous force of the processing liquid, wherein the constant is set to a value greater than "10" depending on the jumping velocity of the tool electrode estimated by said jumping velocity estimating module, said jump-up quantity estimating module estimates, arithmetically, an optimum jump-up quantity for the tool electrode based on the parameters in accordance with ju=d·h·L/S, and said jumping velocity estimating module estimates, arithmetically, the jumping velocity of the tool electrode required, at a minimum, based on the parameters in accordance with jmp=Re·L·n/S. 14. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 10, wherein the parameters include: a spark gap betwe en the tool electrode and the workpiece; a machined-surface length extending from a machined surface being machined at a tip end of the tool electrode to a top surface of the workpiece; an outer peripheral length of the tool electrode at the top surface of the workpiece; a tip end width of the tool electrode; kinematic viscosity of the processing liquid; and a constant indicating a ratio between an inertia force and a viscous force of the processing liquid, wherein the constant is set to a value greater than "10" depending on the jumping velocity of the tool electrode estimated by said jumping velocity estimating module, and the tool electrode has a rib-like shape, said jump-up quantity estimating module estimates, arithmetically, an optimum jump-up quantity for the tool electrode based on the parameters in accordance with ju=2d·h/w, while said jumping velocity estimating module estimates, arithmetically, the jumping velocity of the tool electrode required, at a minimum, based on the parameters in accordance with jmp=2Re·n/w. 15. A jump control apparatus for an electric discharge shaping/profiling machine for machining a workpiece by applying a pulse voltage across a tool electrode mounted at one end of a main spindle and the workpiece disposed in opposition to the tool electrode with a processing liquid intervening therebetween, the apparatus comprising: a feed control unit for controlling a feed quantity of a main spindle to control a vertical position of a tool electrode relative to a workpiece; a jump condition estimating unit for estimating jump conditions for effectuating jump motion of the tool electrode for discharging sludge from between the tool electrode and the workpiece in a machining process performed on the workpiece, the jump conditions estimated being input to said feed control unit; an input unit for inputting machining conditions considering the jump conditions in precedence to a machining process to be performed on the workpiece; and a numerical control unit for determining, arithmetically, parameters depending on the machining conditions and input to said jump condition estimating unit, wherein said jump condition estimating unit determines values for the jump conditions through inference based on the parameters, upon starting of machining of the workpiece, the values being output. 16. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 15, further comprising machining stage detecting means for detecting machining stages of the workpiece based on movement of the main spindle, wherein the machining conditions include a plurality of preset values which differ depending on the machining stages, and said numerical control unit arithmetically determines the parameters based on the machining conditions conforming to the machining stages, respectively. 17. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 15, wherein the parameters include shape information concerning the tool electrode, and wherein said jump condition estimating unit includes: a jump-up quantity estimating module estimating jump-up quantity of the tool electrode; and a jumping velocity estimating module estimating jumping velocity of the tool electrode. 18. The jump control apparatus for an electric discharge shaping/profiling machine according to claim 17, wherein the parameters include: a spark gap between the tool electrode and the workpiece, arithmetically determined based on the machining conditions for the workpiece; and a machined-surface length extending from a machined surface being machined at a tip end of the tool electrode to a top surface of the workpiece, wherein said jump-up quantity estimating module estimates an optimal jump-up quantity for the tool electrode based on the shape information of the tool electrode, the spark gap, and the machined-surface length. 19. The jump control apparatus for an e
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