Flex shaft-drive motor connection for power operated rotary knife
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F16C-001/06
F16C-001/08
F16D-001/10
출원번호
US-0344760
(2012-01-06)
등록번호
US-8968107
(2015-03-03)
발명자
/ 주소
Rapp, Geoffrey D.
Muniga, Scott M.
Rosu, Marinel
Whited, Jeffrey A.
Mascari, Nicholas A.
출원인 / 주소
Bettcher Industries, Inc.
대리인 / 주소
Tarolli, Sundheim, Covell & Tummino LLP
인용정보
피인용 횟수 :
3인용 특허 :
24
초록▼
A flexible shaft drive transmission for transmitting rotational power between a drive motor and a gear train of a power operated tool. The flexible shaft drive transmission includes an elongated drive shaft assembly including a rotatable drive transmitting shaft assembly extending through an outer c
A flexible shaft drive transmission for transmitting rotational power between a drive motor and a gear train of a power operated tool. The flexible shaft drive transmission includes an elongated drive shaft assembly including a rotatable drive transmitting shaft assembly extending through an outer casing. The shaft drive transmission includes a motor end coupling affixed to one end the outer casing and adapted to be releasably connected to a mating coupling of the drive motor. The motor end coupling includes a coupling body having an outer surface tapered region tapering from a larger diameter to a smaller diameter at a distal end of the tapered region to facilitate insertion and proper alignment with the drive motor coupling. The drive transmitting shaft assembly includes a driven fitting having a plurality of drive faces surrounding an axially extending locating member for engagement with a mating drive fitting of the drive motor.
대표청구항▼
1. A flexible shaft drive transmission coupled between a coupling of a drive motor and a gear train of a power operated tool, the flexible shaft drive transmission comprising: a) an elongated drive shaft assembly including a flexible, rotatable drive transmitting shaft extending along a longitudinal
1. A flexible shaft drive transmission coupled between a coupling of a drive motor and a gear train of a power operated tool, the flexible shaft drive transmission comprising: a) an elongated drive shaft assembly including a flexible, rotatable drive transmitting shaft extending along a longitudinal axis, a first driven fitting at one end of the drive transmitting shaft and a second drive fitting at a second end of the drive transmitting shaft, the first driven fitting and the second drive fitting rotating with the drive transmitting shaft;b) a flexible outer casing including first and second ends and defining a through bore, the outer casing receiving the drive transmitting shaft within the through bore and supporting the drive transmitting shaft for rotation within the outer casing; andc) a motor end coupling affixed to the first end of the outer casing and adapted to be releasably connected to the drive motor coupling, the motor end coupling including a coupling body defining a central opening through which the drive transmitting shaft passes and having an outer surface defining a tapered region, the tapered region having a proximal end and a distal end, the proximal end of the tapered region of the coupling body being closer in proximity to the outer casing than the distal end of the tapered region, the tapered region tapering from a first diameter at the proximal end of the tapered region to a second diameter at the distal end of the tapered region, the first diameter being larger than the second diameter, the tapered region of the coupling body configured to contact and interfit with the drive motor coupling and including a plurality of axially extending raised ribs radially spaced apart by a plurality of channels, each pair of adjacent ribs of the plurality of ribs being separated by a channel of the plurality of channels, the tapered region having a configuration of a frustoconical, tapered cone. 2. The flexible shaft drive transmission of claim 1 wherein the outer surface of the tapered region of the coupling body of the motor end coupling tapers uniformly from between the proximal and distal ends. 3. The flexible shaft drive transmission of claim 1 wherein the outer surface of the tapered region of the coupling body of the motor end coupling is conical between the proximal and distal ends. 4. The flexible shaft drive transmission of claim 1 wherein each of the ribs of the plurality of ribs of the tapered region of the coupling body are tapered in radial width from a wider first end to a narrower second end, the wider first end being closer to the proximal end of the tapered region of the coupling body and the narrower second end being closer to the distal end of the tapered region. 5. The flexible shaft drive transmission of claim 1 wherein each of the channels of the plurality of channels of the tapered region are tapered in radial width from a wider first end to a narrower second end, the wider first end being closer to the proximal end of the tapered region of the coupling body and the narrower second end being closer to the distal end of the tapered region. 6. The flexible shaft drive transmission of claim 1 wherein the motor end coupling defines a through bore in communication with the through bore of the outer casing, the drive transmitting shaft extending through the motor end coupling through bore and the driven fitting extending beyond a distal end of the coupling. 7. The flexible shaft drive transmission of claim 6 wherein the motor end coupling further includes a support pedestal, the support pedestal extending through the central opening of the coupling body, the support pedestal including a longitudinal passageway defining at least a portion of the motor end coupling through bore, the coupling body being radially and axially constrained with respect to the support pedestal. 8. The flexible shaft drive transmission of claim 7 wherein the motor end coupling further includes a sleeve bushing at a distal end of the support pedestal, the sleeve bushing including an enlarged head and an extending shaft, the shaft received in the longitudinal passageway of the support pedestal and the enlarged head defining a bearing surface for rotationally supporting the driven fitting of the drive shaft assembly. 9. The flexible shaft drive transmission of claim 8 wherein the extending shaft of the sleeve bushing defines a passageway, the passageway defining at least a portion of the motor end coupling through bore. 10. A flexible shaft drive transmission coupled between a drive motor and a gear train of a power operated tool, the flexible shaft drive transmission comprising: a) an elongated drive shaft assembly including a flexible, rotatable drive transmitting shaft extending along a longitudinal axis, a first driven fitting at one end of the drive transmitting shaft and a second drive fitting at a second end of the drive transmitting shaft, the first driven fitting and the second drive fitting rotating with the drive transmitting shaft, the first driven fitting adapted to engage a drive fitting of a drive motor;b) a flexible outer casing including first and second ends and defining a through bore, the outer casing receiving the drive transmitting shaft within the through bore and supporting the drive transmitting shaft for rotation within the outer casing; andc) the first driven fitting including a cylindrical base, a plurality of vanes defining a plurality of drive engagement faces, each vane of the plurality of vanes defining a drive engagement face of the plurality of drive engagement faces, and a locating member, the cylindrical base includes a planar upper surface and an outer surface, the plurality of vanes and the axially extending locating member extend axially from the planar upper surface of the cylindrical base, each vane of the plurality of vanes includes an outer surface congruent and coextensive with the outer surface of the cylindrical base, the plurality of drive engagement faces are disposed about the axially extending locating member, wherein each of the plurality of drive engagement faces is planar and extend radially with respect to the longitudinal axis of the drive transmitting shaft such that a plane extending along and coextensive with each of the plurality of drive engagement faces would intersect the longitudinal axis of the drive transmitting shaft. 11. The flexible shaft drive transmission of claim 10 wherein the axially extending locating member comprises a central projection aligned with the longitudinal axis of the drive transmitting shaft. 12. The flexible shaft drive transmission of claim 11 wherein the plurality of drive engagement faces of the first driven fitting extend radially outwardly from the central projection. 13. The flexible shaft drive transmission of claim 10 wherein each drive engagement face of the plurality of drive engagement faces of the first driven fitting is substantially planar. 14. The flexible shaft drive transmission of claim 13 wherein each drive engagement face of the plurality of drive engagement faces extends substantially parallel to the longitudinal axis of the drive transmitting shaft. 15. The flexible shaft drive transmission of claim 10 wherein each vane of the plurality of vanes includes a back wall, the back wall and the drive engagement face of the vane forming an included angle therebetween, the included angle being an acute angle. 16. The flexible shaft drive transmission of claim 10 wherein the cylindrical base of the first driven fitting further includes a proximal wall, the proximal wall including an axially stepped central portion which functions as a seating surface for the first driven fitting, the axially stepped central portion extending in a direction opposite a direction that the plurality of vanes and the locating member extend from the planar upper surface of the cylindrical base. 17. A connection structure for a flexible shaft drive transmission and a drive motor, the flexible shaft drive transmission transmitting rotational power between the drive motor and a gear train of a power operated tool, the connection structure comprising: a) the flexible shaft drive transmission including:i) an elongated drive shaft assembly including a flexible, rotatable drive transmitting shaft extending along a central longitudinal axis, a first driven fitting at one end of the drive transmitting shaft and a second drive fitting at a second end of the drive transmitting shaft, the first driven fitting and the second drive fitting rotating with the drive transmitting shaft;ii) a flexible outer casing including first and second ends and defining a through bore, the outer casing receiving the drive transmitting shaft within the through bore and supporting the drive transmitting shaft for rotation within the outer casing; andiii) a first motor end coupling affixed to the first end the outer casing, the motor end coupling including a coupling body defining a central opening through which the drive transmitting shaft passes and having an outer surface defining a tapered region, the tapered region having a proximal end and a distal end, the proximal end of the tapered region of the coupling body being closer in proximity to the outer casing than the distal end of the tapered region, the tapered region tapering from a first diameter at the proximal end of the tapered region to a second diameter at the distal end of the tapered region, the first diameter being larger than the second diameter; andb) the drive motor including: a drive fitting rotatable about an axis of rotation and a coupling, the coupling including a collar, an inner surface of the collar including a tapered region defining a tapered opening configured to receive the coupling body of the motor end coupling such that the drive fitting of the drive motor operatively engages the driven fitting of the drive shaft assembly to rotate the drive transmitting shaft within the outer casing of the shaft drive transmission, wherein the tapered region of the coupling body of the first motor end coupling is received in the tapered opening of the collar of the drive motor coupling and the tapered region of the coupling body contacts and interfits with the tapered region of the collar of the drive motor coupling along an entirety of a region of overlap between the tapered region of the coupling body and the tapered region of the collar of the drive motor coupling. 18. The connection structure of claim 17 wherein the coupling of the drive motor includes a latching mechanism to secure the coupling body of the motor end coupling to the drive motor coupling. 19. The connection structure of claim 18 wherein the latching mechanism includes a latch that moves transversely with respect to the axis of rotation of the drive fitting of the drive motor to engage the coupling body of the motor end coupling and secure the coupling body to the drive motor coupling. 20. The connection structure of claim 19 wherein latch of the latching mechanism engages a proximal end of the coupling body to secure the coupling body to the drive motor coupling. 21. The connection structure of claim 20 wherein the collar of the drive motor coupling moves axially with respect to the axis of rotation of the drive fitting to provide clearance between the latch and the coupling body of the motor end coupling such that the latch can engage the proximal end of the coupling body. 22. The connection structure of claim 17 wherein the outer surface of the tapered region of the coupling body of the motor end coupling tapers uniformly from between the proximal and distal ends. 23. The connection structure of claim 17 wherein the outer surface of the tapered region of the coupling body of the motor end coupling is conical between the proximal and distal ends. 24. The connection structure of claim 17 wherein the tapered region of the coupling body of the motor end coupling includes a plurality of axially extending raised ribs radially spaced apart by a plurality of channels, each pair of adjacent ribs of the plurality of ribs being separated by a channel of the plurality of channels. 25. The connection structure of claim 24 wherein each of the ribs of the plurality of ribs of the tapered region of the coupling body are tapered in radial width from a wider first end to a narrower second end, the wider first end being closer to the proximal end of the tapered region of the coupling body and the narrower second end being closer to the distal end of the tapered region. 26. The connection structure of claim 24 wherein each of the channels of the plurality of channels of the tapered region are tapered in radial width from a wider first end to a narrower second end, the wider first end being closer to the proximal end of the tapered region of the coupling body and the narrower second end being closer to the distal end of the tapered region. 27. The connection structure of claim 17 wherein the motor end coupling defines a through bore in communication with the through bore of the outer casing, the drive transmitting shaft extending through the motor end coupling through bore and the driven fitting extending beyond a distal end of the coupling. 28. The connection structure of claim 27 wherein the motor end coupling further includes a support pedestal, the support pedestal extending through the central opening of the coupling body, the support pedestal including a longitudinal passageway defining at least a portion of the motor end coupling through bore, the coupling body being radially and axially constrained with respect to the support pedestal. 29. The connection structure of claim 28 wherein the motor end coupling further includes a sleeve bushing at a distal end of the support pedestal, the sleeve bushing including an enlarged head and an extending shaft, the shaft received in the longitudinal passageway of the support pedestal and the enlarged head defining a bearing surface for rotationally supporting the driven fitting of the drive shaft assembly. 30. The connection structure of claim 29 wherein the extending shaft of the sleeve bushing defines a passageway, the passageway defining at least a portion of the motor end coupling through bore.
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이 특허에 인용된 특허 (24)
Decker Richard B. (Vermilion OH) Bozzi Richard P. (Vermilion OH), Cable driven ring blade knife.
Kulischenko Walter (East Brunswick NJ) Bogan William F. (Somerville NJ) Ellis William C. (Bridgewater NJ), Flexible shaft assembly with universal adapter.
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