MECHANICAL FINGER

The invention relates to a mechanical finger comprising, a knuckle, a proximal element, a rod, a motor, a motor driven screw and a distal element. The knuckle has a first and second pivot. The proximal element knuckle end is coupled to the first pivot. The proximal element also has a third pivot at a variable longitudinal distance from the first pivot. The rod has a near end pivotally coupled to the second pivot and a far end pivotally coupled to the third pivot. A motor is coupled to and referenced to the proximal element. A screw is driven to change the distance between the third pivot and the first pivot in response to a command from a controller to the motor. A distal element is pivotally coupled to the proximal element. The distal element rotates with respect to the proximal element in response to a change in the variable distance between the third pivot and the first pivot.

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Description

This invention claims priority from provisional patent application Ser. 61/780,622 filed 13 Mar. 2013 for a Prosthetic Finger Design having a common sole inventor.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

This invention was not developed with Government funded effort.

FIELD OF THE INVENTION

This invention relates to the field of prosthetic appliances made for and used by human amputees and more particularly to those amputees that have lost one or more fingers on a hand.

BACKGROUND OF THE INVENTION

U.S. Pat. No. 8,100,986 issued on Jan. 24, 2012 to inventor Gregor Puchhammer of Vienna (AT) shows a mechanical prosthetic finger with a proximal member, a medial member and a distal member all mounted pivotally on one another. A moveable balance arm is connected via leavers to the proximal member and to the distal member. However the Puchhammer ‘986’ reference does not show the simpler arrangement of a screw nut assembly in a proximal element cavity having a left and right pivot boss extending through the left and right slots in the proximal element cavity. The left and right pivot boss are each sized to provide free longitudinal movement within its respective left guide and right slots so as to prevent the screw nut assembly from rotating in the proximal element cavity as the screw nut assembly is moved longitudinally in the proximal element cavity by a an axial screw drive.

U.S. Pat. No. 5,888,246 issued Mar. 30, 1999 to inventor David J. Gow of Edinburgh (GB) from application Ser. No. 08/702,605 filed Mar. 10, 1995. The ‘246’ patent is related art but it fails to show a screw nut assembly in a proximal element cavity having a left guide and pivot boss extending through the left slot and a right guide and pivot boss extending through the right slot of the proximal element cavity. The left and right pivot boss are each sized to provide free longitudinal movement of the left and right boss toward the distal element or toward the knuckle end of the proximal element within its respective left guide or right guide while preventing the screw nut assembly from rotating in the proximal element cavity as the screw nut assembly is moved longitudinally in the proximal element cavity by a direct longitudinal screw drive.

Mechanical fingers for artificial hands require various features to best perform the functions for an upper limb prosthetic user. The required features and functions include a high strength force generator, a light weight, good reliability, adequate speed, and a size that permits a cover that provides a natural appearance. These features are made difficult to include by the small space available inside an individual finger.

Another feature that is difficult to achieve in the design of a prosthetic mechanical finger is the short section where the prosthetic finger attaches to the residual end of the finger on the patient. Previous embodiments have placed the force generators or a part of the drive mechanism inside the build height which extends the length of the prosthetic to a position that is outside of the natural envelope of a finger. A longer than natural build height tends to result in fewer patients being fitted with a prosthetic finger. The shorter build height made possible by the invention is expected to improve the market acceptance of the prosthetic with expanded sales including sales to female s and teenagers.

Another feature made possible by the invention prosthetic is a reduced cost flowing from its reduced complexity. Earlier embodiments have higher part counts with parts of significant complexity that contributed to a higher price for the prosthetic.

SUMMARY OF THE INVENTION

It is an object of the present invention to solve or reduce many of the problems stated above. The mechanical finger as taught by this disclosure, in a first embodiment that comprises the following components as referenced in FIGS. 1a-1c: a knuckle (12), a proximal element (24), a rod (18), a screw nut boss (22), a force generator (26) with an axial drive shaft driving a screw that is axially coupled to the screw nut assembly, and a frame (10) means for coupling the knuckle (12) to the stump or residual limb of the patient. The knuckle (12) is coupled to the frame (10) and has a first (14) and second pivot (16) separated by a first predetermined distance. The proximal element has a knuckle end and a distal end. The knuckle end of the proximal element is coupled to the knuckle first pivot (14). The proximal element provides a third pivot (21). The third pivot is located on the proximal element (24) at a variable longitudinal distance from the first pivot (14).

It should be understood that the each of the three pivots characterized herein, and later a fourth pivot, are characterized in the structure of the invention mechanical finger by a corresponding left and right counterpart, each left and right counterpart being axially aligned, the axis of each pivot being normal to a plane that contains the longitudinal axis of the axial screw drive to the screw nut assembly.

The rod (18) having a near end pivotally coupled to the knuckle second pivot (16) and a far end of the rod (18) is pivotally coupled to the third pivot (21). A screw (74) drives the screw nut boss (22). The force generator (26) is coupled to or reference to the proximal element (24), and more particularly to the near end or knuckle end of the proximal element cavity. The screw (74) is coupled to the third pivot (21) to change the variable longitudinal distance between the third pivot (21) and the first pivot (14) in response to a command from a controller to the force generator (26).

A distal element (38) is pivotally coupled to the proximal element at a fourth pivot (36). The distal element (38) rotates with respect to the proximal element (24) in response to a change in the variable distance between the third pivot (21) and the first pivot (14). The distal element (38) further has at least a first phalange pivotally coupled to the fourth pivot (36) on the proximal element (24). Each phalange has a distal element follower aperture (47) characterized to receive a screw nut boss (22) through a proximal element slot (42) then passing through the distal element follower aperture (47).

Movement of the screw nut boss (22) toward the knuckle (12) results in a counter clockwise torque applied to the distal element (38) around the fourth pivot (36) as the screw nut boss (22) engages the wall of the distal element follower aperture (47). Movement of the screw nut boss (22) toward the distal end of the proximal element (24) results in a clockwise torque applied to the distal element (38) around the fourth pivot (36) as the screw nut boss (22) engages the wall of the distal element follower aperture (47). In another alternative embodiment, the mechanical finger comprises a frame coupled to the knuckle and formed to receive and be attached to the residual limb of a patient. The mechanical finger also has an elastic or spring element (46) extending in tension from the distal element (38) to the proximal element (24) to add to the grip force of the finger as it closes and to help to maintain a limited closed grip on the object grasped as the power to the force generator is interrupted.

The screw nut assembly within the proximal element cavity has a left guide and pivot boss extending through a left slot and a right guide and pivot boss extending through a right slot, each guide and pivot boss extending through its respective slot. As explained above, the force generator or motor rotates the screw that is engaged with the screw nut assembly. The screw nut assembly carries the left and right pivot boss in its slot, each pivot boss being sized to provide free longitudinal movement within its respective left guide and right guide to prevent the screw nut assembly from rotating in the proximal element cavity. The rotation of the screw is transferred into a linear movement of the third pivot as the screw nut assembly is moved longitudinally through the proximal element cavity.

BRIEF DESCRIPTION OF THE DRAWINGS

An example of a mechanical finger embodying the present invention will now be described in greater detail with reference to the accompanying drawings, in which;

FIG. 1a shows a schematic stick drawing of the mechanical finger in the fully open position

FIG. 1b shows a schematic stick drawing of the mechanical finger in a partially flexed position

FIG. 1c shows a schematic stick drawing of the mechanical finger in a fully flexed position

FIG. 2a is a perspective view of the mechanical finger shown in the fully open position

FIG. 2b is a perspective view of the mechanical finger shown in a partially flexed position

FIG. 2c is a perspective view of the mechanical finger shown in fully flexed position

FIG. 3a shows a partial sectional perspective view of the mechanical finger in the fully open position, showing the drive mechanism

FIG. 3b shows a partial sectional perspective view of the mechanical finger in the partially closed position, showing the drive mechanism

FIG. 3c shows a partial sectional showing the drive mechanism in a perspective view of the mechanical finger in the fully closed position,

FIG. 4a is a perspective view of the mechanical finger,

FIG. 4b is a perspective exploded view of FIG. 4a,

FIG. 5a shows a plan view of the mechanical finger with a section line A-A

FIG. 5b shows the section view A-A

FIG. 6a is a perspective view of the distal element

FIG. 6b shows an exploded view FIG. 6a

FIG. 7a is a perspective view of the force generator and the drive mechanism,

FIG. 7b shows an exploded view of FIG. 7a

FIG. 8a is a perspective view of the proximal element,

FIG. 8b shows an exploded view of FIG. 8a

FIG. 9a is a perspective view of the knuckle to frame mount and frame mount assembly,

FIG. 9b shows an exploded view of FIG. 9a

FIG. 10a shows a side view of the rod

FIG. 10b shows a plan view of the rod

FIG. 10c shows an exploded view of the rod with bearings

FIG. 10d shows the rod with bearings fitted

FIG. 11a shows a side view of the screw nut

FIG. 11b shows a front view of the screw nut

FIG. 11c shows a perspective view of the screw nut with ×2 washers

FIG. 11d shows a perspective view of the screw nut with ×2 washers

FIG. 11e shows a perspective view of the screw nut with ×4 washers fitted

FIG. 11f shows a perspective view of the screw nut with ×4 washers fitted

FIG. 12a shows the sprung element side view

FIG. 12b shows the sprung element in perspective

FIG. 13a is a perspective and partial view of the proximal element and screw nut in the fully open position

FIG. 13b is a perspective and partial view of the proximal element and screw nut in the partially closed position

FIG. 13c is a perspective and partial view of the proximal element and screw nut in the fully closed position

FIG. 14a is a perspective and partial view of the proximal element, screw nut and distal element in the fully open position

FIG. 14b is a perspective and partial view of the proximal element, screw nut and distal element in the partially closed position

FIG. 14c is a perspective and partial view of the proximal element, screw nut and distal element in the fully closed position

FIG. 15a is a perspective and partial view of the proximal element, rod and distal element in the fully open position

FIG. 15b is a perspective and partial view of the proximal element, rod and distal element in the partially closed position

FIG. 15c is a perspective and partial view of the proximal element, rod and distal element in the fully closed position

FIG. 16a shows a partial view of the proximal element, rod and distal element in the fully open position, the distal element having an alternative slot design

FIG. 16b shows a partial view of the proximal element, rod and distal element in the fully open position, the distal element having an alternative slot design and the distal element being pushed closed

DESCRIPTION OF THE INVENTION

The invention Mechanical Finger will now be discussed with reference to FIG. 1 through FIG. 16b with FIG. 1a being a simplified stick drawing showing frame 10 which attaches to the amputee residual limb, and the knuckle 12 attached to the frame 10. The knuckle 12 has a proximal element to knuckle pivot 14 and a rod to knuckle pivot 16. The knuckle end of the rod 18 is attached to the knuckle 12 at the rod to knuckle pivot 16. The distal end of the rod 18 is attached to the rod to screw nut boss 22. The proximal element 24 contains the force generator 26 that is connected to and can push and pull the screw nut boss 22 in a longitudinal direction. The force generator 26 is powered by the battery 28, and controlled by the control sensor 32 and the processor 34. The proximal element 24 has a proximal element to distal element pivot 36 which connects the proximal element 24 to the distal element 38. The proximal element 24 has a proximal element slot 42 that guides the screw nut boss 22 in a longitudinal direction. The distal element 38 has a distal element follower aperture 47 which contains the screw nut boss 22. As the force generator actuates the screw nut boss 22, the distal element follower aperture 47 accommodates the linear movement of the screw nut boss 22 as it travels through the arc from the proximal element to distal element pivot 36 and pulls the distal element 38 closed. The elastic or spring element 46 is connected to the distal element 38 and the proximal element 24 to maintain force when the power is interrupted.

FIG. 1b being a simplified stick drawing showing the force generator 26 as it has pulled the screw nut boss 22 towards the knuckle 12 to a part closed position of the mechanical finger. The screw nut boss 22 travels through the proximal element slot 42, as it does the distance between the screw nut boss 22 and the proximal element to knuckle pivot 14 gets shorter, because the screw nut boss 22 and the rod to knuckle pivot 16 are always the same distance apart due to the length of the rod 18, the proximal element to knuckle pivot 14 is actuated towards a closed position. The screw nut boss 22 is connected to the distal element follower aperture 47. As the screw nut boss 22 is pulled towards the knuckle 12 the distal element follower aperture 47 is rotated around the proximal element to distal element pivot 36.

FIG. 1c is another schematic simplified stick drawing showing the force generator 26 as it has pulled the screw nut boss 22 towards the knuckle 12 to a fully closed position of the finger.

FIG. 2a is a perspective view of the mechanical finger assembly shown if greater detail than FIG. 1 in the fully open position. The frame 10 is connected to the knuckle to frame mount 48 which connects the left knuckle 52 and the right knuckle 54 to the frame 10. The left knuckle 52 contains the left knuckle to left rod pivot 56 and the left proximal element to knuckle pivot 58. The left rod 68 is shown coupled to and extending from the left rod to screw nut boss pivot 114 to the left knuckle to left rod pivot 56. The left proximal element 64 is connected to the left knuckle 52 at left proximal element to knuckle pivot 58. The left proximal element 64 is connected to the left distal element 66 at the left proximal element to distal element pivot 94. The elastic or spring element 46 is connected in tension to the left distal element 66 and the left proximal element 64.

FIG. 2b is a perspective view of the mechanical finger assembly shown in the partially closed position

FIG. 2c is a perspective view of the mechanical finger assembly shown in the fully closed position.

FIG. 3a shows a partial sectional view of the mechanical finger. The left proximal element 64, the left distal element 66 and the left rod 68 have been removed for clarity. Inside the left proximal element 64 and the right proximal element 72 is the force generator 26 which is connected to the screw 74. When the force generator 26 receives a drive command it rotates to move the screw 74 in a clockwise or counter clockwise direction. The screw nut 76 is threaded onto the screw 74. The screw nut 76 has a left screw nut boss 62 which extends through the left proximal element slot 78 (not shown). Although the left proximal element slot 78 is not shown on FIG. 3a, 3b or 3c, that feature can be seen on FIGS. 13a, 13b and 13c. The right screw nut boss 82 (not shown) extends though the right proximal element slot 84 (not shown). As the left and right pivot bosses extend through the respective left and right proximal element slots, they serve to prevent the screw nut 76 from rotating inside the proximal element cavity in response to rotation of the screw 74 as the prosthesis is commanded to operate. Rotation of screw 74 in the screw nut 76 exerts a torsional force on the screw nut 76. By preventing the screw nut 76 from rotating, the torque applied to the screw nut 76 is converted and combined with the inclined plane of the screw thread to provide an axial linear force to the screw nut boss pivot 21 (shown in FIGS. 1a-c) via the left and right boss as they extend through the left proximal element slot 78 (not show) and right proximal element slot 84 (not shown).

FIG. 3b shows a partial view of the mechanical finger in the partially closed position with the screw nut 76 being at its middle position on the length of the screw 74. FIG. 3c shows a partial sectional view of the mechanical finger in the fully closed position with the screw nut 76 moved to a limit on screw 74 toward the motor or force generator 26.

FIG. 4a is a perspective view from above, of the mechanical finger. FIG. 4b is an exploded view of FIG. 4a. A sensor 86 is positioned in the proximal element cavity between the rear or knuckle end of the motor and the knuckle to frame mount 48. The sensor 86 measures the longitudinal position or distance that the screw nut 76 is at or has traveled along the length of the screw 74 driven by the force generator 26. The force generator 26 is connected to and rotates the screw 74.

As stated earlier, the screw 74 is threaded into the screw nut 76. The screw nut 76 has a left screw nut boss 62 and a right screw nut boss 82. These elements constitute the drive mechanism. The drive mechanism is contained inside the proximal element cavity formed by the left proximal element 64 and the right proximal element 72. In operation, as the force generator 26 receives a command or drive signal, the screw 74 turns, the screw nut 76 is prevented from turning by the left proximal element slot 78 and the right proximal element slot 84 shown on FIGS. 8a and 8b. The slots 78 and 84 allow a linear movement of the screw nut 76 along the threaded length of the screw 74.

With continuing reference to the exploded view of FIG. 4b, the left knuckle 52 is connected to the left proximal element 64 at the left proximal element to knuckle pivot 58. The right knuckle 54 is connected to the right proximal element 72 at the right knuckle to proximal element pivot 88 (not shown). The left knuckle 52 is connected to the right knuckle 54. The knuckle to frame mount 48 is connected to the left knuckle 52 and right knuckle 54. The knuckle to frame mount 48 is connected to the frame 10.

The left distal element 66 is connected to the right distal element 92. The left distal element 66 and right distal element 92 are pivoted on the proximal element at the right proximal element to distal element pivot 96 (not shown) which is formed by the left distal element to proximal element pivot boss 126 capturing the left distal element to proximal element pivot aperture 132 (not shown), and the left proximal element to distal element pivot 94 (not shown) which is formed by the right distal element to proximal element pivot boss 128 capturing the right distal element to proximal element pivot aperture 134 (not shown). The left proximal element to distal element pivot 94 and the right proximal element to distal element pivot 96 facilitate the rotational movement of the distal elements 66, 92 relative to the proximal elements 64, 72.

The left rod 68 has rod boss 138 that captures the left knuckle rod aperture 146 to form the left knuckle to left rod pivot 56. The right rod 98 has rod boss 139 that captures the right knuckle rod aperture 148 to form the right knuckle to rod pivot 102.

The left rod 68 has a rod aperture 136 that is received by the left screw nut boss 62. The right rod 98 has a rod aperture 137 that receives the right screw nut boss 82.

FIG. 5a shows a plan view of the mechanical finger with a section line A-A and FIG. 5b shows the sectional view of FIG. 5a taken on section line A-A. The frame 10 is shown connected to the knuckle to frame mount 48 which is shown connected to the right knuckle 54. The sensor 86 is depicted inside and to the rear of the force generator 26. The microprocessor 104 is shown on top of the force generator 26. The bearing for screw knuckle end 106 and the screw 74 is attached to the left end of the force generator 26. The screw 74 is threaded through the screw nut 76. A bearing for screw distal end 108 is shown that holds the distal end of the screw 74. An elastic or spring element 46 is shown that is joined to the left proximal element 64 (not shown) and right proximal element 72, and to the left distal element 66 (not shown) and right distal element 92. The bearings for screw knuckle end 106 and the bearing for screw distal end 108 protect the screw 74 and the force generator 26 from radial and linear loading.

FIG. 6a shows the left distal element 66 and the right distal element 92 with the assembly screws 112 holding the two in contact with each other to form the distal element 38. The left distal element 66 has a left distal element flange 122. The left distal element flange 122 has a left distal element to proximal element pivot aperture 132 and a left distal element aperture 116. The right distal element 92 has a right distal element flange 124. The right distal element flange 124 has a right distal element to proximal element pivot aperture 134 and a right distal element aperture 118. FIG. 6b shows an exploded view of FIG. 6a. It may be possible to reverse the position and function of the left distal element aperture 116 and the right distal element aperture 118 with the left distal element to proximal element pivot aperture 132 and the right distal element to proximal element pivot aperture 134.

FIG. 7a shows the force generator 26 and drive mechanism assembly. The sensor 86 is connected to the force generator 26. The force generator 26 is connected to and drives the screw 74. The screw nut 76 is threaded onto the screw 74. The bearing for screw knuckle end 106 and the bearing for screw distal end 108 are designed to protect the force generator 26 from axial (thrust) and radial loading. FIG. 7b is an exploded perspective view of FIG. 7a

FIG. 8a is a perspective view of the assembled proximal formed from a left proximal element 64 and a right proximal element 72. FIG. 8b also shows the assembly screws 112 used to couple the left and right sides to form the proximal element 24.

The left distal element to proximal element pivot boss 126 is shown above the left proximal element slot 78. The right distal element to proximal element pivot boss 128 is shown above the right proximal element slot 84. The left distal element to proximal element pivot boss 126 and right distal element to proximal element pivot boss 128 each respectively extend through the respective left and right distal element into proximal element pivot apertures 132, 134 on the respective left and right flanges 122, 124 of the distal element.

The left distal element to proximal element pivot boss 126 with the left distal element to proximal element pivot apertures 132 (shown on FIG. 6.b), and the right distal element to proximal element pivot boss 128 with the right distal element to proximal element pivot apertures 134 (shown on FIG. 6.b), in combination form the proximal element to distal element pivot 36 (shown on FIG. 1.a). The left proximal element 64 has a left proximal element to knuckle boss 156 that is received by a left proximal element to knuckle aperture 152 shown on FIGS. 9a and 9b. The right proximal element 72 has a right proximal element to knuckle boss 158 (not shown) that is received by a right proximal element to knuckle aperture 154 also shown on FIGS. 9a and 9b. The combination of left proximal element to knuckle boss 156 into the left proximal element to knuckle aperture 152 and the right proximal element to knuckle boss 158 into the right proximal element to knuckle aperture 154 form the proximal element to knuckle pivot 14. FIG. 8b shows an exploded view of FIG. 8a.

FIG. 9a is a perspective view of the knuckle 12 formed from a left knuckle 52 and a right knuckle 54 pair of components. The knuckle to frame mount 48 and the frame 10 are also shown. The left knuckle 52 is joined to the right knuckle 54 with two assembly screws 112. The knuckle to frame mount 48 is attached to the left knuckle 52 and right knuckle 54 with screws 112. The frame 10 is attached to the knuckle to frame mount 48 with screws 112. The left knuckle 52 has a left proximal element to knuckle aperture 152. The right knuckle 54 has a right proximal element to knuckle aperture 154 as discussed in connection with the above discussion of FIG. 8a and FIG. 8b.

FIG. 9b shows an exploded view of 9a.

FIGS. 10a-10d shows the left rod 68. The left rod 68 is the same as the right rod 98 (not shown). The left rod 68 contains a rod aperture 136 that fits onto left screw nut boss 62 (not shown) to form left rod to screw nut boss pivot 114. The right rod 98 (not shown) contains a right rod aperture 137 that fits onto right screw nut boss 82 to form right rod to screw nut boss pivot 120. The combination of the left rod 68 which contains the left rod aperture 136 with the left screw nut boss 62 and the right rod aperture 137 with the right screw nut boss 82 form the screw nut boss pivot 21 located on the screw nut boss 22.

The left rod 68 also contains the rod boss 138. The rod boss 138 connects the left rod 68 to the left knuckle to left rod pivot 56. To increase efficiency the left rod 68 has a rod aperture bearing 142 inserted into the rod aperture 136, and rod boss bearing 144 inserted onto the rod boss 138. The right rod 98 mirrors the described arrangement of the left rod 68.

The stiffness of the rod contributes to the ability of the mechanical finger to deliver a grip that could exceed design limits. It may be possible to design the rods so as to experience distortion when a design limit is exceeded so as to preclude damage to the structure elements. One possible design embodiment for this purpose could be to design the rods to have a corrugated or curved feature fabricated into the surface of the rod, or to design the rod to have a spring characteristic. The combination of the left rod boss 138 with the left knuckle rod aperture 146 along with the combination of an identical right rod boss 139 (not shown) with the right knuckle rod aperture 148 form the rod to knuckle pivot 16 shown in FIGS. 1a-1c.

FIG. 11a is a side view of the screw nut 76. FIG. 11b is a front view of the screw nut 76. FIG. 11c is an exploded view of the screw nut 76 showing the left screw nut boss 62 and the right screw nut boss 82 with sleeve bearings ready for installation on the bosses and aligned on each of the bosses.

FIG. 11d is a perspective view of the screw nut 76, with sleeve bearings on the left and right screw nut boss. The left screw nut boss 62 and the right screw nut boss 82, each with sleeve bearings installed are received by the respective proximal element slots 78, 84 (not shown), and the outer surface of the bearings are sized to ride in the proximal element slots.

FIG. 11e is an exploded view of the screw nut 76 with the left screw nut boss 62 and the right screw nut boss 82, each being ready to receive a bushing that is stopped by the edge of an earlier sleeve bearing.

FIG. 11f is a perspective view showing the screw nut assembly ready for assembly, the bushing on each of the bosses 62, 82 receiving the respective distal element aperture for screw nut boss left and right side 116, 118 (not shown). The sleeves and bearings are added to space the distal element aperture for screw nut boss left and right side from the respective outer surface of the proximal element 24 and add an increase in efficiency between the left screw nut boss 62 and the right screw nut boss 82 and the distal element aperture left and right side 116, 118.

FIG. 12a is a side view of a single elastic or spring element 46, and FIG. 12b is a perspective view of a pair of elastic or spring elements 46.

FIG. 13a is a partial perspective view of the distal end of the left proximal element 64, the right proximal element 72 being partially unseen behind the left side. The left and right sides are assembled together with the screw 74 appearing in FIG. 13c. As shown in FIG. 13a, as the mechanical finger is fully opened, the left screw nut boss 62 is at the distal end of the left proximal element slot 78.

FIG. 13b is a partial perspective view of the left proximal element 64 and the right proximal element 72 behind the surface, the two being assembled together with the screw 74 and screw nut 76 in the half way closed position.

FIG. 13c a partial perspective view of the left proximal element 64 and the right proximal element 72 assembled together with the screw 74 and screw nut 76 of the mechanical finger being in the fully closed position.

FIG. 14a shows a partial view of the proximal element to distal element joint with the finger in a fully opened configuration. The left screw nut boss 62 is in the lower part of the left distal element aperture 116 to the left of the left proximal element to distal element pivot 94.

FIG. 14b shows that the left screw nut boss 62 has moved approximately half way through its actuation travel. The left distal element 66 is pulled by the left screw nut boss 62 in a counter clockwise rotation towards the knuckle 12. As the left screw nut boss 62 moves from the position shown in FIG. 14a, to FIG. 14b and then to FIG. 14c within the left proximal element slot 78 (not shown), the left screw nut boss 62 applies a force to the edge of the left distal element aperture 116 that results in a torque applied to the left distal element 66 forcing it to pivot and rotate in a counter clockwise rotation around the left proximal element to distal element pivot 94. The left screw nut boss 62 touches the inner surface or perimeter of the left distal element aperture 116 with a sliding or rolling surface on a fixed slot surface only traversing an arc path along the inner surface of the left distal element aperture 116. The arc movement of the left screw nut boss 62 is accommodated by the left distal element aperture 116 as the left screw nut boss 62 travels upwards in the left distal element aperture 116 towards the left proximal element to distal element pivot 94. In FIG. 14c the finger is fully closed; the left screw nut boss 62 can be seen sitting in the lower part of the left distal element aperture 116 away from the left proximal element to distal element pivot 94.

It will be understood that the right distal element 92 has the same relationship and movement with the right screw nut boss 82 (not shown) as the left distal element 66 has with the left screw nut boss 62. FIG. 14a-14c also shows the elastic or spring element 46 which is attached and connects the left proximal element 64 and the right proximal element 72 to the left distal element 66 and the right distal element 92. The elastic or spring element 46 is in tension, so when the power is interrupted or paused, the elastic or spring element 46 together with the resistance in the force generator 26 and the drive mechanism operate to resist and prevent the mechanical finger from opening. If the mechanical finger is holding an item at the time of the interruption, the item held will remain secured in the grip of the mechanical finger, or fingers as the case may be.

FIGS. 15a-15c are distinguished from FIGS. 14a-14c by showing the addition of left rod 68 in the FIGS. 15a-15c series. FIG. 15a shows a partial view of the left proximal element 64 and the right proximal element 72 receding into the image. The left proximal element 64 is assembled together with the left rod 68. The left rod 68 is connected to the left screw nut boss 62 (not shown) at the left rod to screw nut boss pivot 114. FIG. 15a shows the mechanical finger in a fully open position. 15b shows the mechanical finger in a partially closed position and FIG. 15c shows the mechanical finger in a fully closed position.

FIG. 16a shows the proximal element to distal element pivot with the distal element having an alternative embodiment—the distal element has a more elongated left distal element aperture 116 and right distal element aperture 118 (not shown). The left screw nut boss 62 and the right screw nut boss 82 (not shown) sit inside a more elongated left distal element aperture 116 and the right distal element aperture 118 (not shown). FIG. 16b shows the left distal element 66 and the right distal element 92 (not shown) receiving an unexpected load and being pushed downwards by the force. Since the left distal element aperture 116 and right distal element aperture 118 (not shown) are more elongated the left distal element 66 and the right distal element 92 (not shown) are able to be pushed downwards, this can be used as a feature to protective the mechanical finger from accidental external shock.

While certain specific relationships, materials and other parameters have been detailed in the above description of a preferred embodiment, those can be varied, where suitable, with similar results. Other applications and variations of the present invention will occur to those skilled in the art upon reading the present disclosure. Those variations are also intended to be included within the scope of this invention as defined in the appended claims.

APPENDIX List of Parts

  • 10—Frame
  • 12—Knuckle
  • 14—First pivot—Proximal element to knuckle pivot
  • 16—Second pivot—Rod to knuckle pivot
  • 18—Rod
  • 21—Third pivot—Screw nut boss pivot
  • 22—Screw nut boss
  • 24—Proximal element
  • 26—Force generator
  • 28—Battery
  • 32—Control sensor
  • 34—Processor
  • 36—Fourth pivot—Proximal element to distal element pivot
  • 38—Distal element
  • 42—Proximal element slot
  • 44—Distal element pivot aperture
  • 45—Distal element follower
  • 46—Elastic or spring element
  • 47—Distal element follower aperture
  • 48—Knuckle to frame mount
  • 52—Left knuckle
  • 54—Right knuckle
  • 56—Left knuckle to left rod pivot
  • 58—Left proximal element to knuckle pivot
  • 62—Left screw nut boss
  • 64—Left proximal element
  • 66—Left distal element
  • 68—Left rod
  • 72—Right proximal element
  • 74—Screw
  • 76—Screw nut
  • 78—Left proximal element slot
  • 82—Right screw nut boss
  • 84—Right proximal element slot
  • 86—Sensor
  • 88—Right knuckle to proximal element pivot
  • 92—Right distal element
  • 94—Left proximal element to distal element pivot
  • 96—Right proximal element to distal element pivot
  • 98—Right rod
  • 102—Right knuckle to rod pivot
  • 104—Microprocessor
  • 106—Bearing for screw knuckle end
  • 108—Bearing for screw distal end
  • 112—Assembly screws
  • 114—Left rod to screw nut boss pivot
  • 116—Left distal element aperture
  • 118—Right distal element aperture
  • 120—Right rod to screw nut boss pivot
  • 122—Left distal element flange
  • 124—Right distal element flange
  • 126—Left distal element to proximal element pivot boss
  • 128—Right distal element to proximal element pivot boss
  • 132—Left distal element to proximal element pivot aperture
  • 134—Right distal element to proximal element pivot aperture
  • 136—Left rod aperture
  • 137—Right rod aperture
  • 138—Left rod boss
  • 139—Right rod boss
  • 142—Rod aperture bearing
  • 144—Rod boss bearing
  • 146—Left knuckle rod aperture
  • 148—Right knuckle rod aperture
  • 152—Left proximal element to knuckle aperture
  • 154—Right proximal element to knuckle aperture
  • 156—Left proximal element to knuckle boss
  • 158—Right proximal element to knuckle boss

Claims

1. A mechanical finger comprising:

a knuckle,
a proximal element,
a rod, the knuckle having
a first pivot and
a second pivot separated by
a first predetermined distance, the proximal element having a knuckle end pivotally coupled to the knuckle first pivot and
a third pivot at a variable longitudinal distance from the first pivot, the rod having a knuckle end pivotally coupled to the knuckle second pivot and a distal element end pivotally coupled to the third pivot,
a force generator driving a screw, the force generator being coupled to the proximal element, the screw being coupled to the third pivot to change the variable longitudinal distance between the first pivot and the third pivot in response to a command from a control sensor to the force generator,
a distal element, the distal element being pivotally coupled to the proximal element at a fourth pivot, the distal element rotating with respect to the proximal element and the fourth pivot in response to a change in the variable distance between the third pivot and the first pivot.

2. The mechanical finger of claim 1 wherein the distal element further comprises:

a first flange, the first flange having;
a distal element pivot aperture and,
a distal element follower aperture, wherein
the distal element follower aperture captures and follows the third pivot.

3. The mechanical finger of claim 2 wherein the distal element follower aperture further comprises:

an elongated hole in the first flange, wherein the elongated hole captures and follows the third pivot without binding.

4. The mechanical finger of claim 2 wherein the distal element pivot aperture further comprises:

a cylindrical hole in the first flange which captures
a proximal element to distal element pivot boss on the distal element end of the proximal element.

5. The mechanical finger of claim 1 further comprising:

a frame, the frame being formed to receive and be attached to the residual limb of a patient,
the knuckle being coupled to the frame.

6. The mechanical finger of claim 1 further comprising:

an elastic or spring element extending in tension from the distal element (38) to the proximal element to add to the grip force and help maintain a closed grip as the power to the force generator is interrupted.

7. The mechanical finger of claim 1 wherein the proximal element further comprises:

a proximal element cavity accommodating
a screw nut threaded to receive the screw the force generator being coupled to drive the screw in response to a control signal
a sensor coupled to the force generator for measuring the variable longitudinal distance between the first pivot and the third pivot.

8.-28. (canceled)

Patent History
Publication number: 20170014245
Type: Application
Filed: Mar 13, 2014
Publication Date: Jan 19, 2017
Patent Grant number: 9913737
Inventor: Mark Hunter (Marina del Rey, CA)
Application Number: 14/207,635
Classifications
International Classification: A61F 2/58 (20060101);