The present invention relates in general to robotic devices and, more particularly, to a robotic prosthetic device with an active linking member and compliant linking member.
A prosthetic device helps restore mobility to people who lack able-bodied motion or gait. The prosthetic device is intended to replace the function or appearance of a missing limb and can return mobility to the wearer or user. The prosthetic device is available to replace or support various portions of the body. A lower limb prosthetic device includes, for example, the prosthetic foot, foot-ankle prosthesis, prosthetic knee joint, and prosthetic hip joint. People who require a lower limb prosthesis often expend more metabolic power to walk or move at the same speed as an able-bodied individual. One goal of the lower limb prosthetic device is to help the user achieve a normal gait while reducing energy expended by the user.
Prosthetic devices can be divided into two groups, passive devices and active devices. A passive lower limb prosthetic generally relies on a compliant member, such as a spring, to store and release energy. A spring is able to return no more than the amount of energy that is put into the spring. Thus, the energy that is released by a spring in a passive device is limited to the energy as is put in by the user. For example, a spring-based passive foot prosthetic provides about half of the peak power required for gait. The user of a passive device must expend additional energy through other muscles and joints to maintain a normal walking gait. Therefore, the passive prosthetic design is limited in capacity to help users reduce metabolic energy expenditure while achieving a normal walking gait and performing other activities.
An active device differs from the passive device in that the active device uses a motor to supply power to the device and to control the device. Some active device designs are inefficient, either requiring relatively large motors, which are heavy and undesirable for wearable devices, or providing low peak power output, which is insufficient for many activities. Control systems for the active device are limited in capability to control active devices. The active prosthetic is typically restricted to a single degree of freedom, which reduces the motion available to the device. Further, the active prosthetic may be limited to low power activities, because the power necessary for high power activities is unattainable in a small portable system. One goal of the active prosthetic device is to increase efficiency of the active components and to build a lighter weight device.
Prosthetic devices are typically designed for a specific activity, such as walking. The majority of active compliant devices utilize a traditional rigid structure. The traditional rigid structure typically includes links powered by actuators such as electric motors or hydraulics. One strategy employs an architecture having a joint which is powered by a compliant member, such as a spring, and an active member, such as a motor driven screw, arranged in series. An activity-specific design strategy and traditional rigid structures may be suited for one specific activity, but the designs are limited in application and are not efficient beyond the intended activity. For example, devices designed for walking perform poorly for running, navigating uneven terrain, walking up and down inclines or stairs, or simply balancing while standing. Carrying heavy loads or transitioning from walking to running remains a challenge for users. Some active devices are ineffective for activities requiring both high velocities under low load and low velocities under high load.
A need exists for a prosthetic device that is able to mimic the performance of human muscles over a wide range of activities. Accordingly, in one embodiment, the present invention is a method of making a prosthetic device comprising the steps of providing a foot member including a first joint and a second joint, providing a movable body including a first joint and a second joint, providing a base body coupled to the first joint of the foot member, disposing a compliant linking member between the second joint of the foot member and the first joint of the moveable body, and disposing an actuator between the base body and the second joint of the movable body.
In another embodiment, the present invention is a method of making a prosthetic device comprising the steps of providing a first passive linking member, providing a base body rotationally coupled to the first passive linking member, providing a movable body, disposing a compliant linking member rotationally coupled between the first passive linking member and the moveable body, and disposing an actuating linking member between the base body and the movable body.
In another embodiment, the present invention is a prosthetic device comprising a foot member including a first joint and a second joint. A movable body includes a first joint and a second joint. A base body is coupled to the first joint of the foot member. A compliant linking member is disposed between the second joint of the foot member and the first joint of the moveable body. An actuator is disposed between the base body and the second joint of the movable body.
In another embodiment, the present invention is a prosthetic device comprising a first passive linking member, and base body rotationally coupled to the first passive linking member. A compliant linking member is rotationally coupled between the first passive linking member and a moveable body. An actuating linking member is coupled between the base body and the movable body.
The present invention is described in one or more embodiments in the following description with reference to the figures, in which like numerals represent the same or similar elements. While the invention is described in terms of the best mode for achieving the invention's objectives, it will be appreciated by those skilled in the art that it is intended to cover alternatives, modifications, and equivalents as may be included within the spirit and scope of the invention as defined by the appended claims and their equivalents as supported by the following disclosure and drawings.
A prosthetic device is a wearable robotic device controlled by a control system. The prosthetic devices described herein incorporate active and compliant mechanisms working together in order to behave more like human muscles and thereby improve the performance of the devices.
Moveable body 110 is coupled to base body 102 through actuating linking member 130. In one embodiment, actuating linking member 130 includes an electric motor and lead screw or ball, hydraulic, pneumatic, direct-drive, series-elastic, electroactive polymer-based, chemical-based, or other actuation scheme. One end of actuating linking member 130 is coupled to moveable body 110 at revolute joint 116 and a distal end of the actuating linking member is coupled to base body 102. An optional prismatic joint 132 is coupled between base body 102 and moveable body 110, in parallel with actuating linking member 130, to maintain the motion of the actuating linking member in alignment with an outer housing of ACM 100. In one embodiment, prismatic joint 132 is a slideable linear bearing to reduce loading on actuating linking member 130.
Moveable body 160 is coupled to base body 152 through actuating linking member 180 (130). In one embodiment, actuating linking member 180 includes an actuator 182 implemented as an electric motor and lead screw or ball, hydraulic, pneumatic, direct-drive, series-elastic, electroactive polymer-based, chemical-based, or other actuation scheme. Actuator 182 includes a motor member 182a, shaft 182b, and moveable member 182c. Motor member 182a is coupled to base body 152 and contains a direct current (DC) motor with gear ratio optimized for efficient use of power during actuation. Shaft 182b connects motor member 182a to moveable member 182c. Moveable member 182c is coupled to moveable body 160 at revolute joint 166. In an extended position of actuating linking member 180, shaft 182b operates to separate moveable member 182c from motor member 182a. Shaft 182b can be drawn out of motor member 182a, or the shaft can be drawn out of moveable member 182c, to position the moveable member away from the motor member and lengthen actuating linking member 180. In a shortened position of actuating linking member 180, shaft 182b operates to draw moveable member 182c closer to motor member 182a. Shaft 182b can be drawn into motor member 182a, or the shaft can be drawn through moveable member 182c, to position the moveable member in proximity to the motor member and shorten the length of actuating linking member 180. An optional prismatic joint may be coupled between base body 152 and moveable body 160, in parallel with actuating linking member 180, to maintain the motion of the actuating linking member in alignment with an outer housing 186 of ACM 150. In one embodiment, the prismatic joint is a slideable linear bearing to reduce loading on actuating linking member 180. Portions of ACM 150 are contained within housing 186.
As spring 172 compresses or extends, compliant linking member 170 changes in length. The change in length of compliant linking member 170 produces a force which pushes or pulls on movable body 160 at revolute joint 162, causing movable body 160 to move with respect to base body 152. Similarly, actuator 182 pushes or pulls on movable body 160 at revolute joint 166 by lengthening or shortening the distance between motor member 182a and moveable member 182c along shaft 182b, causing movable body 160 to move with respect to base body 152. Passive linking member 156 is coupled through passive linking member 174 to movable body 160 such that, as movable body 160 moves, passive linking member 156 also moves. Passive linking member 174 maintains a fixed length, rotatable linkage (about revolute joints 164 and 176) between passive linking member 156 and moveable body 160. Passive linking member 156 rotates about revolute joint 158 as actuator 182 and spring 172 act on movable body 160. The rotation or motion of passive linking member 156 is thereby controlled by spring 172 and actuator 182 through movable body 160.
During a typical walking gait cycle, the moment required from a human reaches a maximum value of approximately 1.25 newton meters per kilogram (N-m/kg) of body weight, while the typical velocity reaches a maximum of approximately 450 degrees per second, and the maximum power reaches approximately 6.5 watts per kilogram (W/kg) of body weight. Thus, the output moment, for example, ranges from about 1-1.5 N-m/kg of body weight. The output velocity ranges from about 400-450 degrees per second. The output power ranges from about 6-7 W/kg of body weight. Through the use of ACM 150, approximately the same output moment, velocity, and power required during gait is supplied from an actuator which provides 2.3 W/kg of body mass.
Spring 172 is able to store and release energy. Spring 172 is lengthened by the forward motion of base body 152 and stores potential energy during extension. The stiffness of spring 172 is selected to provide the optimal resistance to the user without undue expenditure of metabolic energy during gait. During the roll-over phase, actuator 182 engages to shorten the distance between motor member 182a and moveable member 182c along shaft 182b. Moveable member 182c moves toward motor member 182a, which pulls up on moveable body 160 and aids in extending spring 172. The input position, velocity, or force of actuator 182 is measured using a sensor. Based on the input measurement, actuator 182 engages to shorten the distance between motor member 182a and moveable member 182c, which causes a change to the internal geometry of ACM 150. Actuator 182 shortens and pulls on movable body 160 at revolute joint 166. Passive linking member 174 rotates about revolute joint 176 and swings upward with movable body 160. The upward motion of movable body 160, as driven by actuator 182, pulls upon compliant linking member 170 at revolute joint 162 and acts to lengthen spring 172. Accordingly, spring 172 is extended by the movement of shank 154 over passive linking member 156, and further by shortening actuator 182. By actuator 182 aiding with extending the length of spring 172, additional energy is stored in the spring over the amount of energy input by the user motion. The potential energy stored in spring 172 is later used during the push-off phase of the gait cycle. With the action of actuator 182, the energy returned to the user by ACM 150 is greater than the energy put in by the user.
The push-off phase of gait requires the maximum amount of power compared to the other phases of gait. For example, an 80 kg human may require up to 350 W of peak power in the ankle during push-off. Spring 172 provides power as the spring relaxes from the extended position. The amount of power provided by spring 172 is directly related to the amount of extension of the spring. Actuator 182 supplies power to extend spring 172 during the roll-over phase of gait shown in
Spring 172 and actuator 182 can each be considered as a prismatic joint. The length of spring 172 is the distance between revolute joint 162 and revolute joint 173. The length of spring 172 is determined by compression or extension of the spring and is related to the force applied to the spring. The length of actuator 182 is controlled by motor member 182a acting on shaft 182b. The length of spring 172 and actuator 182 comprises the input positions for ACM 150. The output force of ACM 150 is a function of the input force and the input position of each linking member.
The input and output positions of ACM 150 are determined by measuring the length of spring 172 and actuator 182 either directly or indirectly. In one embodiment, actuator 182 is a screw-type DC motor and is encoded to count the number of rotations of the motor to calculate the distance between motor member 182a and moveable member 182c. The length of spring 172 is determined by measuring the distance between revolute joints 162 and 173. Alternatively, sensors are disposed on one or more joints or linking members of ACM 150 to measure the input positions of spring 172 and actuator 182. In an implementation of ACM 150, sensors may be disposed on a limb of the user and on the device. The input positions of ACM 150 are denoted by variables (1).
x=[x1,x2]T (1)
where:
Alternatively, ACM 150 includes one or more additional compliant members, linking members, damping members, or passive members coupled to base body 152 and movable body 160. The input positions of additional linking members are denoted by variables (2).
x=[x1,x2,x3 . . . ]T (2)
The output position of ACM 150 is measured using a sensor disposed on revolute joint 158 to measure the rotation or angle of passive linking member 156. Alternatively, the output position may be measured directly or indirectly by sensors disposed on one or more joints or linking members of ACM 150. The output position of passive linking member 156 in ACM 150 is denoted as y. Alternatively, ACM 150 includes one or more additional linking members as outputs. The output positions of an alternative ACM are denoted by variables (3).
y=[y1,y2,y3 . . . ]T (3)
Each output position, yn, of ACM 150 is a function of the input positions, xn as given in equation (4).
y=[y
1(x1,x2, . . . )y2(x1,x2, . . . )y3(x1,x2, . . . ) . . . ]T (4)
The velocity at the output is written as a function of the velocity of the inputs by taking the time derivative of the input and output positions, resulting in a matrix known as the Jacobian denoted by J in equation (5) and equation (6).
{dot over (y)}=J{dot over (x)} (5)
For ACM 150, the number of inputs, represented by n, may be greater than the number of outputs, represented by m. In one embodiment, ACM 150 has one extra degree of freedom at the input. The extra degree of freedom allows the internal geometry of ACM 150 to be controlled and the transmission ratio of actuator 182 to be adjusted. In another embodiment, ACM 150 has additional degrees of freedom to make a biarticular device. For example, ACM 150 moves in the sagittal plane and in the coronal plane such that the device includes two directions of motion, or two degrees of freedom.
The power input into ACM 150 equals the power output and is shown generally by equation (7).
Powerin={dot over (x)}TFx={dot over (y)}TFy=Powerout (7)
where:
Applying equation (7) specifically with respect to ACM 150, the input force, Fx, represents the force along actuator 182 at length or position x1 and the force along spring 172 at length or position x2. The output force, Fy, represents the moment around revolute joint 158, which is the joint about which passive linking member 156 rotates. The power output of ACM 150 is equal to the sum of the power input from spring 172 and actuator 182. The relationship between the input force of ACM 150 and the output force is defined by equation (8). Equation (8) is obtained by substituting equation (5) into equation (7).
Fx=JTFy (8)
The input positions of spring 172, actuator 182, and passive linking member 156 vary with the amount of force put into the device by the user. As the user applies force to ACM 150 during gait, spring 172 changes in length, which changes the ratio of input force to output force. Equation (5) is more dependent on the length of spring 172, i.e., the length of the spring, and is less dependent on the output angle of passive linking member 156. The geometry within ACM 150, such as the position of each of revolute joints with respect to the linking members and base body 152, is selected to optimize the transmission ratio of the device. The stiffness of ACM 150 is thereby is tuned by selecting the internal geometry of the ACM according to the user's needs and desired stiffness of the device.
ACM 150 mimics a human ankle over a range of activities. The anatomy and mechanical properties of the human ankle are such that the elasticity and the load displacement response of the ankle behave like a non-linear spring. ACM 150 has an adjustable or tunable stiffness to allow for high performance over a range of speeds. For example, as more force is applied to spring 172 and actuator 182, the geometry of ACM 150 changes so that less torque and more velocity is required from actuator 182. When output force is high, ACM 150 requires less torque and more velocity. When output torque is low, ACM 150 requires more torque and less velocity.
The efficiency of a DC motor is highly dependent on the motor torque. A lower peak torque requirement results in a lower peak power use by actuator 182. A smaller motor is used for actuator 182, because ACM 150 has a lower peak power requirement. The more efficient energy usage also allows actuator 182, i.e., the motor, to run cooler and allow for longer operation. Overall, the lower peak torque in ACM 150 results in a higher performance prosthesis. Efficiency of a DC motor is less dependent on the angular velocity of the motor, and is much more dependent on motor torque. Further, a DC motor operates at peak efficiency over a relatively narrow window of torque. The lower peak torque requirement from actuator 182 of ACM 150 results in more efficient operation of actuator 182 and results in a higher performance prosthesis. Actuator 182 operates within more favorable torque and velocity zones compared to a direct drive system. Therefore, the DC motor operates closer to peak efficiency. An average efficiency of actuator 182 is approximately 80% within ACM 150, because actuator 182 operates closer to the optimal operating velocity and torque. ACM 150 also provides greater impulse tolerance and increased force fidelity over direct drive systems. Increasing the efficiency of actuator 182 also improves the overall efficiency of ACM 150.
Moveable body 230 is coupled to passive linking member 226 through actuating linking member 250. In one embodiment, actuating linking member 250 includes an electric motor and lead screw or ball, hydraulic, pneumatic, direct-drive, series-elastic, electroactive polymer-based, chemical-based, or other actuation scheme. One end of actuating linking member 250 is coupled to moveable body 230 at revolute joint 236 and a distal end of the actuating linking member is coupled to passive linking member 226 at joint 252. A physical implementation of ACM 220 can be realized similar to
Moveable body 310 is coupled to base body 302 through actuating linking member 330. In one embodiment, actuating linking member 330 includes an electric motor and lead screw or ball, hydraulic, pneumatic, direct-drive, series-elastic, electroactive polymer-based, chemical-based, or other actuation scheme. One end of actuating linking member 330 is coupled to moveable body 310 at revolute joint 316 and a distal end of the actuating linking member is coupled to base body 302 at revolute joint 332.
Moveable body 360 is coupled to base body 352 through actuating linking member 380 (330). In one embodiment, actuating linking member 380 includes an actuator 382 implemented as an electric motor and lead screw or ball, hydraulic, pneumatic, direct-drive, series-elastic, electroactive polymer-based, chemical-based, or other actuation scheme. Actuator 382 includes a motor member 382a, shaft 382b, and moveable member 382c. Motor member 382a is coupled to base body 152 and contains a DC motor with gear ratio optimized for efficient use of power during actuation. Shaft 382b connects motor member 382a to moveable member 382c. Moveable member 382c is coupled to moveable body 360 at revolute joint 366. In an extended position of actuating linking member 380, shaft 382b operates to separate moveable member 382c from motor member 382a. Shaft 382b can be drawn out of motor member 382a, or the shaft can be drawn out of moveable member 382c, to position the moveable member away from the motor member and lengthen actuating linking member 380. In a shortened position of actuating linking member 380, shaft 382b operates to draw moveable member 382c closer to motor member 382a. Shaft 382b can be drawn into motor member 382a, or the shaft can be drawn through moveable member 382c, to position the moveable member in proximity to the motor member and shorten the length of actuating linking member 380. Portions of ACM 350 are contained in housing 386.
As beam 372 flexes about revolute joint 362, compliant linking member 370 produces a force which pushes or pulls on movable body 360 at revolute joint 362, causing movable body 360 to move with respect to base body 352. Similarly, actuator 382 pushes or pulls on movable body 360 at revolute joint 366 by lengthening or shortening the distance between motor member 382a and moveable member 382c along shaft 382b, causing movable body 360 to move with respect to base body 352. Moveable body 360 is coupled through passive linking member 374 to base body 352 such that, as movable body 360 moves, passive linking member 356 also moves. Passive linking member 356 rotates about revolute joint 358 as actuator 382 and beam 372 act on movable body 360. The rotation or motion of passive linking member 356 is thereby controlled by beam 372 and actuator 382 through movable body 360.
Flexible beam 372 is able to store and release energy. The flexing end of beam 372 is flexed downward by the forward motion of base body 352 and stores potential energy. The stiffness of beam 372 is selected to provide the optimal resistance to the user without undue expenditure of metabolic energy during gait. During the roll-over phase, actuator 382 engages to shorten the distance between motor member 382a and moveable member 382c along shaft 382b. Moveable member 382c moves toward motor member 382a, which aids in downward movement of the flexing end of beam 372. The input position, velocity, or force of actuator 382 is measured using a sensor. Based on the input measurement, actuator 382 engages to shorten the distance between motor member 382a and moveable member 382c along shaft 382b, which causes a change to the internal geometry of ACM 350. Actuator 382 shortens and pulls on movable body 360 at revolute joint 366. Passive linking member 374 rotates about revolute joint 376 and swings upward with movable body 360. The upward motion of movable body 360, as driven by actuator 382, pulls on compliant linking member 370 at revolute joint 362 and acts to move the flexing end of beam 372 downward. Accordingly, beam 372 is downward flexed by the movement of shank 354 over passive linking member 356, and further by shortening actuator 382. By actuator 382 aiding with the flexing of beam 372, additional energy is stored in the beam over the amount input by the user motion. The potential energy stored in beam 372 is later used during the push-off phase of the gait cycle. With the action of actuator 382, the energy returned to the user by ACM 350 is greater than the energy put in by the user.
The push-off phase of gait requires the maximum amount of power compared to the other phases of gait. For example, an 80 kg human may require up to 350 W of peak power in the ankle during push-off. Beam 372 provides power as the beam relaxes from the downward flexed position. The amount of power provided by beam 372 is directly related to the amount of flexing of the beam. Actuator 382 supplies power to move the flexing end of beam 372 downward during the roll-over phase of gait shown in
Moveable body 410 is coupled to passive linking member 406 through actuating linking member 430. In one embodiment, actuating linking member 430 includes an electric motor and lead screw or ball, hydraulic, pneumatic, direct-drive, series-elastic, electroactive polymer-based, chemical-based, or other actuation scheme. One end of actuating linking member 430 is coupled to moveable body 410 at revolute joint 416 and a distal end of the actuating linking member is coupled to passive linking member 406 at joint 432. A physical implementation of ACM 400 can be realized similar to
While one or more embodiments of the present invention have been illustrated in detail, the skilled artisan will appreciate that modifications and adaptations to those embodiments may be made without departing from the scope of the present invention as set forth in the following claims.
The present application is a continuation-in-part of U.S. patent application Ser. No. 14/081,857, filed Nov. 15, 2013, which is a continuation-in-part of U.S. patent application Ser. No. 13/673,177, filed Nov. 9, 2012, which claims the benefit of U.S. Provisional Application No. 61/558,761, filed Nov. 11, 2011, which applications are incorporated herein by reference.
Number | Date | Country | |
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61558761 | Nov 2011 | US |
Number | Date | Country | |
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Parent | 14081857 | Nov 2013 | US |
Child | 15146826 | US | |
Parent | 13673177 | Nov 2012 | US |
Child | 14081857 | US |