In lower-limb rehabilitation, there is a specific group of patients that can perform voluntary muscle contraction and visible limb movement provided that the weight of his/her leg is fully supported by a physical therapist. In addition, this therapist is necessary in guiding the patient to switch between hip-only and knee-only motions for training specific muscles effectively. These clinic needs have motivated us to devise a novel reconfigurable gravity-balanced mechanism for tackling with the clinical demands without the help from therapists. The proposed mechanism has two working configurations, each leading the patient to do either hip-only or knee-only exercise. Based on the principle of static balancing, two tensile springs are attached to the mechanism to eliminate the gravitational effect of the mechanism and its payload (i.e., the weight of the patient's leg) in both configurations. The gravity balancing design is verified by a numerical example and adams software simulation. A mechanical prototype of the design was built up and was tested on a healthy subject. By using electromyography (EMG), the myoelectric signals of two major muscles for the subject with/without wearing the device were measured and analyzed. The results show that the myoelectric voltages of the stimulated muscles in both hip-only and knee-only motion modes are reduced when the subject is wearing the device. In summary, the paper for the first time demonstrates the design philosophy and applications by integrating the reconfigurability and static balancing into mechanisms.
Issue Section:
Research Papers
Keywords:
Mechanism design
Topics:
Gravity (Force),
Knee,
Potential energy,
Springs,
Design,
Muscle,
Electromyography,
Simulation
References
1.
O'Sullivan
, S. B.
, and Schmitz
, T. J.
, 2007
, Physical Rehabilitation
, 5th ed., F. A. Davis Company
, Philadelphia, PA
.2.
Kim
, C. M.
, Eng
, J. J.
, and Whittaker
, M. W.
, 2004
, “Level Walking and Ambulatory Capacity in Persons With Incomplete Spinal Cord Injury: Relationship With Muscle Strength
,” Spinal Cord
, 42
(3
), pp. 156
–162
.3.
Helen
, J. H.
, 2014
, Daniels and Worthingham's Muscle Testing: Techniques of Manual Examination and Performance Testing
, 9th ed., Saunders/Elsevier
, St. Louis, MO
.4.
Prange
, G. B.
, Jannink
, M. J. A.
, Groothuis-Oudshoorn
, C. G. M.
, Hermens
, H. J.
, and IJzerman
, M. J.
, 2006
, “Systematic Review of the Effect of Robot-Aided Therapy on Recovery of the Hemiparetic Arm After Stroke
,” J. Rehabil. Res. Dev.
, 43
(2
), pp. 171
–184
.5.
Brewer
, B. R.
, McDowell
, S. K.
, and Worthen-Chaudhari
, L. C.
, 2007
, “Poststroke Upper Extremity Rehabilitation: A Review of Robotic Systems and Clinical Results
,” Top. Stroke Rehabil.
, 14
(6
), pp. 22
–44
.6.
Mehrholz
, J.
, Hädrich
, A.
, Platz
, T.
, Kugler
, J.
, and Pohl
, M.
, 2012
, “Electromechanical and Robot-Assisted Arm Training for Improving Generic Activities of Daily Living, Arm Function, and Arm Muscle Strength After Stroke
,” Cochrane Database Syst. Rev.
, 13
(6
), p. CD006876
.7.
Sukal
, T. M.
, Ellis
, M. D.
, and Dewald
, J. P. A.
, 2007
, “Shoulder Abduction-Induced Reductions in Reaching Work Area Following Hemiparetic Stroke: Neuroscientific Implications
,” Exp. Brain Res.
, 183
(2
), pp. 215
–223
.8.
Kwakkel
, G.
, and Meskers
, C. G. M.
, 2014
, “Effects of Robotic Therapy of the Arm After Stroke
,” Lancet Neurol.
, 13
(2
), pp. 132
–133
.9.
Runnalls
, K. D.
, Anson
, G.
, and Byblow
, W. D.
, 2015
, “Partial Weight Support of the Arm Affects Corticomotor Selectivity of Biceps Brachii
,” J. NeuroEng. Rehabil.
, 12
(1
), p. 94
.10.
Hislop
, H. J.
, and Montgomery
, J.
, 2007
, Daniels and Worthingham's Muscle Testing: Techniques of Manual Examination
, 8th ed., Saunders/Elsevier
, St. Louis, MO
.11.
Lew
, H. L.
, Lombard
, L. A.
, Reddy
, C. C.
, Moroz
, A.
, Edgley
, S. R.
, and Chae
, J.
, 2009
, “Stroke and Neurodegenerative Disorders—3: Poststroke Rehabilitation
,” PM&R
, 1
(3
), pp. S19
–S26
.12.
Nathan
, R. H.
, 1985
, “A Constant Force Generation Mechanism
,” ASME J. Mech. Transm. Autom. Des.
, 107
(4
), pp. 508
–512
.13.
Rahman
, T.
, Ramanathan
, R.
, Seliktar
, R.
, and Harwin
, W.
, 1995
, “A Simple Technique to Passively Gravity-Balance Articulated Mechanisms
,” ASME J. Mech. Des.
, 117
(4
), pp. 655
–658
.14.
Agrawal
, S. K.
, and Fattah
, A.
, 2004
, “Gravity-Balancing of Spatial Robotic Manipulators
,” Mech. Mach. Theory
, 39
(12
), pp. 1331
–1344
.15.
Banala
, S. K.
, Agrawal
, S. K.
, Fattah
, A.
, Krishnamoorthy
, V.
, Hsu
, W.-L.
, Scholz
, J.
, and Rudolph
, K.
, 2006
, “Gravity-Balancing Leg Orthosis and Its Performance Evaluation
,” IEEE Trans. Rob.
, 22
(6
), pp. 1228
–1239
.16.
Herder
, J. L.
, 2001
, “Energy-Free Systems: Theory, Conception, and Design of Statically Balanced Spring Mechanisms
,” Ph.D. thesis
, Faculty of Mechanical Maritime and Materials Engineering, Delft University of Technology, Delft, The Netherlands.17.
van Dorsser
, W. D.
, Barents
, R.
, Wisse
, B. M.
, and Herder
, J. L.
, 2007
, “Gravity-Balanced Arm Support With Energy-Free Adjustment
,” ASME J. Med. Devices
, 1
(2
), pp. 151
–158
.18.
Barents
, R.
, Schenk
, M.
, van Dorsser
, W. D.
, Wisse
, B. M.
, and Herder
, J. L.
, 2011
, “Spring-to-Spring Balancing as Energy-Free Adjustment Method in Gravity Equilibrators
,” ASME J. Mech. Des.
, 133
(6
), p. 061010
.19.
Lin
, P.-Y.
, Shieh
, W.-B.
, and Chen
, D.-Z.
, 2010
, “Design of a Gravity-Balanced General Spatial Serial-Type Manipulator
,” ASME J. Mech. Rob.
, 2
(3
), p. 031003
.20.
Dubey
, V. N.
, and Agrawal
, S. K.
, 2011
, “Study of an Upper Arm Exoskeleton for Gravity Balancing and Minimization of Transmitted Forces
,” Proc. Inst. Mech. Eng., Part H
, 225
(11
), pp. 1025
–1035
.21.
Eckenstein
, N.
, and Yim
, M.
, 2013
, “Modular Advantage and Kinematic Decoupling in Gravity Compensated Robotic Systems
,” ASME J. Mech. Rob.
, 5
(4
), p. 041013
.22.
Yang
, Z.-W.
, and Lan
, C.-C.
, 2015
, “An Adjustable Gravity-Balancing Mechanism Using Planar Extension and Compression Springs
,” Mech. Mach. Theory
, 92
, pp. 314
–329
.23.
Shieh
, W.-B.
, and Chou
, B.-S.
, 2015
, “Gravity Balancing of a Spatial Articulated Manipulator Based on a New Spring Mechanism
,” ASME
Paper No. DETC2015-47033.24.
Herder
, J. L.
, 1998
, “Design of Spring Force Compensation Systems
,” Mech. Mach. Theory
, 33
(1–2
), pp. 151
–161
.25.
Ebert-Uphoff
, I.
, Gosselin
, C. M.
, and Laliberté
, T.
, 2000
, “Static Balancing of Spatial Parallel Platform Mechanisms—Revisited
,” ASME J. Mech. Des.
, 122
(1
), pp. 43
–51
.26.
Deepak
, S. R.
, and Ananthasuresh
, G. K.
, 2012
, “Perfect Static Balance of Linkages by Addition of Springs But Not Auxiliary Bodies
,” ASME J. Mech. Rob.
, 4
(2
), p. 021014
.27.
Lin
, P.-Y.
, 2012
, “Design of Statically Balanced Spatial Mechanisms With Spring Suspensions
,” ASME J. Mech. Rob.
, 4
(2
), p. 021015
.28.
Cho
, C.
, and Kang
, S.
, 2014
, “Design of a Static Balancing Mechanism for a Serial Manipulator With an Unconstrained Joint Space Using One-DOF Gravity Compensators
,” IEEE Trans. Rob.
, 30
(2
), pp. 421
–431
.29.
Kim
, S.-H.
, and Cho
, C.-H.
, 2014
, “Design of Planar Static Balancer With Associated Linkage
,” Mech. Mach. Theory
, 81
, pp. 79
–93
.30.
Kim
, H.-S.
, and Song
, J.-B.
, 2014
, “Multi-DOF Counterbalance Mechanism for a Service Robot Arm
,” IEEE/ASME Trans. Mech.
, 19
(6
), pp. 1756
–1763
.31.
Veer
, S.
, and Sujatha
, S.
, 2015
, “Approximate Spring Balancing of Linkages to Reduce Actuator Requirements
,” Mech. Mach. Theory
, 86
, pp. 108
–124
.32.
Kuo
, C.-H.
, and Lai
, S.-J.
, 2016
, “Design of a Novel Statically Balanced Mechanism for Laparoscope Holders With Decoupled Positioning and Orientating Manipulation
,” ASME J. Mech. Rob.
, 8
(1
), p. 015001
.33.
Hsiu
, W.-H.
, Syu
, F.-C.
, and Kuo
, C.-H.
, 2015
, “Design and Implementation of a New Statically Balanced Mechanism for Slider-Type Desktop Monitor Stands
,” Proc. Inst. Mech. Eng., Part C
, 229
(9
), pp. 1671
–1685
.34.
Arakelian
, V.
, 2016
, “Gravity Compensation in Robotics
,” Adv. Rob.
, 30
(2
), pp. 79
–96
.35.
Agrawal
, A.
, and Agrawal
, S. K.
, 2005
, “Design of Gravity Balancing Leg Orthosis Using Non-Zero Free Length Springs
,” Mech. Mach. Theory
, 40
(6
), pp. 693
–709
.36.
Agrawal
, S. K.
, Banala
, S. K.
, Fattah
, A.
, Sangwan
, V.
, Krishnamoorthy
, V.
, Scholz
, J. P.
, and Hsu
, W.-L.
, 2007
, “Assessment of Motion of a Swing Leg and Gait Rehabilitation With a Gravity Balancing Exoskeleton
,” IEEE Trans. Neural Syst. Rehabil. Eng.
, 15
(3
), pp. 410
–420
.37.
Agrawal
, S. K.
, and Fattah
, A.
, 2004
, “Theory and Design of an Orthotic Device for Full or Partial Gravity-Balancing of a Human Leg During Motion
,” IEEE Trans. Neural Syst. Rehabil. Eng.
, 12
(2
), pp. 157
–165
.38.
Lin
, P.-Y.
, Shieh
, W.-B.
, and Chen
, D.-Z.
, 2013
, “A Theoretical Study of Weight-Balanced Mechanisms for Design of Spring Assistive Mobile Arm Support (MAS)
,” Mech. Mach. Theory
, 61
, pp. 156
–167
.39.
Cannella
, G.
, Laila
, D. S.
, and Freeman
, C. T.
, 2016
, “Mechanical Design of an Affordable Adaptive Gravity Balanced Orthosis for Upper Limb Stroke Rehabilitation
,” Mech. Based Des. Struct. Mach.
, 44
(1–2
), pp. 96
–108
.40.
Kuo
, C.-H.
, Dai
, J. S.
, and Yan
, H.-S.
, 2009
, “Reconfiguration Principles and Strategies for Reconfigurable Mechanisms
,” ASME/IFToMM International Conference on Reconfigurable Mechanisms and Robots
(ReMAR
), London, June 22–24, pp. 1–7.41.
Yoon
, J.
, Ryu
, J.
, and Lim
, K.-B.
, 2006
, “Reconfigurable Ankle Rehabilitation Robot for Various Exercises
,” J. Rob. Syst.
, 22
(S1
), pp. S15
–S33
.42.
Satici
, A. C.
, Erdogan
, A.
, and Patoglu
, V.
, 2009
, “Design of a Reconfigurable Ankle Rehabilitation Robot and Its Use for the Estimation of the Ankle Impedance
,” IEEE International Conference on Rehabilitation Robotics
(ICORR
), Kyoto, Japan, June 23–26, pp. 257–264.43.
Zeng
, S.
, Yao
, L.
, Guo
, X.
, Wang
, H.
, and Sui
, P.
, 2015
, “Kinematics Analysis and Verification on the Novel Reconfigurable Ankle Rehabilitation Robot Based on Parallel Mechanism
,” New Trends in Mechanism and Machine Science
, Vol. 24
, P.
Flores
and F.
Viadero
, eds., Springer International Publishing
, Cham, Switzerland
, pp. 195
–202
.44.
MSC Software, 2014, “
Introducing Adams Real Time
,” MSC Software Corporation, Newport Beach, CA, accessed July 31, 2014, http://www.mscsoftware.com/45.
Haley, J.,
1988
, “Anthropometry and Mass Distribution for Human Analogues
,” Harry G. Armstrong Aerospace Medical Research Laboratory, Wright-Patterson Air Force Base, OH, Report No. AAMRL-TR-88-010
, pp. 33–38.46.
Spring Ming, 2014, “
Stock Precision Engineered Components Spring Catalog
,” Taipei, Taiwan, accessed July 31, 2014, http://www.springming.com/47.
Delsys, 2014, “DELSYS: Wearable Sensors For Movement Sciences,” Delsys, Inc., accessed July 31, 2014, http://www.delsys.com/
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