The effect of control strategies for an active back-support exoskeleton on spine loading and kinematics during lifting

Koopman, Axel S.; Toxiri, Stefano; Power, Valerie; Kingma, Idsart; Dieën, Jaap H. van; Ortiz, Jesús; Looze, M.P. de

doi:10.1016/j.jbiomech.2019.04.044

Cited by 78 publications

(56 citation statements)

References 54 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…The net L5S1 moment generated by subjects was significantly lower when wearing the exoskeleton for all the assistance modes, with reductions of up to 17%, in line with Koopman et al (2019c). The peak reductions observed were similar to those obtained when the PLAD passive device was tested (Frost et al, 2009), and greater than those with Laevo, a commercially available passive exoskeleton for which a similar study was conducted (Koopman et al, 2019a).…”

Section: Discussionsupporting

confidence: 64%

“…To validate this new strategy, its effectiveness was experimentally evaluated in terms of spine kinematics, muscle activation, lumbar extensor moment, and compression reductions and variations in the task execution relative to the condition without the exoskeleton. Additionally, to study its effects in greater detail, the acceleration-based strategy was tested against existing strategies for comparison (Toxiri et al, 2018;Koopman et al, 2019c).…”

Section: Objective Of This Studymentioning

confidence: 99%

See 1 more Smart Citation

Evaluation of an acceleration-based assistive strategy to control a back-support exoskeleton for manual material handling

et al. 2020

Self Cite

View full text Add to dashboard Cite

To reduce the incidence of occupational musculoskeletal disorders, back-support exoskeletons are being introduced to assist manual material handling activities. Using a device of this type, this study investigates the effects of a new control strategy that uses the angular acceleration of the user’s trunk to assist during lifting tasks. To validate this new strategy, its effectiveness was experimentally evaluated relative to the condition without the exoskeleton as well as against existing strategies for comparison. Using the exoskeleton during lifting tasks reduced the peak compression force on the L5S1 disc by up to 16%, with all the control strategies. Substantial differences between the control strategies in the reductions of compression force, lumbar moment and back muscle activation were not observed. However, the new control strategy reduced the movement speed less with respect to the existing strategies. Thanks to improved timing in the assistance in relation to the typical dynamics of the target task, the hindrance to typical movements appeared reduced, thereby promoting intuitiveness and comfort.

show abstract

Section: Discussionsupporting

confidence: 64%

Section: Objective Of This Studymentioning

confidence: 99%

Evaluation of an acceleration-based assistive strategy to control a back-support exoskeleton for manual material handling

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…EMG data were normalized to maximum voluntary contractions (MVC) (McGill, 1991). Overall, lumbar extensor activity (averaged IL and LL muscle activity, right and left side) was computed prior to performing deep-back muscles analysis as in Koopman et al (2019).…”

Section: Measurements and Data Processingmentioning

confidence: 99%

Applicability of an Active Back-Support Exoskeleton to Carrying Activities

et al. 2020

Self Cite

View full text Add to dashboard Cite

Occupational back-support exoskeletons are becoming a more and more common solution to mitigate work-related lower-back pain associated with lifting activities. In addition to lifting, there are many other tasks performed by workers, such as carrying, pushing, and pulling, that might benefit from the use of an exoskeleton. In this work, the impact that carrying has on lower-back loading compared to lifting and the need to select different assistive strategies based on the performed task are presented. This latter need is studied by using a control strategy that commands for constant torques. The results of the experimental campaign conducted on 9 subjects suggest that such a control strategy is beneficial for the back muscles (up to 12% reduction in overall lumbar activity), but constrains the legs (around 10% reduction in hip and knee ranges of motion). Task recognition and the design of specific controllers can be exploited by active and, partially, passive exoskeletons to enhance their versatility, i.e., the ability to adapt to different requirements.

show abstract

“…In practice, people adopt a wide range of postures in daily life, and postures with smaller torso angles will have lower torques needed to support the torso. Additionally, torques of up to 50 Nm are provided by passive structures in the back (Dolan et al, 1994;Bazrgari et al, 2007;Olson et al, 2009;Koopman et al, 2019b), and this will reduce the torque needed by an exoskeleton unless the wearer is extremely flexible (Dolan and Adams, 1993a). Thus, it may be beneficial in most circumstances for a back exoskeleton to provide smaller torques than those in Figure 1.…”

Section: Exoskeleton Comparative Design Analysis Design Goalsmentioning

confidence: 99%

Design and preliminary evaluation of a flexible exoskeleton to assist with lifting

et al. 2020

View full text Add to dashboard Cite

We present a passive (unpowered) exoskeleton that assists the back during lifting. Our exoskeleton uses carbon fiber beams as the sole means to store energy and return it to the wearer. To motivate the design, we present general requirements for the design of a lifting exoskeleton, including calculating the required torque to support the torso for people of different weights and heights. We compare a number of methods of energy storage for exoskeletons in terms of mass, volume, hysteresis, and cycle life. We then discuss the design of our exoskeleton, and show how the torso assembly leads to balanced forces. We characterize the energy storage in the exoskeleton and the torque it provides during testing with human subjects. Ten participants performed freestyle, stoop, and squat lifts. Custom image processing software was used to extract the curvature of the carbon fiber beams in the exoskeleton to determine the stored energy. During freestyle lifting, it stores an average of 59.3 J and provides a peak torque of 71.7 Nm.

show abstract

The effect of control strategies for an active back-support exoskeleton on spine loading and kinematics during lifting

Cited by 78 publications

References 54 publications

Evaluation of an acceleration-based assistive strategy to control a back-support exoskeleton for manual material handling

Evaluation of an acceleration-based assistive strategy to control a back-support exoskeleton for manual material handling

Applicability of an Active Back-Support Exoskeleton to Carrying Activities

Design and preliminary evaluation of a flexible exoskeleton to assist with lifting

Contact Info

Product

Resources

About