Soft Robotic Bilateral Rehabilitation System for Hand and Wrist Joints
Abstract
:1. Introduction
- Combination of soft hand-and-wrist exoskeletons for achieving necessary coordinated motion.
- Bilateral therapy of combined hand and wrist joints.
2. Bilateral Therapy System
2.1. Hand-and-Wrist Sensor Glove
2.2. Hand-and-Wrist Exoskeleton
2.3. Pneumatic Control Unit
3. Control Algorithm
4. Experimental Setup
4.1. Materials
4.2. Methods
4.2.1. Wrist Exercise with Dumbbell
4.2.2. Object Pick-and-Place Task
5. Results and Discussion
5.1. Wrist Exercise with Dumbbell
5.2. Object Pick-and-Place Task
5.3. Discussions
- Qualitatively, the graphs demonstrate that the fingers and wrist joints assisted by HWE followed the same trajectories as guided by the HWSG, which verifies the functionality of the bilateral therapy algorithm.
- In this work, the main focus was to show that the motions of both HWSG and HWE followed a similar trajectory during a rehabilitation task rather than error computation. Regardless, discrepancies between the reference () and measured () angles were observed in some joints and could be attributed to the nature of the experiment. In this work, a human controlled the sensor glove, and object manipulation was involved in the experiments. Therefore, the user had no sense of how much angle to move their fingers in order for the HWE to grab an object. The joint angles in HWSG could move to higher angles than HWE, as there was no object present in the HWSG hand to interfere with the joint motion. However, a similar bilateral soft robotic system for the hand (wrist excluded) was tested in our previous work [16] and showed minimal error between the angular motion of the sensor glove versus the robotic glove while both gloves were attached to artificial hand models.
- It was observed that the gaps (angle difference) between the angles recorded by the HWSG and HWE were greater in the thumb actuators than in all other actuators (Figure 10e and Figure 12e). This was because the user was holding either a dumbbell or an object in the HWE hand, which restricted the movement of the thumb once it touched the object, whereas, in the case of the HWSG hand, there was no object to restrict the movement.
- Results from both applications show that all the finger actuators inflated quicker than the wrist actuator. This was because finger actuators have a very small volume to be filled compared to that of the wrist actuator. This situation can be resolved by using a bigger proportional valve for the wrist actuator.
- In the case of deflation, finger actuators deflated slower than the wrist actuator. This was because the orifice size of the proportional valves used to deflate the finger actuators was small in comparison to the proportional valve used for the wrist actuator. For the fingers and wrist actuators, the orifice sizes of proportional valves were 0.25 mm (Parker-910-000042-030) and 1.02 mm (Parker-910-000045-030), respectively. Conductivity (C) of a pipe under vacuum flow is given as [22],
6. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
Abbreviations
HWSG | Hand-and-wrist sensor glove |
HWE | Hand-and-wrist exoskeleton |
PD | Proportional derivative |
ADC | Analog-to-digital converter |
ROM | Range of motion |
PWM | Pulse width modulation |
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Component Name | Model | Dimensions (L × W × H) mm | Weight (g) |
---|---|---|---|
Pump | Parker D1020-23-01 | 85 × 30 × 75 | 257.48 |
Solenoid Valve (Fingers) | Clippard E210C | 45 × 15 × 20 | 10.01 |
Solenoid Valve (Wrist) | Clippard E210H | 45 × 15 × 20 | 9.91 |
Proportional Valve (Fingers) | Parker 910-000042-030 | 30 × 10 × 20 | 47.00 |
Proportional Valve (Wrist) | Parker 910-000045-030 | 30 × 10 × 20 | 47.00 |
Pressure Sensor (Range: 0 to 206.84 kPa) | Honeywell ABPMANN004BGAA5 | 7.3 × 6.3 × 18.6 | 7.08 |
Vacuum Sensor (Range: −115 to 0 kPa) | NXP MPXV6115V | 18.01 × 10.54 × 5.38 | 1.30 |
Microcontroller | ESP-32 | 50 × 25 × 10 | 10.46 |
Thumb Actuator | 5.5 | 4 |
Index Actuator | 4.5 | 3.4 |
Middle Actuator | 5.8 | 4.6 |
Ring Actuator | 4.5 | 3.4 |
Little Actuator | 5.2 | 4.1 |
Wrist Actuator | 8.1 | 6.7 |
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Ridremont, T.; Singh, I.; Bruzek, B.; Erel, V.; Jamieson, A.; Gu, Y.; Merzouki, R.; Wijesundara, M.B.J. Soft Robotic Bilateral Rehabilitation System for Hand and Wrist Joints. Machines 2024, 12, 288. https://doi.org/10.3390/machines12050288
Ridremont T, Singh I, Bruzek B, Erel V, Jamieson A, Gu Y, Merzouki R, Wijesundara MBJ. Soft Robotic Bilateral Rehabilitation System for Hand and Wrist Joints. Machines. 2024; 12(5):288. https://doi.org/10.3390/machines12050288
Chicago/Turabian StyleRidremont, Tanguy, Inderjeet Singh, Baptiste Bruzek, Veysel Erel, Alexandra Jamieson, Yixin Gu, Rochdi Merzouki, and Muthu B. J. Wijesundara. 2024. "Soft Robotic Bilateral Rehabilitation System for Hand and Wrist Joints" Machines 12, no. 5: 288. https://doi.org/10.3390/machines12050288
APA StyleRidremont, T., Singh, I., Bruzek, B., Erel, V., Jamieson, A., Gu, Y., Merzouki, R., & Wijesundara, M. B. J. (2024). Soft Robotic Bilateral Rehabilitation System for Hand and Wrist Joints. Machines, 12(5), 288. https://doi.org/10.3390/machines12050288