Development of a Soft Robotics Module for Active Control of Sitting Comfort

Tjark Roozendaal; Martin Verwaal; Alice Buso; Rob B.N. Scharff; Yu Song; Peter Vink

doi:10.3390/mi13030477

Development of a Soft Robotics Module for Active Control of Sitting Comfort

Tjark Roozendaal, Martin Verwaal, Alice Buso, Rob B.N. Scharff, Yu Song, Peter Vink^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

3 Citations (Scopus)

54 Downloads (Pure)

Abstract

Sitting comfort is an important factor for passengers in selecting cars, airlines, etc. This paper proposes a soft robotic module that can be integrated into the seat cushion to provide better comfort experiences to passengers. Building on rapid manufacturing technologies and a data-driven approach, the module can be controlled to sense the applied force and the displacement of the top surface and actuate according to four designed modes. A total of 2 modules were prototyped and integrated into a seat cushion, and 16 subjects were invited to test the module’s effectiveness. Experiments proved the principle by showing significant differences regarding (dis)comfort. It was concluded that the proposed soft robotics module could provide passengers with better comfort experiences by adjusting the pressure distribution of the seat as well as introducing a variation of postures relevant for prolonged sitting.

Original language	English
Article number	477
Number of pages	14
Journal	Micromachines
Volume	13
Issue number	3
DOIs	https://doi.org/10.3390/mi13030477
Publication status	Published - 2022

Keywords

adaptive
comfort
pneumatics
seat
soft-robotics module

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10.3390/mi13030477

micromachines-13-00477-v2Final published version, 5.67 MBLicence: CC BY

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AU - Song, Yu

AU - Vink, Peter

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AB - Sitting comfort is an important factor for passengers in selecting cars, airlines, etc. This paper proposes a soft robotic module that can be integrated into the seat cushion to provide better comfort experiences to passengers. Building on rapid manufacturing technologies and a data-driven approach, the module can be controlled to sense the applied force and the displacement of the top surface and actuate according to four designed modes. A total of 2 modules were prototyped and integrated into a seat cushion, and 16 subjects were invited to test the module’s effectiveness. Experiments proved the principle by showing significant differences regarding (dis)comfort. It was concluded that the proposed soft robotics module could provide passengers with better comfort experiences by adjusting the pressure distribution of the seat as well as introducing a variation of postures relevant for prolonged sitting.

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Development of a Soft Robotics Module for Active Control of Sitting Comfort

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Keywords

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