PolyJet-Printed Bellows Actuators: Design, Structural Optimization, and Experimental Investigation

Dämmer, Gabriel; Gablenz, Sven; Hildebrandt, A.; Major, Zoltán

doi:10.3389/frobt.2019.00034

Cited by 35 publications

(47 citation statements)

References 34 publications

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“…The AM of suitable actuators for lightweight robots seems to be particularly challenging but the use of printed pneumatic bellows actuators presents a promising approach and could become a decisive factor for the success of pneumatic lightweight robots in the long-term. Bellows actuators overcome some of the difficulties in printing conventional pneumatic actuation systems ( MacCurdy et al, 2016 ) which require tight tolerances and smooth surfaces and the structural behavior of bellows actuators can easily be modified by varying shape and material ( Dämmer et al, 2019a ). In bellows actuators, actuation results from expansion of a deformable chamber due to pressurization.…”

Section: Introductionmentioning

confidence: 99%

“…Programming parallel deposition of droplets of different materials allows 3D multi-material objects to be produced ( Schmitt et al, 2018 ). These may consist of materials with different physical properties, such as color ( Scharff et al, 2018 ), hardness ( Stratasys, Ltd., 2017 ; Dämmer et al, 2019a ) and electrical conductivity ( Saleh et al, 2017 ); even ceramic-filled inks for abrasion-resistant components are being developed ( Graf et al, 2020 ). However, 3D inkjet printing is currently used predominantly to produce monolithic multi-material parts with soft and rigid features.…”

Section: Introductionmentioning

confidence: 99%

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Design of an Inkjet-Printed Rotary Bellows Actuator and Simulation of its Time-Dependent Deformation Behavior

et al. 2021

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State-of-the-art Additive Manufacturing processes such as three-dimensional (3D) inkjet printing are capable of producing geometrically complex multi-material components with integrated elastomeric features. Researchers and engineers seeking to exploit these capabilities must handle the complex mechanical behavior of inkjet-printed elastomers and expect a lack of suitable design examples. We address these obstacles using a pneumatic actuator as an application case. First, an inkjet-printable actuator design with elastomeric bellows structures is presented. While soft robotics research has brought forward several examples of inkjet-printed linear and bending bellows actuators, the rotary actuator described here advances into the still unexplored field of additively manufactured pneumatic lightweight robots with articulated joints. Second, we demonstrate that the complex structural behavior of the actuator’s elastomeric bellows structure can be predicted by Finite Element (FE) simulation. To this end, a suitable hyperviscoelastic material model was calibrated and compared to recently published models in a multiaxial-state-of-stress relaxation experiment. To verify the material model, Finite Element simulations of the actuator’s deformation behavior were conducted, and the results compared to those of corresponding experiments. The simulations presented here advance the materials science of inkjet-printed elastomers by demonstrating use of a hyperviscoelastic material model for estimating the deformation behavior of a prototypic robotic component. The results obtained contribute to the long-term goal of additively manufactured and pneumatically actuated lightweight robots.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design of an Inkjet-Printed Rotary Bellows Actuator and Simulation of its Time-Dependent Deformation Behavior

et al. 2021

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“…Utilizing endo- and exo-skeleton designs has been shown to prevent buckling and improve overall strength ( Fishman et al, 2017 ; Castledine et al, 2019 ). Bellows, which have high torsional rigidity in comparison with its flexural rigidity, have also been used in pneumatic ( Drotman et al, 2017 ; Dämmer et al, 2019 ) and concentric-tube robots ( Childs and Rucker, 2020 ) which can drastically improve the torsional strength of the overall robot. Origami-inspired structures show great promise as many of these designs can be tuned from geometric parameters and can be made on a wide range of scales ( Liu et al, 2018 ; Rus and Sung, 2018 ; Santoso and Onal, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Leveraging Geometry to Enable High-Strength Continuum Robots

Childs

Rucker

2021

Front. Robot. AI

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Developing high-strength continuum robots can be challenging without compromising on the overall size of the robot, the complexity of design and the range of motion. In this work, we explore how the load capacity of continuum robots can drastically be improved through a combination of backbone design and convergent actuation path routing. We propose a rhombus-patterned backbone structure composed of thin walled-plates that can be easily fabricated via 3D printing and exhibits high shear and torsional stiffness while allowing bending. We then explore the effect of combined parallel and converging actuation path routing and its influence on continuum robot strength. Experimentally determined compliance matrices are generated for straight, translation and bending configurations for analysis and discussion. A robotic actuation platform is constructed to demonstrate the applicability of these design choices.

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“…For example, when it comes to printing ever smaller structures [10,11] or simplifying the process by using physical conditions to meet economic requirements [12,13]. 3D inkjet printing differs from the above-mentioned production methods in that it allows several materials to be deposited in one process step, which could enable the production of fully functional and complete components in one printing process [14][15][16]. Layer by layer, a low-viscosity material is usually dispensed from a drop-on-demand print head via piezoelectric actuation.…”

Section: Introductionmentioning

confidence: 99%

“…To further increase the potential of 3D inkjet printing, the technology is moving from rapid prototyping to rapid manufacturing [14,15]. This creates a demand for components with suitable mechanical properties.…”

Section: Introductionmentioning

confidence: 99%

Investigations on the Processing of Ceramic Filled Inks for 3D InkJet Printing

2020

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3D inkjet printing is moving from a technology of rapid prototyping to rapid manufacturing. The introduction of ultraviolet curable composites filled with functional ceramics could expand the possibilities of this technology. In this work, a simple and scalable process was investigated as a template for the production of inkjet printable functional ceramics. Pyrogenic alumina particles with an average size of 13 nm, 35 nm and 100 nm were used as fillers in an acrylate mixture. The physical coating of the ceramics with 2-[2-(2-methoxyethoxy)ethoxy] acetic acid results in a low-viscosity dispersion with a ceramic content of up to 2 vol%, Newtonian behavior and surface tension within the limits allowed for inkjet printing. The material has sufficient stability for printing tensile specimens. Tensile tests have shown that modulus of elasticity, tensile strength and toughness can be kept constant despite the light scatter caused by the particles. The final production steps could be reduced to grinding and drying of the powders, their resuspension in the organic matrix and inkjet printing. The process can be used in an industrial-scale production of materials for abrasion-resistant components with adapted tribology.

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PolyJet-Printed Bellows Actuators: Design, Structural Optimization, and Experimental Investigation

Cited by 35 publications

References 34 publications

Design of an Inkjet-Printed Rotary Bellows Actuator and Simulation of its Time-Dependent Deformation Behavior

Design of an Inkjet-Printed Rotary Bellows Actuator and Simulation of its Time-Dependent Deformation Behavior

Leveraging Geometry to Enable High-Strength Continuum Robots

Investigations on the Processing of Ceramic Filled Inks for 3D InkJet Printing

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