Multi-material 3D printed hydraulic actuator for medical robots

Siegfarth, Marius; Pusch, Tim Philipp; Pfeil, Antoine; Renaud, Pierre; Stallkamp, Jan

doi:10.1108/rpj-07-2019-0205

Cited by 12 publications

(11 citation statements)

References 10 publications

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“…The capacity to produce multimaterial components was exploited to design each piston as a single part, with a hollow shape at the tip. It was observed [18] this creates an adaptive sealing effect: friction between the piston and the bore is reduced for low fluid pressure, while high fluid pressure increases the friction to avoid leakage (Fig. ??).…”

Section: Design Of Hydraulic Cylindersmentioning

confidence: 99%

“…There are still limits to the proposed hydraulic-based actuated joint in its current implementation. First, the use of Polyjet process as considered here with TangoBlack plus material was observed to suffer from material degradation for long-term uses [18]. Further process development would help to have functional systems with large endurance.…”

Section: Characterization Of the Componentmentioning

confidence: 99%

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Design and Experimental Characterization of Hydraulically Actuated Revolute Joint Based on Multimaterial Additive Manufacturing

Pfeil

Siegfarth²,

Pusch³

et al. 2021

Journal of Mechanical Design

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Design of fluidic actuators remain challenging in specific contexts such as the medical field, when solutions have for instance to be compatible with the stringent requirements of magnetic resonance imaging. In this paper, an innovative design of hydraulically-actuated revolute joint is introduced. The design originality is linked to the use of multimaterial additive manufacturing for its production. Hydraulic actuation and polymer manufacturing are selected to have compatibility with the medical context. A design taking advantage of the process capabilities is proposed. The proposed component associates a large stroke compliant revolute joint and miniature pistons. An helical rack-and-pinion mechanism is integrated to the compliant joint to control the joint rotation. A specific gear geometry is elaborated to minimize the joint size. It is experimentally characterized in terms of range of motion, stiffness and available torque, to discuss the suitability of the component as a fluidic actuator. The component offers an interesting compactness, range of motion and the process is shown to be adequate for the design of functional systems.

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Section: Design Of Hydraulic Cylindersmentioning

confidence: 99%

Section: Characterization Of the Componentmentioning

confidence: 99%

Design and Experimental Characterization of Hydraulically Actuated Revolute Joint Based on Multimaterial Additive Manufacturing

Pfeil

Siegfarth²,

Pusch³

et al. 2021

Journal of Mechanical Design

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“…The valves are a very simple three-piece assembly with an assembled diameter of 3 mm. Multi material additive manufacturing has been used to print hydraulic actuators with integrated seals safe for medical applications [15]. These examples show how 3D printing is being utilized to produce very low-pressure hydraulic components in ways not possible by traditional manufacturing methods.…”

Section: P Cmentioning

confidence: 99%

A Low-Cost Miniature Electrohydrostatic Actuator System

Wiens

Deibert

2020

Actuators

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Hydraulic linear actuators dominate in high power applications but are much less common in low power (<100 W) systems. One reason for this is the cost: electric actuators in this power range generally exhibit lower performance but are also much less expensive than hydraulic systems. However, in recent years, some miniature hydraulic components have been mass produced, driving down prices. This paper presents the application of these low-cost components, together with a novel very low-cost 3D-printed valve to create an electrohydrostatic actuator. Capable of very high power and force density, this system is competitive on cost with lower-performing electric actuators. This paper presents models for the system’s performance, as well as experimental validation data.

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“…However, for direct AM of complex multi-material components, only a few technologies are available. The most wide-spread commercial option is the PolyJet (PJ) process (Siegfarth et al , 2020), in which objects of desired shapes are accumulated from droplets of acrylate-based photocurable ink that are deposited via piezo nozzles and cured by infrared light. Kundera and Bochnia (2014) fabricated O-ring seals using PJ technology and found that, although the seals were usable, they exhibited complex time-dependent mechanical behavior.…”

Section: Introductionmentioning

confidence: 99%

Design, additive manufacturing and component testing of pneumatic rotary vane actuators for lightweight robots

Dämmer

Bauer

Neumann

et al. 2022

RPJ

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Purpose This study aims to investigate the suitability of a multi-step prototyping strategy for producing pneumatic rotary vane actuators (RVAs) for the development of lightweight robots and actuation systems. Design/methodology/approach RVAs typically have cast aluminum housings and injection-molded seals that consist of hard thermoplastic cores and soft elastomeric overmolds. Using a combination of additive manufacturing (AM), computer numerical control (CNC) machining and elastomer molding, a conventionally manufactured standard RVA was replicated. The standard housing design was modified, and polymeric replicas were obtained by selective laser sintering (SLS) or PolyJet (PJ) printing and subsequent CNC milling. Using laser-sintered molds, actuator seals were replicated by overmolding laser-sintered polyamide cores with silicone (SIL) and polyurethane (PU) elastomers. The replica RVAs were subjected to a series of leakage, friction and durability experiments. Findings The AM-based prototyping strategy described is suitable for producing functional and reliable RVAs for research and product development. In a representative durability experiment, the RVAs in this study endured between 40,000 and 1,000,000 load cycles. Frictional torques were around 0.5 Nm, which is 10% of the theoretical torque at 6 bar and comparable to that of the standard RVA. Models and parameters are provided for describing the velocity-dependent frictional torque. Leakage experiments at 10,000 load cycles and 6 bar differential pressure showed that PJ housings exhibit lower leakage values (6.8 L/min) than laser-sintered housings (15.2 L/min), and PU seals exhibit lower values (8.0 l/min) than SIL seals (14.0 L/min). Combining PU seals with PJ housings led to an initial leakage of 0.4 L/min, which increased to only 1.2 L/min after 10,000 load cycles. Overall, the PU material used was more difficult to process but also more abrasion- and tear-resistant than the SIL elastomer. Research limitations/implications More work is needed to understand individual cause–effect relationships between specific design features and system behavior. Originality/value To date, pneumatic RVAs have been manufactured by large-scale production technologies. The absence of suitable prototyping strategies has limited the available range to fixed sizes and has thus complicated the use of RVAs in research and product development. This paper proves that functional pneumatic RVAs can be produced by using more accessible manufacturing technologies and provides the tools for prototyping of application-specific RVAs.

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Multi-material 3D printed hydraulic actuator for medical robots

Cited by 12 publications

References 10 publications

Design and Experimental Characterization of Hydraulically Actuated Revolute Joint Based on Multimaterial Additive Manufacturing

Design and Experimental Characterization of Hydraulically Actuated Revolute Joint Based on Multimaterial Additive Manufacturing

A Low-Cost Miniature Electrohydrostatic Actuator System

Design, additive manufacturing and component testing of pneumatic rotary vane actuators for lightweight robots

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