Aerosol-jet-printed, conformable microfluidic force sensors

Jing, Qingshen; Pace, Alizée; Ives, Liam; Husmann, Anke; Ćatić, Nordin; Khanduja, Vikas; Cama, Jehangir; Kar‐Narayan, Sohini

doi:10.1016/j.xcrp.2021.100386

Cited by 21 publications

(19 citation statements)

References 37 publications

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“…[229][230][231] Despite being less popular than the IJP process for the fabrication of soft sensors, there have been several works on AJP printed soft sensors. [232,233]…”

Section: Material-jetting Techniquesmentioning

confidence: 99%

3D Printing of Robotic Soft Grippers: Toward Smart Actuation and Sensing

Goh

Lyu

Ariffin

et al. 2022

Adv Materials Technologies

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Unlike traditional hard grippers, soft robotic grippers are commonly made of soft materials so that the soft grippers can produce motion via elastic deformations of their compliant components. The advantages of compliance allow soft grippers to effectively eliminate shocks caused by hard contact, which usually occurs when a hard robotic gripper manipulates a hard object. Until now, the soft robotic grippers are able to operate numerous objects with irregular geometries and different textures. Besides, with the help of embedded sensors, soft robotic grippers have facilitated the growing automation of many tasks, which are thought to be far too delicate for robotic manipulation. This paper reviews the advancement in soft robotic grippers. The paper first introduces the actuation technologies followed by the design and fabrication techniques. The use of 3D printing techniques in the fabrication of the soft gripper is also discussed. The Review then highlights the challenges and future outlook in the fabrication of soft grippers and sensors.

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“…[229][230][231] Despite being less popular than the IJP process for the fabrication of soft sensors, there have been several works on AJP printed soft sensors. [232,233]…”

Section: Material-jetting Techniquesmentioning

confidence: 99%

3D Printing of Robotic Soft Grippers: Toward Smart Actuation and Sensing

Goh

Lyu

Ariffin

et al. 2022

Adv Materials Technologies

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“…Besides, the cost-effectiveness of screen printing makes the use of large area electronic or tactile skin in robotics possible. 122 While AJP 35,45,67,123 and DLP 38,40,42,43,124,125 have been applied for the fabrication of flexible mechanical sensors, they are less common due to various reasons. For example, although AJP is a newly developed printing technique with high resolution 91 and fast printing speed, 90 the cost of AJP is much higher in contrast to other techniques; while DLP can fabricate sophisticated 3D geometries with high resolution and rapid speed, the requirement of a photocurable resin limits the material selection.…”

Section: Changhong Caomentioning

confidence: 99%

“…10c). 35 The interdigitated microfluidic configuration effectively enhances the capacitive response similar to typical silicon-based comb-drive electrostatic sensors. Compared to a straight and parallel-electrode design, the interdigitated configuration increased the linear sensitivity of the sensor from 0.55 pF N −1 to 3.75 pF N −1 up to an applied force of 9 N, and its response remained stable for 2200+ compression cycles.…”

Section: Printed Flexible Force Sensorsmentioning

confidence: 99%

“…Printing technologies have also been applied to fabricate flexible force sensors using inks including silver, 35,47,48,52 CNTs, 19,34,66,122,152 liquid metals 18 and conductive polymers 114,125 as the sensing elements. Based on the sensing mechanism, they can also be grouped into three major types: capacitive, piezoelectric and others ( e.g.…”

Section: Mechanical Sensors By Typementioning

confidence: 99%

“…Fabrication of flexible mechanical sensors by printing technologies have emerged as a versatile, economical, and enabling approach. For instance, various types of mechanical sensors (e.g., force, [33][34][35] pressure, [36][37][38][39][40] and strain [41][42][43][44][45][46] ) can be produced by leveraging many 2D/3D printing techniques including but not limited to screen printing, [47][48][49][50][51] inkjet printing, [52][53][54][55][56] direct ink writing (DIW), [57][58][59] digital light processing (DLP), [60][61][62] and fused filament fabrication (FFF). [63][64][65][66] The additive nature of printing technologies also largely reduces the fabrication cost and time; 67,68 in addition, fabrication by printing enabled the production of flexible mechanical sensors with excellent performance.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Printed flexible mechanical sensors

Smocot

Zhang

et al. 2022

Nanoscale

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Aerosol‐Jet Printed Sensors for Environmental, Safety, and Health Monitoring: A Review

Fisher

Skolrood

et al. 2023

Adv Materials Technologies

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An emergent direct‐write approach, aerosol‐jet printing (AJP), is gaining attention for the deployment of rapid and affordable microadditively manufactured energy‐efficient sensors and printed electronics. AJP enables a broad range of ink viscosities (0.001–1 Pa s) for printing diverse materials ranging from ceramics and metals to polymers and biological matter. Reproducible, high‐spatial‐resolution features (≈10 µm), and wide standoff distances (1–11 mm) between the nozzle and the substrate facilitate conformal printing of complex geometrical designs on nonplanar—e.g., stepped or curved—surfaces. This paper aims to provide a comprehensive overview of state‐of‐the‐art AJP‐based sensors (e.g., strain and temperature gauges, biosensors, photosensors, humidity and surface acoustic wave sensors, dielectric elastomer actuators, and motion, smoke, and hazardous gas detectors) and to discuss prospective applications. The drive toward cost‐effective devices that are smaller, lighter, and better‐performing remains a frontier challenge in the field of printed electronics. Consequently, as AJP becomes increasingly utilized in the high‐volume manufacturing of miniaturized active and passive sensors, it opens a pathway for facile large‐scale fabrication of devices for a wide range of consumer and industrial applications, including transportation, agriculture, infrastructure, aerospace, national defense, and healthcare.

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Aerosol-jet-printed, conformable microfluidic force sensors

Cited by 21 publications

References 37 publications

3D Printing of Robotic Soft Grippers: Toward Smart Actuation and Sensing

3D Printing of Robotic Soft Grippers: Toward Smart Actuation and Sensing

Printed flexible mechanical sensors

Aerosol‐Jet Printed Sensors for Environmental, Safety, and Health Monitoring: A Review

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