Additive Manufacturing of Elastomeric Composite Lattices with Thermally Grown Micro‐Architectures for Versatile Applications

Tang, Zhen‐Hua; Xue, Shan‐Shan; Li, Yuan‐Qing; Huang, Pei; Fu, Ya‐Qin; Fu, Shao‐Yun

doi:10.1002/admt.202300799

Cited by 3 publications

(1 citation statement)

References 54 publications

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“…Hensleigh et al [19] employed SLA technology to print a multi-material structure with positive, negative, and neutral resins and soaked it in either a positive or negative catalyst solution to define the ELP deposition area for the fabrication of 3D electronics. Tang, Z et al [20] combined AM and thermal growth processes to prepare elastomeric composite dots with microstructures that have excellent impact energy dissipation capabilities and thermal insulation properties. Our group proposed a series of HAM technology experiments based on laser activated electroless plating for the fabrication of 3D conformal/multilayer electronics, sensors, antennas, etc.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional Polymer-Metal Lattice Composites via Hybrid Additive Manufacturing Technology

He,

Wang,

Wang

et al. 2023

Micromachines

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With increasing interest in the rapid development of lattice structures, hybrid additive manufacturing (HAM) technology has become a competent alternative to traditional solutions such as water jet cutting and investment casting. Herein, a HAM technology that combines vat photopolymerization (VPP) and electroless/electroplating processes is developed for the fabrication of multifunctional polymer-metal lattice composites. A VPP 3D printing process is used to deliver complex lattice frameworks, and afterward, electroless plating is employed to deposit a thin layer of nickel-phosphorus (Ni-P) conductive seed layer. With the subsequent electroplating process, the thickness of the copper layer can reach 40 μm within 1 h and the resistivity is around 1.9×10−8 Ω⋅m, which is quite close to pure copper (1.7 ×10−8 Ω⋅m). The thick metal shell can largely enhance the mechanical performance of lattice structures, including structural strength, ductility, and stiffness, and meanwhile provide current supply capability for electrical applications. With this technology, the frame arms of unmanned aerial vehicles (UAV) are developed to demonstrate the application potential of this HAM technology for fabricating multifunctional polymer-metal lattice composites.

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Section: Introductionmentioning

confidence: 99%

Multifunctional Polymer-Metal Lattice Composites via Hybrid Additive Manufacturing Technology

He,

Wang,

Wang

et al. 2023

Micromachines

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3D‐Printed Soft Proprioceptive Graded Porous Actuators with Strain Estimation by System Identification

Willemstein,

van der Kooij,

Sadeghi

2024

Advanced Intelligent Systems

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Integration of both actuation and proprioception into the robot body leads to a single integrated system that can deform and sense. Within this work, liquid rope coiling is used to 3D‐print soft graded porous actuators. By fabricating these actuators from a conductive thermoplastic elastomer, piezoresistive sensing is directly integrated. These sensor‐integrated actuators exhibit nonlinearities and hysteresis in their resistance change. To overcome this challenge, a novel approach that uses identified Wiener–Hammerstein (WH) models is proposed to estimate the strain based on the resistance change. Three actuator types were investigated, namely, a bending actuator, a contractor, and a three degrees of freedom bending segment. By using the design freedom of additive manufacturing to set the porosity, the actuation and sensing behavior of a contracting actuator can be programmed. Furthermore, the WH models can provide strain estimation with on average high fits (83%) and low root mean square (RMS) errors (6%) for all three actuators, which outperformed linear models significantly (76.2/9.4% fit/RMS error). In these results, it is indicated that combining 3D‐printed graded porous structures and system identification can realize sensor‐integrated actuators that can estimate their strain but also tailor their behavior through the porosity.

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Research on high sensitivity piezoresistive sensor based on structural design

Li,

Liu,

Wang

et al. 2024

Discover Nano

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With the popularity of smart terminals, wearable electronic devices have shown great market prospects, especially high-sensitivity pressure sensors, which can monitor micro-stimuli and high-precision dynamic external stimuli, and will have an important impact on future functional development. Compressible flexible sensors have attracted wide attention due to their simple sensing mechanism and the advantages of light weight and convenience. Sensors with high sensitivity are very sensitive to pressure and can detect resistance/current changes under pressure, which has been widely studied. On this basis, this review focuses on analyzing the performance impact of device structure design strategies on high sensitivity pressure sensors. The design of structures can be divided into interface microstructures and three-dimensional framework structures. The preparation methods of various structures are introduced in detail, and the current research status and future development challenges are summarized.

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Additive Manufacturing of Elastomeric Composite Lattices with Thermally Grown Micro‐Architectures for Versatile Applications

Cited by 3 publications

References 54 publications

Multifunctional Polymer-Metal Lattice Composites via Hybrid Additive Manufacturing Technology

Multifunctional Polymer-Metal Lattice Composites via Hybrid Additive Manufacturing Technology

3D‐Printed Soft Proprioceptive Graded Porous Actuators with Strain Estimation by System Identification

Research on high sensitivity piezoresistive sensor based on structural design

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