Your search keyword '"high stiffness"' showing total 803 results

1. Reduction of Friction Loss by Arrangement of the Segment of the Polyimide Arms & Guides for Timing Chains in Automobile Engines

Author

Kento Ito, Satoru Sekiguchi, Yuichi Maruyama, Toshiya Naoe, and Hideaki Seki

Subjects

internal combustion engines, timing chain, polyimide, high stiffness, segment, friction, Physics, QC1-999, Engineering (General). Civil engineering (General), TA1-2040, Mechanical engineering and machinery, TJ1-1570, Chemistry, QD1-999

Abstract

The world cannot counter climate change without the automobile industry becoming far more environmentally sustainable than it is today. With the realization that electrified mobility will take decades, not years, and that internal combustion engines (ICE) will continue to power vehicles in the near future, we need to step up the focus on improving fuel efficiency of ICE vehicles. In this report, we have confirmed that, in timing chains for automobile engines, the sliding area can be reduced by changing the arrangement of the arms & guides from continuous contact to a segmented one and by using an aromatic polyimide (PI) that can withstand the high contact surface pressure, thereby reducing friction loss. Through bench test monitoring, we confirmed that the friction loss was reduced in comparison to that by the conventional arms & guides in ICEs. The conventional arms & guides in the layout of the timing chains are placed with a curvature of ~ R2000 mm (at least R500 mm). In this study, the layout of the arms & guides was investigated. Each arm or guide is divided into two or three segments in the direction of travel and each curvature is reduced to about R100 mm. In addition, the material has been changed from polyamide (PA66) to PI. By these changes, the contact surface is decreased, and the surface pressure is increased. This means that on the Stribeck diagram, the lubrication conditions move in the direction of the smaller Sommerfeld number and the friction loss decreases. The use of the high compressive modulus material reduces the amount of deformation of the arms & guides contact surface, leading to the reduction of the friction loss.

Published

2024

2. All-metal enhanced members with extreme dissipation capacity for vibration suppression of grille structures.

Author

Ji, Shubin, Wang, Jiarui, Wei, Yingjie, and Wang, Cong

Subjects

*OFFSHORE structures, *ENERGY dissipation

Abstract

Marine structures are supposed to simultaneously possess high stiffness bearing high loadings and large damping dissipating dynamic energy. Structural impact protection and stiffening approach is achieved via assembling a pre-compressed negative stiffness component and linear members, which not only exhibits high initial stiffness but also dissipation capacity approaching the theoretical limit under small deformation. The effects of design parameters on the energy dissipation characteristics are investigated by the combination of quasi-static, dynamic and finite element analysis. For potential applications, the dynamic responses and vibration suppression of a representative grille structure optimized by the novel design are studied via FE simulations. [ABSTRACT FROM AUTHOR]

Published

2024

3. A Low-Inertia and High-Stiffness Cable-Driven Biped Robot: Design, Modeling, and Control.

Author

Tang, Jun, Mou, Haiming, Hou, Yunfeng, Zhu, Yudi, Liu, Jian, and Zhang, Jianwei

Subjects

*ROBOT design & construction, *ANKLE joint, *CABLE structures, *HIP joint, *ANKLE, *ELASTIC deformation, *WALKING speed, *JOINTS (Anatomy)

Abstract

In this paper, a biped robot system for dynamic walking is presented. It has two 2-degree-of-freedom (DOF) lightweight legs and a 6-DOF hip. All the joint pulleys of the legs are driven by motors that are placed at the hip using steel cables. Since all the heavy motors are mounted at the hip, the biped robot has remarkably low-mass legs beyond the hip, which guarantees low inertia during walking at high speeds. Utilizing cable-amplification mechanisms, high stiffness and strength are achieved, resulting in better control performance compared to conventional direct-driven methods. Techniques are developed to estimate joint-angle errors caused by the elastic deformation of the cables. To achieve smooth control, we introduce the concept of a virtual leg, which is an imaginary leg connecting the hip joint and the ankle joint. A robust control approach based on the "virtual leg" is presented, which considers the variances of the virtual leg length during walking. Experiments are conducted to validate the effectiveness of the mechanical design and the proposed control approach. [ABSTRACT FROM AUTHOR]

Published

2024

4. Upcycling of HDPE Milk Bottles into High-Stiffness, High-HDT Composites with Pineapple Leaf Waste Materials.

Author

Amornsakchai, Taweechai and Duangsuwan, Sorn

Subjects

*WASTE products, *PINEAPPLE, *HIGH density polyethylene, *PLASTICS, *FLEXURAL strength, *MILK

Abstract

In the pursuit of sustainability and reduced dependence on new plastic materials, this study explores the upcycling potential of high-density polyethylene (HDPE) milk bottles into high-stiffness, high-heat-distortion-temperature (HDT) composites. Recycled high-density polyethylene (rHDPE) sourced from used milk bottles serves as the composite matrix, while reinforcing fillers are derived from dried pineapple leaves, comprising fibers (PALF) and non-fibrous materials (NFM). A two-roll mixer is employed to prepare rHDPE/NFM and rHDPE/PALF mixtures, facilitating filler alignment in the resulting prepreg. The prepreg is subsequently stacked and pressed into composite sheets. The introduction of PALF as a reinforcing filler significantly enhances the flexural strength and modulus of the rHDPE composite. A 20 wt.% PALF content yields a remarkable 162% increase in flexural strength and a 204% increase in modulus compared to neat rHDPE. The rHDPE/NFM composite also shows improved mechanical properties, albeit to a lesser degree than fiber reinforcement. Both composites exhibit a slight reduction in impact resistance. Notably, the addition of NFM or PALF substantially elevates HDT, raising the HDT values of the composites to approximately 84 °C and 108 °C, respectively, in contrast to the 71 °C HDT of neat rHDPE. Furthermore, the overall properties of both the composites are further enhanced by improving their compatibility through maleic anhydride-modified polyethylene (MAPE) use. Impact fracture surfaces of both composites reveal higher compatibility and clear alignment of NFM and PALF fillers, underscoring the enhanced performance and environmental friendliness of composites produced from recycled plastics reinforced with pineapple leaf waste fillers. [ABSTRACT FROM AUTHOR]

Published

2023

5. Type Synthesis of Fully Decoupled Three Translational Parallel Mechanism with Closed-Loop Units and High Stiffness

Author

Shihua Li, Sen Wang, Haoran Li, Yongjie Wang, and Shuang Chen

Subjects

Screw theory, Three translational parallel mechanism, Full decoupled, Closed-loop units, High stiffness, Ocean engineering, TC1501-1800, Mechanical engineering and machinery, TJ1-1570

Abstract

Abstract In order to solve the problem of weak stiffness of the existing fully decoupled parallel mechanism, a new synthesis method of fully decoupled three translational (3T) parallel mechanisms (PMs) with closed-loop units and high stiffness is proposed based on screw theory. Firstly, a new criterion for the full decoupled of PMs is presented that the reciprocal product of the transmission wrench screw matrix and the output twist screw matrix of PMs is a diagonal matrix, and all elements on the main diagonal are nonzero constants. The forms of the transmission wrench screws are determined by the criterion. Secondly, the forms of the actuated and unactuated screws can be obtained according to their relationships with the transmission wrench screws. The basic decoupled limbs are generated by combination of the above actuated and unactuated screws. Finally, a closed-loop units construction method is investigated to apply the decoupled mechanisms in a better way on the high stiffness occasion. The closed-loop units are constructed in the basic decoupled limbs to generate a high-stiffness fully decoupled 3T PM. Kinematic and stiffness analyses show that the Jacobian matrix is a diagonal matrix, and the stiffness is obviously higher than that of the coupling mechanisms, which verifies the correctness of the proposed synthesis method. The mechanism synthesized by this method has a good application prospect in vehicle durability test platform.

Published

2023

6. Type Synthesis of Fully Decoupled Three Translational Parallel Mechanism with Closed-Loop Units and High Stiffness.

Author

Li, Shihua, Wang, Sen, Li, Haoran, Wang, Yongjie, and Chen, Shuang

Abstract

In order to solve the problem of weak stiffness of the existing fully decoupled parallel mechanism, a new synthesis method of fully decoupled three translational (3T) parallel mechanisms (PMs) with closed-loop units and high stiffness is proposed based on screw theory. Firstly, a new criterion for the full decoupled of PMs is presented that the reciprocal product of the transmission wrench screw matrix and the output twist screw matrix of PMs is a diagonal matrix, and all elements on the main diagonal are nonzero constants. The forms of the transmission wrench screws are determined by the criterion. Secondly, the forms of the actuated and unactuated screws can be obtained according to their relationships with the transmission wrench screws. The basic decoupled limbs are generated by combination of the above actuated and unactuated screws. Finally, a closed-loop units construction method is investigated to apply the decoupled mechanisms in a better way on the high stiffness occasion. The closed-loop units are constructed in the basic decoupled limbs to generate a high-stiffness fully decoupled 3T PM. Kinematic and stiffness analyses show that the Jacobian matrix is a diagonal matrix, and the stiffness is obviously higher than that of the coupling mechanisms, which verifies the correctness of the proposed synthesis method. The mechanism synthesized by this method has a good application prospect in vehicle durability test platform. [ABSTRACT FROM AUTHOR]

Published

2023

7. Development and Rotation Characteristics Analysis of a Large-Scale Deployable Arm.

Author

Chen, Huawei, Shi, Chuang, Guo, Hongwei, Liu, Rongqiang, Yin, Dezheng, Ji, Hongjuan, and Deng, Zongquan

Subjects

CENTRIFUGAL force, ROTATIONAL motion, STELLAR rotation, TORQUE

Abstract

In the spin-off acceleration stage during high-speed rotation in space, the deployable arm of the space gravity simulation device must withstand a large axial centrifugal force and a driving torque. In this paper, a large-scale high-speed rotating deployable arm is proposed, and the relevant characteristics during the rotation process are analyzed. A new driving mode of towed deployment is proposed that can lead to the rapid and efficient deployment of a large-scale deployable arm. First, an optimized configuration of a deployable arm is proposed. Second, the deployment driving process of the deployable arm under several different drag driving modes is simulated and analyzed, and a comparative analysis is performed to select a simple and reliable drag deployment driving scheme. Then, the effects of various disturbances on the posture of the deployable arm during the rotation process are explored, guiding the posture control of the deployable arm. Finally, a 10 m four-unit prototype is developed for the stiffness and rotation tests, which verify that the theoretical analysis in this paper is correct. [ABSTRACT FROM AUTHOR]

Published

2023

8. A Low-Inertia and High-Stiffness Cable-Driven Biped Robot: Design, Modeling, and Control

Author

Jun Tang, Haiming Mou, Yunfeng Hou, Yudi Zhu, Jian Liu, and Jianwei Zhang

Subjects

biped robot, cable driven, low inertia, high stiffness, joint-angle error, virtual leg, Mathematics, QA1-939

Abstract

In this paper, a biped robot system for dynamic walking is presented. It has two 2-degree-of-freedom (DOF) lightweight legs and a 6-DOF hip. All the joint pulleys of the legs are driven by motors that are placed at the hip using steel cables. Since all the heavy motors are mounted at the hip, the biped robot has remarkably low-mass legs beyond the hip, which guarantees low inertia during walking at high speeds. Utilizing cable-amplification mechanisms, high stiffness and strength are achieved, resulting in better control performance compared to conventional direct-driven methods. Techniques are developed to estimate joint-angle errors caused by the elastic deformation of the cables. To achieve smooth control, we introduce the concept of a virtual leg, which is an imaginary leg connecting the hip joint and the ankle joint. A robust control approach based on the “virtual leg” is presented, which considers the variances of the virtual leg length during walking. Experiments are conducted to validate the effectiveness of the mechanical design and the proposed control approach.

Published

2024

9. Upcycling of HDPE Milk Bottles into High-Stiffness, High-HDT Composites with Pineapple Leaf Waste Materials

Author

Taweechai Amornsakchai and Sorn Duangsuwan

Subjects

upcycling, HDPE milk bottle, pineapple leaf waste, natural fiber, high stiffness, Organic chemistry, QD241-441

Abstract

In the pursuit of sustainability and reduced dependence on new plastic materials, this study explores the upcycling potential of high-density polyethylene (HDPE) milk bottles into high-stiffness, high-heat-distortion-temperature (HDT) composites. Recycled high-density polyethylene (rHDPE) sourced from used milk bottles serves as the composite matrix, while reinforcing fillers are derived from dried pineapple leaves, comprising fibers (PALF) and non-fibrous materials (NFM). A two-roll mixer is employed to prepare rHDPE/NFM and rHDPE/PALF mixtures, facilitating filler alignment in the resulting prepreg. The prepreg is subsequently stacked and pressed into composite sheets. The introduction of PALF as a reinforcing filler significantly enhances the flexural strength and modulus of the rHDPE composite. A 20 wt.% PALF content yields a remarkable 162% increase in flexural strength and a 204% increase in modulus compared to neat rHDPE. The rHDPE/NFM composite also shows improved mechanical properties, albeit to a lesser degree than fiber reinforcement. Both composites exhibit a slight reduction in impact resistance. Notably, the addition of NFM or PALF substantially elevates HDT, raising the HDT values of the composites to approximately 84 °C and 108 °C, respectively, in contrast to the 71 °C HDT of neat rHDPE. Furthermore, the overall properties of both the composites are further enhanced by improving their compatibility through maleic anhydride-modified polyethylene (MAPE) use. Impact fracture surfaces of both composites reveal higher compatibility and clear alignment of NFM and PALF fillers, underscoring the enhanced performance and environmental friendliness of composites produced from recycled plastics reinforced with pineapple leaf waste fillers.

Published

2023

10. Metal members stiffened by bistable components for the protection of naval architectures under periodic loading.

Author

Ji, Shubin, Wang, Cong, and Fang, Hui

Subjects

ENERGY dissipation, FINITE element method, VIBRATION (Marine engineering), POTENTIAL well, LAMINATED composite beams, NAVAL architecture, POTENTIAL energy

Abstract

Naval architectures are required to simultaneously have high stiffness and high damping to bear periodic loading and suppress resonance that is possibly caused by ship self-excitation vibration. A protection approach, namely, metal members stiffened by bistable components, is proposed. This approach not only achieves high stiffness but also exhibits excellent energy dissipation compared to that of traditional approaches under periodic loading. A two-degree-of-freedom (2-DOF) model of a Euler beam stiffened by a bistable component is derived and characterised by two potential wells. The influence of the structural parameters and energy dissipation mechanisms of the coupled bistable-linear (CBL) beam on the laws of the potential energy wells are studied via theoretical model. In the end, a panel stiffened by optimally designed CBL beams, according to the parametric studies, effectively dissipate the dynamic energy and protect the structure by staying within the elastic range found in the finite element model (FEM). [ABSTRACT FROM AUTHOR]

Published

2023

11. Multi-step snap-through structures with programmable energy dissipation characteristics for vibration suppression of jacket structures.

Author

Ji, Shubin, Wei, Yingjie, Wang, Cong, and Chen, Jianrui

Subjects

*MARINE engineering, *STRUCTURAL engineering, *FINITE element method, *ENERGY dissipation, *MATERIAL plasticity

Abstract

Steel jacket structures exposed to environmental impacts can experience intense dynamic responses, leading to potential localized fatigue failure, plastic deformation, and even catastrophic collapse. Therefore, the jacket structure needs to possess both high stiffness and large damping to cope with impacts and dissipate dynamic energy. A novel damper with programmable mechanical behaviors and damping performance has been designed by using the contact interaction between two columns. Analytical models have been derived to investigate the effect of design parameters on mechanical behaviors and dissipation capacity of the damper and provide guidance for practical applications. Experiments and finite element analysis indicate that the stiffness-damping comprehensive performance of the damper is far superior to the general materials and other nonlinear structures that rely on elastic buckling to achieve energy dissipation. For potential engineering applications, the vibration decay responses of a three-dimensional jacket structure installed with the damper were simulated using ABAQUS software. The results indicate that the damper can serve as a potential candidate for achieving simultaneously high stiffness and large damping in marine engineering structures. • A novel damper with multi-step snap-through energy dissipation enhanced characteristics. • Investigating the complex contact interaction and elastic buckling configurations of columns. • Exploring the engineering applications of the novel damper in the field of vibration suppression. [ABSTRACT FROM AUTHOR]

Published

2024

12. Physically Entangled Antiswelling Hydrogels with High Stiffness.

Author

Ji, Suchun, Li, Xiying, Wang, Shuang, Li, Hongyuan, Duan, Huiling, Yang, Xin, and Lv, Pengyu

Subjects

*CROSSLINKED polymers, *HYDROGELS, *POLYIMIDES, *UNIFORM spaces, *TISSUE engineering, *THREE-dimensional printing, *PYRROLIDINONES

Abstract

Physically cross‐linked hydrogels have great potential for tissue engineering because of their excellent biocompatibility and easy fabrication. However, physical cross‐linking points are typically weaker compared to chemical ones and therefore cannot form robust hydrogels with excellent water stability, which greatly hinder their further applications. In this work, a novel hydrogel with high stiffness and outstanding antiswelling performance cross‐linked by hydrophobic polymer chains entanglements is reported. The hydrophobic polymer polyimide (PI) is mixed with the hydrophilic polymer poly‐(vinyl pyrrolidone) (PVP) to form cross‐linking points between the chains. At the equilibrium swelling state, tensile modulus of the hydrogel can be up to 22.57 MPa (higher than most existing hydrogels) and the equilibrium water swelling ratio (ESR) can be as low as 125.0%. By decreasing the PI mass ratio, tensile modulus and ESR of the hydrogel can be tuned in a wide range from 22.57 to 0.005 MPa and 125.0% to 765.6%, respectively. Using PVP/PI solutions as inks, uniform structures and multi‐material structures are fabricated having mechanical properties close to cartilage through a direct ink writing 3D printing platform. This current work demonstrates that entangled PVP/PI hydrogels have excellent tailoring capabilities and are promising candidates for tissue engineering applications. [ABSTRACT FROM AUTHOR]

Published

2022

13. On high stiffness of soft robots for compatibility of deformation and function.

Author

Hagiwara, Keisuke, Yamamoto, Ko, Shibata, Yoshihisa, Komagata, Mitsuo, and Nakamura, Yoshihiko

Subjects

*SOFT robotics, *ROBOT hands, *OBJECT manipulation, *ROBOTS, *NUMERICAL analysis, *ROBOTICS

Abstract

This study investigates the compatibility between the soft deformation and high stiffness through the development of a soft robotic gripper for a human-scale payload. Softness is important for robotic systems that physically interact with the environments, especially for adaptive grasping or manipulation of unknown objects. Pursuing only softness would not achieve them either, and creating a certain stiffness is also an essential function in many human-scale applications. Soft robotics is unique in that it employs soft materials for the structure, and will find a lot more applications if it gains the human-scale specifications of force or the equivalent stiffness. We discuss the compatibility of the soft deformation and high stiffness based on a numerical analysis, and then present the design of a soft robotic gripper actuated by high oil-pressure, reporting its experimental validations. [ABSTRACT FROM AUTHOR]

Published

2022

14. A High-Stiffness Sandwich Structure with a Tristable Core for Low-Frequency Vibration Isolation.

Author

Fang, Hui, Liu, Ze, Lei, Ming, and Duan, Liya

Subjects

VIBRATION isolation, SANDWICH construction (Materials), VIBRATION (Mechanics), FREQUENCIES of oscillating systems, DYNAMIC stiffness, FINITE element method

Abstract

Background: Typical non-linear vibration isolation systems address the inadequate control of low frequency vibration in linear isolation systems by introducing negative stiffness mechanisms to reduce the overall stiffness of the system and achieve relatively low or zero dynamic stiffness without sacrificing load carrying capacity. In practice, however, adjusting the system stiffness to zero and balancing the loads at the desired equilibrium point can be challenging due to manufacturing and installation defects and changing environments. Purpose: For better application in practical engineering, a simple and easily controlled structure is necessary. This study innovatively designs a sandwich structure with a tristable core comprised of paired columns is innovatively designed to have a high initial stiffness for bearing heavy weights, a quasi-zero intermediate stiffness for isolating vibration and high culminating stiffness for preventing deformation. Method: An experimental prototype of this structure is designed through finite element modelling and fabricated by a 3D printer; then, its variable stiffness is verified. An analytical approach for the post-buckling process is implemented to derive the axial-flexible displacement relation of the tristable pair columns. Averaging and incremental harmonic balance methods are developed to define the relationship between the isolation range and the stiffness characteristics of this tristable system. Results: The lower limit of isolation frequency in this tristable structure is much smaller than that of the linear structure with the same load-bearing capacity. Conclusion: Combining post-buckling and nonlinear dynamic analysis, the design methodology for these sandwich structures is established: according to the excitation, the varied stiffness characteristic of this isolation structure is determined based on nonlinear dynamic analysis; the buckling length and the spacing distance of the pair of beams are determined through post-buckling analysis; and series-parallel pairs of beams can be constructed to fit the dead weight of the equipment and installations. [ABSTRACT FROM AUTHOR]

Published

2022

15. Heavy-load Nonapod: A novel flexible redundant parallel kinematic machine for multi-DoF forming process.

Author

Zheng, Fangyan, Xin, Shuai, Han, Xinghui, Hua, Lin, Zhuang, Wuhao, Hu, Xuan, and Chai, Fang

Subjects

*PARALLEL kinematic machines, *MULTI-degree of freedom, *STANDARD deviations, *LATERAL loads, *BEVEL gearing

Abstract

The high-performance multi-DoF forming process (MDFP) necessitates a 6-DoF forming machine tool with high normal and lateral stiffness to bear large normal and lateral forming force of millions of Newton (MN). However, the payload of parallel kinematic machine (PKM) is generally limited to thousands of Newton (kN), which restricts its application in MDFP. Therefore, this paper aims to develop a novel heavy load PKM with high stiffness for MDFP. To maximise the normal stiffness, a 6-PSS PKM with zero base angle and horizontal driver is proposed. Further, the inner force transfer model of 6-PSS PKM is established, indicating that the normal stiffness will be maximised when the link force approaches to be vertical. Consequently, a design criterion for maximising normal stiffness, i.e., the root mean square error (RMSE) for horizontal projection of all links should be minimised, is established. To maximise the lateral stiffness, general force balance equations of 6-PSS PKM are derived, indicating that lateral force can cause unintended negative force of links, significantly reducing the lateral stiffness. Thus, a novel auxiliary 3-SPS configuration is employed to provide additional force system to mitigate this negative force via hydraulic links. Correspondingly, a design criterion for maximising lateral stiffness, i.e., all link force should remain positive, is proposed. By combining aforementioned design criterion and kinetostatic models, a near-singular 6-PSS PKM with maximising normal stiffness is achieved, and dimension parameters of 3-SPS PKM with maximising lateral stiffness are optimised. On this basis, a novel flexible redundant 6-PSS/3-SPS PKM with both high normal and lateral stiffness is proposed, and a novel heavy load Nonapod with payload of 8 MN and payload-mass ratio of 40 is developed, showing good stiffness performance. The plastic deformation mechanisms of multi-DoF formed aviation bevel gear are revealed, and experimentally formed aviation bevel gear in the new Nonapod achieves good accuracy, microstructure and mechanical performance. This work provides a new methodology for synthesis of heavy load PKM with high normal and lateral stiffness, and has significant application prospect in PKM under heavy load working condition. [Display omitted] • A novel heavy load Nonapod incorporating 6-PSS/3-SPS PKM with payload of 8 MN and payload-mass ratio of 40 is developed. • A novel design criterion for maximising normal stiffness is demonstrated on a near-singular 6-PSS mechanism. • A novel design criterion for maximising lateral stiffness is proposed for a flexible 3-SPS mechanism. • Deformation mechanisms of multi-DoF formed aviation bevel gear are revealed. [ABSTRACT FROM AUTHOR]

Published

2024

16. Development and Rotation Characteristics Analysis of a Large-Scale Deployable Arm

Author

Huawei Chen, Chuang Shi, Hongwei Guo, Rongqiang Liu, Dezheng Yin, Hongjuan Ji, and Zongquan Deng

Subjects

towed deployment, high stiffness, high-speed rotation, mechanical property analysis, prototype development, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

In the spin-off acceleration stage during high-speed rotation in space, the deployable arm of the space gravity simulation device must withstand a large axial centrifugal force and a driving torque. In this paper, a large-scale high-speed rotating deployable arm is proposed, and the relevant characteristics during the rotation process are analyzed. A new driving mode of towed deployment is proposed that can lead to the rapid and efficient deployment of a large-scale deployable arm. First, an optimized configuration of a deployable arm is proposed. Second, the deployment driving process of the deployable arm under several different drag driving modes is simulated and analyzed, and a comparative analysis is performed to select a simple and reliable drag deployment driving scheme. Then, the effects of various disturbances on the posture of the deployable arm during the rotation process are explored, guiding the posture control of the deployable arm. Finally, a 10 m four-unit prototype is developed for the stiffness and rotation tests, which verify that the theoretical analysis in this paper is correct.

Published

2023

17. High-Stiffness Torque Sensor With a Strain Amplification Mechanism for Cooperative Industrial Manipulators.

Author

Kim, Uikyum, Maeng, Chan-Young, Bak, Geonho, and Kim, Yong-Jae

Subjects

*TORQUEMETERS, *STRAIN sensors, *CAPACITIVE sensors, *FLEXURE, *STATISTICAL reliability

Abstract

This study presents a high-stiffness torque sensor with a strain amplification mechanism for cooperative industrial manipulators. A novel strain amplification mechanism for a torque sensor has been designed to increase the stiffness of the sensor. The mechanism has a single structure composed of trapezoidal beams, flexure structures, and inner and outer frames. In this configuration, the displacement that occurs in the beam is amplified by the flexure structure. The amplified displacement is measured using capacitance sensing technology. As a result, the developed torque sensor has a high stiffness (198.7 kN ⋅ m/rad) and compactness (diameter of 110 mm and a thickness of 9.8 mm) that integrates with all the electronics. Additionally, it has a low cost and it is easy to manufacture. Through several experimental setups, we evaluated the sensing performances of the sensor with regard to accuracy, high stiffness, and repeatability. [ABSTRACT FROM AUTHOR]

Published

2022

18. All-metal stiffened members with bistable components for impact protection of naval architectures.

Author

Meng, Xiangjian, Fang, Hui, Li, Dejian, Duan, Liya, and Liu, Yong

Subjects

NAVAL architecture, FREQUENCIES of oscillating systems, POTENTIAL barrier

Abstract

It is desirable for naval architectures to simultaneously bear high force and dissipate dynamic energy. A structural protection approach via a specifically designed all-metal stiffened member with bistable components is proposed, which not only exhibits high stiffness but also an order of magnitude increase in the structural damping compared to that of a traditional member under wave impact. As a typical module, a two-degree-of-freedom model of the Euler beam stiffened by bistable component is derived and characterized as a double-well potential, and the theoretical analysis indicates that a unique combination of this coupled bistable-linear (CBL) module's natural vibration and the bistable components' higher frequency oscillation caused by the potential barrier highly enhances the structural damping. The CBL modules are utilized to stiffen a representative grille structure, which effectively mitigates the slamming response within the elastic range in FEM. [ABSTRACT FROM AUTHOR]

Published

2022

19. Triple-Mechanism Enhanced Flexible SiO 2 Nanofiber Composite Hydrogel with High Stiffness and Toughness for Cartilaginous Ligaments.

Author

Ma Y, Gong J, Li Q, Liu X, Qiao C, Zhang J, Zhang S, and Li Z

Abstract

Hydrogels are widely used in tissue engineering, soft robotics and wearable electronics. However, it is difficult to achieve both the required toughness and stiffness, which severely hampers their application as load-bearing materials. This study presents a strategy to develop a hard and tough composite hydrogel. Herein, flexible SiO 2 nanofibers (SNF) are dispersed homogeneously in a polyvinyl alcohol (PVA) matrix using the synergistic effect of freeze-drying and annealing through the phase separation, the modulation of macromolecular chain movement and the promotion of macromolecular crystallization. When the stress is applied, the strong molecular interaction between PVA and SNF effectively disperses the load damage to the substrate. Freeze-dried and annealed-flexible SiO 2 nanofibers/polyvinyl alcohol (FDA-SNF/PVA) reaches a preferred balance between enhanced stiffness (13.71 ± 0.28 MPa) and toughness (9.9 ± 0.4 MJ m -3 ). Besides, FDA-SNF/PVA hydrogel has a high tensile strength of 7.84 ± 0.10 MPa, super elasticity (no plastic deformation under 100 cycles of stretching), fast deformation recovery ability and excellent mechanical properties that are superior to the other tough PVA hydrogels, providing an effective way to optimize the mechanical properties of hydrogels for potential applications in artificial tendons and ligaments., (© 2024 Wiley‐VCH GmbH.)

Published

2024

20. Multi Degree-of-Freedom Successive Stiffness Increment Approach for High Stiffness Haptic Interaction

Author

Singh, Harsimran, Jafari, Aghil, Ryu, Jee-Hwan, Hasegawa, Shoichi, editor, Konyo, Masashi, editor, Kyung, Ki-Uk, editor, Nojima, Takuya, editor, and Kajimoto, Hiroyuki, editor

Published

2018

21. Research on combination of passive magnetic bearing and mechanical bearing for vertical axis wind turbine.

Author

Jun, Zhu, Zhenyi, Zhang, Di, Cao, Shaotong, Du, Xiangwei, Guo, Penghui, Liu, and Ming, Yang

Abstract

Aiming at the "light wind start, light wind power generation" of vertical axis wind turbine, a new T-shaped radial passive magnetic bearing with high suspension characteristics is proposed. Passive magnetic bearings used in vertical axis wind turbines usually have small bearing capacity and difficult magnetization. The new T-shaped radial PMB can improve the radial bearing capacity, and the three magnetic rings all adopt simple axial magnetization. The new T-shaped radial PMB is combined with mechanical auxiliary bearing to form the suspension system of wind turbine. In the stable state, the suspension system can realize radial and axial stable suspension. The structure and working principle of the suspension system are briefly described. Through the finite element simulation, the characteristics of the new T-shaped radial PMB, the traditional double-ring PMB and the T-shaped PMBs are compared. Taking the high bearing capacity and high stiffness of the new T-shaped radial PMB as the optimization objective, the multi-objective optimization of the new T-shaped radial PMB was carried out by changing its geometric parameters (inner diameter, magnetization length and air gap). The research results show that: Under the same bearing capacity, the volume of the new T-shaped radial PMB is reduced by about 78.64%. Under the same volume, its bearing capacity increased by about 30.7%, and its stiffness increased by about 96.1%. After optimization, its radial bearing capacity increased to 101.38 N, and its stiffness increased to 202.76 N/mm. [ABSTRACT FROM AUTHOR]

Published

2021

22. Composite tree-like re-entrant structure with high stiffness and controllable elastic anisotropy.

Author

Gao, Ying, Wu, Qianqian, Wei, Xingyu, Zhou, Zhengong, and Xiong, Jian

Subjects

*AUXETIC materials, *ELASTICITY, *POISSON'S ratio, *ISOTROPIC properties, *MODULUS of rigidity, *YOUNG'S modulus, *STIFFNESS (Engineering)

Abstract

• A class of novel auxetic lattice structures with high stiffness based on the stretchdominant concept has been proposed. • The new concept of structures shows excellent stiffness and obvious negative Poisson's ratio effect along omni-direction. • The tree-like re-entrant structure exhibits controlled anisotropic elastic properties. • Isotropic elasticity with negative Poisson's ratio between -1 and 0 is achievable. Critical drawback of poor stiffness in traditional auxetic materials limits them to be applied where negative Poisson's ratio behavior and excellent load-bearing capacity are simultaneously desired. In this work, a general prescription for designing auxetic lattice structures with high stiffness and controllable isotropic/anisotropic elastic properties is proposed. Based on it, we rationally design a class of novel auxetic lattice structures whose deformation is mainly governed by the stretching mechanisms and conducted an investigation on a tree-like re-entrant structure. A combination of theoretical predictions, numerical simulations and tensile test experiments have been carried out to gain a comprehensive understanding of the structural in-plane elastic mechanical properties along both the principal axes as well as in the off-axis directions. Besides, theoretical model for designing tree-like re-entrant structure with isotropic elastic properties is established and experimentally verified with specimens fabricated with CFRP composite. The results of this research has proven the tree-like re-entrant structure exhibits excellent effective Young's modulus, shear modulus and obvious negative Poisson's ratio effect along omni-direction. Investigation on the directional dependence of structural effective elastic properties has further indicated the proposed structure presents a great potential for designing auxetic material with controllable anisotropic elastic properties. In particular, the proposed structure is capable in achieving isotropic design with any negative Poisson's ratio between −1 and 0. The design philosophy presented in this paper provides a general prescription for solving the challenge of poor stiffness in traditional auxetic materials and paves a new way for isotropic auxetic design. [ABSTRACT FROM AUTHOR]

Published

2020

23. Shape-morphing carbon fiber composite using electrochemical actuation.

Author

Johannisson, Wilhelm, Harnden, Ross, Zenkert, Dan, and Lindbergh, Göran

Subjects

*CARBON composites, *FIBROUS composites, *CARBON fibers, *COMPOSITE materials, *LOW voltage systems

Abstract

Structures that are capable of changing shape can increase efficiency in many applications, but are often heavy and maintenance intensive. To reduce the mass and mechanical complexity solid-state morphing materials are desirable but are typically nonstructural and problematic to control. Here we present an electrically controlled solid-state morphing composite material that is lightweight and has a stiffness higher than aluminum. It is capable of producing large deformations and holding them with no additional power, albeit at low rates. The material is manufactured from commercial carbon fibers and a structural battery electrolyte, and uses lithiumion insertion to produce shape changes at low voltages. A proof-of concept material in a cantilever setup is used to show morphing, and analytical modeling shows good correlation with experimental observations. The concept presented shows considerable promise and paves the way for stiff, solid-state morphing materials. [ABSTRACT FROM AUTHOR]

Published

2020

24. A Novel Piezoelectric Stack for Rotary Motion by d15 Working Mode: Principle, Modeling, Simulation, and Experiments.

Author

Yu, Hongpeng, Liu, Yingxiang, Deng, Jie, and Zhang, Shijing

Abstract

A novel piezoelectric stack for rotary motion using d15 working mode is proposed, fabricated, and tested in this article to achieve the high stiffness and high precision of rotation. This piezoelectric stack is fabricated by bonding process from only two components—lead zirconate titanate ceramics and electrodes, which is beneficial to realize the simple structure. A theoretical model based on the shear deformation theory is established to predict the static output performances. And the simulation with the finite-element method is adopted to evaluate the dynamic characteristics. An experimental system is built to verify the design and study the performances of the piezoelectric stack. The experimental results indicate that the static output angle changes from −13.25 to +13.33 μrad, whereas the exciting voltage changes from −300 to +300 V, with good linear relationship and high repeatability accuracy. Under the condition of changing the exciting voltage by the step of 0.5 V, the stable resolution is measured to be higher than 0.022 μrad. The large load capacity and width frequency response are verified, which reflect the high stiffness of the proposed piezoelectric stack. The proposed piezoelectric stack achieves accurate and stable rotary output motion with high resolution, rapid response, and large load capacity. Besides, the stack has regular shape and simple structure, and therefore, it is suitable to be integrated in the equipment in the fields of micro–nano manipulations, piezoelectric ultrasonic motors, etc. [ABSTRACT FROM AUTHOR]

Published

2020

25. Co-actuation: Achieve High Stiffness and Low Inertia in Force Feedback Device

Author

Song, Jian, Zhang, Yuru, Zhang, Hongdong, Wang, Dangxiao, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Bello, Fernando, editor, Kajimoto, Hiroyuki, editor, and Visell, Yon, editor

Published

2016

26. The Design and Implementation of a High-Precision Positioner Fixture

Author

Xuesen Zhao, Rongkai Tan, Zhe Wang, Xicong Zou, Zhenjiang Hu, and Tao Sun

Subjects

positioner fixture, high-precision, repeated positioning accuracy, high stiffness, Mechanical engineering and machinery, TJ1-1570

Abstract

In this paper, a novel positioner fixture with a high repeated positioning accuracy and a high stiffness is proposed and investigated. A high-precision end-toothed disc is used to achieve the high repeated positioning accuracy of the designed positioner fixture. The mathematical models of the cumulative error of the tooth pitch, the tooth alignment error and the error of the tooth profile half-angle of the end-toothed disc are analyzed. The allowable tolerance values of the cumulative error of the tooth pitch, the tooth alignment error and the error of the tooth profile half-angle of the end-toothed disc are given. According to the theoretical calculation results, a prototype positioner fixture is fabricated and its repeated positioning accuracy and stiffness are tested. The test results indicate that the stiffness of the proposed positioner fixture is 1050.5 N/μm, which is larger than the previous positioner fixtures of the same type. The repeated positioning accuracy of the proposed positioner fixture in the x, y and z directions are ±0.48 μm, ±0.45 μm and ±0.49 μm, respectively, which is significantly higher than the previous positioner fixtures.

Published

2021

27. Self-Locking Pneumatic Actuators Formed from Origami Shape-Morphing Sheets.

Author

Kim J and Bae J

Abstract

The art of origami has gained traction in various fields such as architecture, the aerospace industry, and soft robotics, owing to the exceptional versatility of flat sheets to exhibit complex shape transformations. Despite the promise that origami robots hold, their use in high-capacity environments has been limited due to the lack of rigidity. This article introduces novel, origami-inspired, self-locking pneumatic modular actuators (SPMAs), enabling them to operate in such environments. Our innovative approach is based on origami patterns that allow for various types of shape morphing, including linear and rotational motion. We have significantly enhanced the stiffness of the actuators by embedding magnets in composite sheets, thus facilitating their application in real-world scenarios. In addition, the embedded self-adjustable valves facilitate the control of sequential origami actuations, making it possible to simplify the pneumatic system for actuating multimodules. With just one actuation source and one solenoid valve, the valves enable efficient control of our SPMAs. The SPMAs can control robotic arms operating in confined spaces, and the entire system can be modularized to accomplish various tasks. Our results demonstrate the potential of origami-inspired designs to achieve more efficient and reliable robotic systems, thus opening up new avenues for the development of robotic systems for various applications.

Published

2024

28. All-metal brace with hysteresis dissipation for impact protection of jacket platforms.

Author

Wang, Shuqing, Meng, Xiangjian, Ji, Shubin, Fang, Hui, Liu, Yong, and Duan, LiYa

Subjects

*OFFSHORE structures, *MARINE engineering, *FINITE element method, *IMPACT loads, *IMPACT response, *HYSTERESIS

Abstract

Environmental impact loading can seriously damage marine structures; thus, it is desirable for structural components to simultaneously bear high force and dissipate dynamic energy. However, the damping properties of structural metals are very low. This paper proposes a structural damping approach via a specifically designed all-metal brace, in which a combination of an asymmetric column with a multistable equilibria (MEQ) mechanism creates a flag-shaped hysteretic loop with an initial modulus similar to that of the parent metal material. The mechanical behavior of the brace is predicted by finite element modeling (FEM). An analytical model is presented for explaining the hysteretic dissipation induced by multistable modes that are transformed through mixed boundary conditions; these hysteretic dissipation behaviors are validated by FEM. A parametric study conducted on the geometric properties illustrates the flexible design of the stiffness and damping configurations of the MEQ brace. The proposed brace effectively mitigates the impact response of a representative jacket platform within the elastic range in the simulation, which utilizes three-dimensional FEM combined with the user-defined material (UMAT) code in ABAQUS. A brace with the MEQ feature is an effective alternative for obtaining high structural stiffness and enhancing damping in marine engineering. • An metal brace with mutli-stable equilibria mechanism introduce hysteretic damping with high modulus. • The transformation of mutli-stable equilibria is predicted by application of an analysis and finite element model (FEM). • Parametric studies using FEM clarify the influence of different geometric properties on the behavior of module. • The proposed brace effectively mitigate the impact response of a schematic jacket platform utilized 3-D FEM. [ABSTRACT FROM AUTHOR]

Published

2019

29. Carbon fiber reinforced shape memory epoxy composites with superior mechanical performances.

Author

Liu, Yayun, Guo, Yufeng, Zhao, Jun, Chen, Xiaodong, Zhang, Hui, Hu, Guoqing, Yu, Xiang, and Zhang, Zhong

Subjects

*SHAPE memory polymers, *CARBON fibers, *EPOXY resins, *CONSTRUCTION materials, *SMART materials, *AIR flow

Abstract

For the shape memory polymers' (SMPs) applications in demanding, high performance scenarios are usually limited by their poor mechanical performances during shape transformation. In this work, shape memory epoxy composites (SMEPCs) with superior mechanical properties are fabricated by adding various short and continuous carbon fibers (CFs) into neat shape memory epoxies (SMEPs) matrix. The resultant SMEPC's storage modulus (E ') at room temperature is as high as 37 GPa, and the maximum recovery force exceeds 4.4 GPa, with good shape memory capabilities. These properties are at least an order of magnitude higher than those in existing typical SMP systems. The excellent mechanical properties of the fibers and their ability to retard crack propagation in the matrix are believed to play an important role in achieving high moduli below and above the shape-memory triggering temperature. The potential applications of such SMEPCs are demonstrated with wind blades. Experimental results and numerical models regarding air flow velocity variation as initiated by shape change in the blades indicate that our SMEPCs can sustain continuous stable mechanical state and provide variable wind speeds. These CF reinforced SMEPCs can be employed as smart structural materials to automatically switch shapes in response to the change in environment, such as those seen in aero foils and energy harvesters. [ABSTRACT FROM AUTHOR]

Published

2019

30. Design optimization of high-precision aerostatic equipment based on orifice restriction.

Author

Lai, Tao, Peng, Xiaoqiang, Liu, Junfeng, Guan, Chaoliang, Chen, Xiaogang, Tie, Guipeng, and Guo, Meng

Abstract

The aerostatic lubrication model with orifice restriction is built based on finite difference method. The model is solved by combination of flux-error feedback and optimization of grids parameter. The stiffness of aerostatic bearing can be improved by reducing the diameter of the orifice, but the optimum working gas gap is reduced and the processing difficulty of surface throttle is improved. The experiments of load and stiffness are carried out on the slider (50 × 50 mm) with the diameter of orifice at 50 µm. The experimental results and theoretical calculation are in good agreement; thus, the model is verified. The structural parameter of two, three, and four orifice gas-bearings is optimized, respectively, based on the proposed model, and the optimum positions of the orifices are obtained. According to the results, the aerostatic bearing guideways, made up of optical material (K9), are manufactured by some optical ways, and the lubrication of the small gas gap is guaranteed; meanwhile, the straightness accuracy of the aerostatic bearing guideways is 0.1 µm/200 mm. The analysis result verifies that the calculation method and the aerostatic lubrication model are significant to the design of high-precision aerostatic equipment. [ABSTRACT FROM AUTHOR]

Published

2019

31. Tristable property and the high stiffness analysis of Kresling pattern origami.

Author

Wang, Xiaolei, Qu, Haibo, and Guo, Sheng

Subjects

*ORIGAMI, *METAMATERIALS, *MATHEMATICAL models

Abstract

• Tristable property of Kresling pattern origami is proposed. • The truss model is corrected based on the tristable property and an established mathematical model. • Energy landscape analysis using the corrected truss model validates the tristable property. • Origami-inspired structures are designed, and the high stiffness of the third stable state is validated. Kresling pattern origami is known for its bistable property, as confirmed by the truss model used to analyze its dynamics. However, our theoretical research and folding experiments reveal that the Kresling pattern origami possesses three stable states during folding motion, with the third state exhibiting high stiffness. These represent exciting new achievements for origami research. Here, Kresling pattern origami is studied using the geometric definitions of triangulated cylindrical origami and triangulated conical origami, and the truss model is corrected based on the proposed tristable property and an established mathematical model of the third stable state. Analysis of the energy landscapes obtained from the corrected truss model reveals various properties of the Kresling pattern origami that confirm its tristable property. In addition, origami-inspired structures are created that exhibit excellent deployability, collapsibility, load-bearing capacity, and multistability. Thereafter, the high stiffness of the third stable state is validated experimentally. These studies can provide new content for constructing multistable metamaterials and improving the load-bearing capacity of deployable structures. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

32. Design and Analysis of a Novel 2T2R Parallel Mechanism with the Closed-loop Limbs

Author

Fang, Hai-Rong, Liu, Peng-Fei, Yang, Hui, and Jiang, Bing-Shan

Published

2021

33. Fabrication of high-stiffness fiber-metal laminates and study of their behavior under low-velocity impact loadings.

Author

Lee, Dong-Woo, Park, Byung-Jin, Park, Sang-Yoon, Choi, Chi-Hoon, and Song, Jung-Il

Subjects

*CARBON fibers, *GLASS fibers, *METAL fibers, *LAMINATED materials, *AUTOCLAVES, *MECHANICAL behavior of materials

Abstract

This study investigates the impact behavior of fiber-metal laminates (FMLs) (Carbon FMLs and Glass FMLs), which were fabricated by using high-stiffness steel, carbon prepreg, and glass prepreg through autoclave molding. The mechanical behavior of the FMLs was evaluated by performing tensile, compressive, in-plane shear, and low-velocity impact tests. Drop-weight impact tests were conducted to induce cracking of the FMLs, and the crack initiation along with crack propagation behavior of the different laminate sequences ([0/0], [0/90], [0/90/0], [90/0/90] and [0/90/90/0]) were also studied. The results show that the fabricated FMLs have higher strength and stiffness than conventional FMLs. Their impact strengths increased, and weights decreased simultaneously. The absorption energy was proportional to the crack length that was induced by the low-velocity impact. Moreover, it was found that the fiber orientation mainly affected the direction of crack propagation in the FMLs. This investigation facilitates the design of high-stiffness and lightweight FMLs for automotive parts. [ABSTRACT FROM AUTHOR]

Published

2018

34. 敏捷卫星高刚度太阳翼的设计与验证.

Author

刘志全, 吴跃民, and 马静雅

Subjects

*HINGES, *ARTIFICIAL satellites, *TORQUE, *SPRING, *MODAL analysis

Abstract

Based on the problem analysis about the current auxiliary support solar wings applied on the agile satellites， the configuration design and layout optimization of the solar wing on the agile satellites are conducted and a single-arm support high-stiffness solar wing is designed by using the spring hinges and adaptive locking hinges. The rod length matching problem existing in the folded configuration of the multi-linking closed-loop mechanism is solved with the deformable characteristic of the spring hinge located in middle of the support arm. Another technical problem about the over-constrained locking at the final step of deployment is solved with the adaptive characteristic of the locking hinges located at the root of this solar wing, thus realizing the reliable locking function of the root hinges in auxiliary support solar wings. The static torque margin, modal analysis and dynamics analysis of this deployable solar wing are respectively conducted. The analysis results show this solar wing has a static torque margin larger than 1，a fundamental frequency in deployed configuration larger than 8 Hz, a smooth deployment process without dead point and a locking impact force within 750 N. The ground test and the on-orbit flight verification of this solar wing are both carried out, which show this highstiffness solar wing is capable of meeting the long-lasting and rapid-maneuvering application requirements for the agile satellites. [ABSTRACT FROM AUTHOR]

Published

2019

35. Augmentation of low frequency damping via hydrogen-doping in a hybrid shape memory alloy composite

Author

Reginald F. Hamilton, Avery D. Brown, Shashank Nagrale, and Charles E. Bakis

Subjects

Carbon fiber reinforced polymer, Materials science, Hydrogen, Mechanical Engineering, Doping, Composite number, chemistry.chemical_element, High stiffness, Shape-memory alloy, Low frequency, chemistry, Nickel titanium, General Materials Science, Composite material

Abstract

Carbon fiber reinforced polymer (CFRP) composites hybridized with hydrogen-doped NiTi wires can be used to design structures requiring high stiffness and high damping in the low frequency range, such as helicopter blades. The current work investigates aging and hydrogen-doping for high damping without hydrogen embrittlement. We establish a hydrogenation treatment that (i) results in a response that is repeatable in the martensitic phase and after exposure to composite processing temperatures and (ii) increases the loss factor in NiTi wires by nearly 470%. By embedding H-doped wires exhibiting the highest damping into the interlayers of a [0/±45]s carbon/epoxy laminate at a volume fraction of 0.1, the hybrid NiTi-CFRP composite loss factor increases by 170%. The measured dynamic properties were found to be close to micromechanical predictions based on the properties of the NiTi and CFRP.

Published

2021

36. Mechanical response and failure mechanism of three-dimensional braided composites under various strain-rate loadings by experimental and simulation research: a review

Author

Ping Wang, Yuanyuan Li, Yan Zhang, Chengming Yue, and Zhimei Chen

Subjects

Materials science, Polymers and Plastics, business.industry, Failure mechanism, High stiffness, 02 engineering and technology, Strain rate, 021001 nanoscience & nanotechnology, 020303 mechanical engineering & transports, 0203 mechanical engineering, Chemical Engineering (miscellaneous), Composite material, 0210 nano-technology, Aerospace, business

Abstract

The high stiffness and great strength of three-dimensional (3D) braided composites mean they are widely used in the aerospace, marine and automotive industries. Three-dimensional braided composites exhibit very different mechanical responses under various strain-rate loadings (such as tensile, compression, punch and shearing) due to their complex structural characteristics. Studies under quasi-static and low strain-rate loadings predict the elasto-plastic properties of 3D braided composites, and research under high strain-rate loading has explored the conditions of industrial composites used in special environments. The investigation of the strain-rate effect can provide a sound database reference for engineering design. Through experiments and simulation analysis methods, this work reviews the braided structural effect, mechanical response and failure mechanism of 3D braided composites under various strain rates. Mechanical properties under different theoretical and structural models are reviewed and summarized. In particular, the damage evolution and stress propagation of 3D braided composites were revealed from both macroscopic and microscopic perspectives through finite element modeling.

Published

2021

37. Carbon fiber–aluminum sandwich for micro-aerial vehicles and miniature robots

Author

Thomas J. Celenza, Wujoon Cha, Igor Bargatin, Cynthia Sung, Luke Kasper, George A. Popov, Mark Yim, Matthew F. Campbell, and Jeremy Wang

Subjects

chemistry.chemical_classification, Materials science, Mechanical Engineering, chemistry.chemical_element, Flexural rigidity, High stiffness, Epoxy, Polymer, Condensed Matter Physics, chemistry, Flexural strength, Mechanics of Materials, Aluminium, visual_art, visual_art.visual_art_medium, Robot, General Materials Science, Millimeter, Composite material

Abstract

We present carbon-fiber and aluminum sandwich plates with millimeter thicknesses that exhibit high stiffness- and strength-to-weight ratios. These composites consist of carbon-fiber-reinforced polymer faces and waterjet-cut aluminum cores, bonded using epoxy. Relative to single-ply carbon-fiber-reinforced polymer sheets, this construction provides 22-fold increases in mass-specific flexural rigidity and 18-fold increases in mass-specific flexural strength, with areal densities of only 120–260 mg/cm2. Our work represents a simple and inexpensive platform for creating extremely lightweight structural components for microflyers and small robots.

Published

2021

38. Development of rotary table grinding machine for large diameter Si wafers (2nd report: Performance investigation of wheel spindle designed to govern infeed motion)

Author

Jumpei KUSUYAMA, Ayumu HONDA, Shintaro IWAHASHI, Takayuki KITAJIMA, Akinori YUI, Toshihiro ITO, Xiaodong LU, and Alexander H. SLOCUM

Subjects

rotary grinding machine, large-diameter si wafer, magnetic actuator, high stiffness, wheel spindle, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Si wafer diameter tends to be increased from 300 mm to 450 mm in order to increase semiconductor device productivity. To this end, the authors developed a rotary grinding machine with high stiffness, equipped with water hydrostatic bearings. This grinding spindle is designed to govern infeed motion of the grinding wheel. This study investigates the basic design and performance of the grinding spindle system. This system itself is composed of a constant pressure water hydrostatic bearing as a radial bearing and a magnetic actuator as a thrust bearing. The magnetic actuator combine the infeed device and the thrust bearing. The measured results show that the static stiffness, Ks, is 1.06 kN/μm, the natural frequency is 353 Hz, and the positioning accuracy is 0.2 μm. These results meet the performance requirements necessary to grind φ450 mm Si wafer.

Published

2017

39. A modified physical model of high-strength water hydraulic artificial muscles considering the effects of geometry and material properties

Author

Che Jinkai, Zengmeng Zhang, Yongjun Gong, Peipei Liu, and Jia Yunrui

Subjects

0209 industrial biotechnology, 020901 industrial engineering & automation, Materials science, Pneumatic artificial muscles, Mechanical Engineering, High stiffness, Artificial muscle, 02 engineering and technology, Composite material, 021001 nanoscience & nanotechnology, 0210 nano-technology, Material properties, Rapid response

Abstract

Compared with pneumatic artificial muscles (PAMs), water hydraulic artificial muscles (WHAMs) have the advantages of high force/weight ratio, high stiffness, rapid response speed, large operating pressure range, low working noise, etc. Although the physical models of PAMs have been widely studied, the model of WHAMs still need to be researched for the different structure parameters and work conditions between PAMs and WHAMs. Therefore, the geometry and the material properties need to be considered in models, including the wall thickness of rubber tube, the geometry of ends, the elastic force of rubber tube, the elongation of fibers, and the friction among fiber strands. WHAMs with different wall thickness and fiber materials were manufactured, and static characteristic experiments were performed when the actuator is static and fixed on both ends, which reflects the relationship between contraction force and pressure under the different contraction ratio. The deviations between theoretical values and experimental results were analyzed to investigate the effect of each physical factor on the modified physical model accuracy at different operating pressures. The results show the relative error of the modified physical model was 7.1% and the relative error of the ideal model was 17.4%. When contraction ratio is below 10% and operating pressure is 4 MPa, the wall thickness of rubber tube was the strongest factor on the accuracy of modified model. When the WHAM contraction ratio from 3% to 20%, the relative error between the modified physical model and the experimental data was within ±10%. Considering the various physical factors, the accuracy of the modified physical model of WHAM is improved, which lays a foundation of non-linear control of the high-strength, tightly fiber-braided and thick-walled WHAMs.

Published

2021

40. Influence of stitching on the out-of-plane behavior of composite materials – A mechanistic review

Author

Rani W. Sullivan, Andrew E. Lovejoy, Daniel A. Drake, Dawn C. Jegley, and Stephen B. Clay

Subjects

Materials science, business.industry, Mechanical Engineering, High stiffness, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Image stitching, Out of plane, Mechanics of Materials, Hardware_INTEGRATEDCIRCUITS, Materials Chemistry, Ceramics and Composites, Fracture (geology), Polymer composites, Composite material, 0210 nano-technology, Aerospace, business, ComputingMethodologies_COMPUTERGRAPHICS

Abstract

Fiber-reinforced polymer composites are widely used in the aerospace industry due to their high stiffness and strength-to-weight ratios. However, their applicability can be limited by their relatively low interlaminar properties when compared to metallic alternatives. Through-thickness reinforcement approaches, such as stitching, z-pinning, needling, tufting, and three-dimensional weaving, have been developed in recent decades to enhance the interlaminar properties of composites. Stitching is considered to be an efficient and cost-effective method to reinforce composites in the through-thickness direction. Additionally, stitch parameters (stitch density, linear thread density, thread material, pretension, etc.) highly influence the in-plane and out-of-plane properties. This paper summarizes results from over one hundred papers on the influence of stitch parameters on fracture energy, interlaminar strength, and impact characteristics of stitched composite laminates, sandwich composites, and high-temperature composites. Much of the research on the influence of stitch parameters has focused on thermoset polymer matrix composites (PMCs), while fewer studies have investigated the impact of stitch parameters on high temperature or sandwich composites. Modification of existing and new test methods have been developed to adequately measure the effectiveness of stitching on the out-of-plane behavior of PMC panels. Results demonstrate that out-of-plane properties of PMCs are highly dependent on stitch parameters and can be enhanced by through-thickness stitching.

Published

2021

41. Deflection and failure of high-stiffness cantilever retaining wall embedded in soft rock

Author

Kuanasegarm, Vijayakanthan, TAKEMURA, JIRO, and Seki, Sake

Subjects

Centrifuge, Cantilever, Materials science, Deflection (engineering), Ultimate failure, Geotechnical engineering, High stiffness, Geotechnical Engineering and Engineering Geology, Retaining wall

Abstract

In this study, a centrifuge modelling system has been developed, in which the loading process from design conditions to the ultimate failure conditions can be simulated on an embedded wall in soft rock at a constant centrifugal (50g) acceleration. Soft sand rock was artificially modelled by using a sand−cement−clay mixture. In-flight excavation and the lateral loading processes were simulated by means of draining water from the wall front and feeding water to the retained soil side, respectively. Two centrifuge model tests have been carried out to investigate the influence of embedment depth on the stability of large-stiffness cantilever walls having flexural rigidity equivalent to a 2·5 m steel tubular pile wall. The results observed reveal that the wall can stand in the design condition with relatively small embedment depth, and provides a reasonable safety margin against ultimate failure. The stiff cantilever walls move by rigid-body rotation about a pivot point under ultimate loads, and a small increment in the embedment depth – for example, 20% – can significantly increase the stability of the wall considered in this study. A compression failure of the embedded medium at the shallow wall front and a shear wedge failure at the wall back from the wall toe were observed.

Published

2021

42. The Problem of Early Crack Detection in the Runner Blades of Hydraulic Units

Author

E. V. Georgievskaia

Subjects

Computer science, business.industry, Mechanical Engineering, Service life, Crack initiation, Fracture mechanics, High stiffness, Structural engineering, Safety, Risk, Reliability and Quality, Diagnostic system, business, Fatigue limit, Industrial and Manufacturing Engineering

Abstract

The initiation and growth of fatigue cracks in the runner blades of hydraulic units is one of the major causes that limit their service life. Practice shows that the current diagnostic systems for hydraulic units do not permit timely identification of cracks in the operating equipment. The data from the numerical experiment demonstrate that high stiffness and the existence of particular eigenmodes in the structure do not enable the dynamic stresses in the blades responsible for crack initiation to be linked to the parameters controlled by the diagnostic system. Analytical approaches based on evaluation of the fatigue strength and fracture mechanics can help solve this problem.

Published

2021

43. Mechano-Induced Assembly of a Nanocomposite for 'Press-N-Go' Coatings with Highly Efficient Surface Disinfection

Author

Xin Huang, Sheng Chen, Bo Yi, Chen Xu, Xi Yao, Youngjin Lee, Changshun Hou, and Chunyan Cao

Subjects

Nanocomposite, Materials science, Surface Properties, Nanocomposite coating, Nanotechnology, High stiffness, 02 engineering and technology, Adhesion, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Durability, Anti-Bacterial Agents, Nanocomposites, 0104 chemical sciences, Disinfection, Coating, Drug Resistance, Bacterial, Healthcare settings, engineering, General Materials Science, Shear Strength, 0210 nano-technology, Rapid response

Abstract

Using antimicrobial coatings to control the spread of pathogenic microbes is appreciated in public and healthcare settings, but the performance of most antimicrobial coatings could not fulfill the increasing requirements, particularly the ease of preparation, high durability, rapid response, and high killing efficiency. Herein, we develop a new type of mechano-induced assembly of nanocomposite coating by simple "Press-N-Go" procedures on various substrates such as glassware, gloves, and fabrics, in which the coating shows strong adhesion, high shear stability, and high stiffness, making it durable in daily use to withstand common mechanical deformation and scratches. The coating also shows remarkable disinfection effectiveness over 99.9% to clinically significant multiple drug-resistant bacterial pathogens upon only 6 s near-infrared irradiation, which can be further improved to over 99.9999% upon another 6 s treatment. We envision that the coating can provide convenience and values to control pathogen spread for easily contaminated substrates in high-risk areas.

Published

2021

44. Modified IWO algorithm for topological optimum synthesis of the displacement amplifying compliant mechanism

Author

MohammadZadeh and SM Varedi-Koulaei

Subjects

Physics, 0209 industrial biotechnology, 020901 industrial engineering & automation, Mechanical Engineering, Topology optimization, 0202 electrical engineering, electronic engineering, information engineering, Compliant mechanism, 020201 artificial intelligence & image processing, Displacement (orthopedic surgery), High stiffness, 02 engineering and technology, Topology, Industrial and Manufacturing Engineering

Abstract

The conventional mechanisms transmitted force and displacement through rigid members (high stiffness) and traditional joints (with high softness), where recently, researchers have come up with new systems called compliant mechanisms that transfer power and mobility through the deformation of their flexible members. One of the most frequently used approaches for designing compliant mechanisms is topology optimization. Extracting the optimal design of a displacement amplifying compliant mechanism using the modified Invasive Weed Optimization (MIWO) method is the current study's main novelty. The studied mechanism is a compliant micro-mechanism that can be used as a micrometric displacement amplifier. The goal of this synthesis is to maximize the output-to-input displacement ratio. In this research, a new random step is added to the Invasive Weed Optimization (IWO) method; the new seeds can be spread farther from their parents, which can be improved the algorithm's abilities. The results show that the use of the modified IWO algorithm for this problem has led to a significant improvement over the results from similar articles.

Published

2021

45. Dynamic behaviors of composite leaf springs with viscoelastic cores

Author

Saman Jolaiy, Mahmoud Mousavi Mashhadi, Mohammadreza Amoozgar, Mahdi Bodaghi, Armin Yousefi, and Bodaghi, M

Subjects

Materials science, Mechanical Engineering, General Mathematics, Composite number, Aerospace Engineering, Ocean Engineering, High stiffness, Condensed Matter Physics, Viscoelasticity, Specific strength, Mechanics of Materials, Spring (device), Leaf spring, Automotive Engineering, Impact energy absorption, Composite material, Suspension (vehicle), Civil and Structural Engineering

Abstract

A leaf spring is a simple form of spring commonly used for the suspension in wheeled vehicles. Due to their high strength to weight ratio, high stiffness, and high impact energy absorption, fiber-reinforced composite leaf springs gain considerable interest recently as a potential alternative to conventional leaf springs with relatively high weight. In the present study, a novel composite leaf spring consists of two composite face layers, and a soft and flexible viscoelastic core is proposed. Employing viscoelastic materials in structures reduces undesirable vibrations leading to fatigue and damage of structures. A numerical method is used to design and analyze composite leaf springs with a viscoelastic core using the Abaqus software package. Results are compared with those from well-known analytical methods, finite element methods, and experiments. Results show that the proposed novel composite leaf spring can withstand the stresses caused by static and impact forces, reduce post-impact vibrations, and prevent undesirable system vibrations. The viscoelastic layer increases the strain energy capacity of proposed composite leaf springs compared to conventional composite leaf springs and enhances the composite leaf spring performance against bump impact.

Published

2021

46. Kinematics analysis and performance testing of 6-RR-<u>RP</u>-RR parallel platform with offset RR-hinges based on Denavit-Hartenberg parameter method

Author

Yang Yu, Zhenbang Xu, A-long Mao, Hasiaoqier Han, Yang Zhang, Qingwen Wu, and Chunyang Han

Subjects

0209 industrial biotechnology, Offset (computer science), Mechanical Engineering, Hinge, High stiffness, 02 engineering and technology, Kinematics, Denavit–Hartenberg parameters, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, 0203 mechanical engineering, Control theory, ComputingMethodologies_COMPUTERGRAPHICS, Mathematics

Abstract

A six degrees-of-freedom parallel platform in a 6-RR-RP-RR configuration with high accuracy, high stiffness and a large working stroke is studied for application to the sub-mirror adjustment system of a large-aperture telescope. To meet the performance requirements, the parallel platform adopts a self-centering and well-designed offset universal hinge. The two hinge axes of the offset hinge do not intersect but have a specific offset in space, which makes the kinematics more complex than that with a common universal hinge. Therefore, to solve this complex kinematics problem, this paper innovatively introduces the Denavit–Hartenberg (D-H) parameter method that is used for series mechanisms. The method has a simple modeling process, strong applicability and continuity, providing a new tool for the analysis and application of the parallel mechanisms. A kinematics model of the parallel platform can be constructed and solved using a numerical iteration method. The accuracy of the numerical kinematics solution is verified using a co-simulation method. This paper analyses the passive derivative motion and the leg length error is compensated. Finally, test studies of the motion resolution, the repetitive positioning accuracy, the motion stroke, the static stiffness of the legs, and the static stiffness and dynamic stiffness of the entire machine were also carried out to verify the platform’s performance.

Published

2021

47. Investigation of Mechanical Properties of Honeycomb Sandwich Structure with Kenaf/glass Hybrid Composite Facesheet

Author

A. M. Ya’acob, Waqas Ashraf, Mohamad Ridzwan Ishak, Zuhri M.Y.M., and Noorfaizal Yidris

Subjects

Materials science, biology, Materials Science (miscellaneous), Composite number, Honeycomb (geometry), High stiffness, 02 engineering and technology, 010501 environmental sciences, 021001 nanoscience & nanotechnology, biology.organism_classification, 01 natural sciences, Kenaf, Honeycomb structure, Composite material, 0210 nano-technology, 0105 earth and related environmental sciences

Abstract

The application of a sandwich structure made with composite facesheet and honeycomb core has increased rapidly due to high stiffness to weight ratio characteristics. There is a growing interest in ...

Published

2021

48. Mechanical and tribological characteristics of Si3N4 reinforced aluminium matrix composites: A short review

Author

Tej Singh, Deepika Shekhawat, Chandramani Goswami, Tapan Kumar Patnaik, and Sanjay Manghnani

Subjects

010302 applied physics, Materials science, Composite number, High stiffness, 02 engineering and technology, Tribology, 021001 nanoscience & nanotechnology, 01 natural sciences, Specific strength, chemistry.chemical_compound, Silicon nitride, chemistry, visual_art, 0103 physical sciences, visual_art.visual_art_medium, Lubrication, Ceramic, Composite material, 0210 nano-technology, Aluminium matrix

Abstract

The aluminium matrix composite (AMCs) plays a significant role in enhancing the properties of the material that are applicable in automotive industries, marine, aerospace, etc. Whereas these AMCs were further researched with the integration of reinforcing particulates in different percentages with the aim of enhancing the characteristics of parent aluminium matrix. Introducing ceramic particulate reinforcements into aluminium matrix produces a composite with better physical, mechanical and tribological properties in comparison to the traditional engineering materials. The main purpose of producing aluminium matrix composites (AMCs) is to develop lightweight materials having high stiffness and high specific strength. There are different effects observed with subsequent addition of reinforcements on the aluminium matrix composite. This paper attempts to present a review concerning the mechanical and tribological characteristics of aluminium matrix composite synthesized via stir casting route. This literature review provides an insight to the effects encountered after incorporating hard Si3N4 particulates in aluminium matrix along with its performance. It also attempts to highlight the impact of addition of silicon nitride (Si3N4) in AMCs, as this ceramic possesses superior wear and mechanical characteristics. Moreover, the effect of different reinforcements upon minimizing the resultant friction as well as wear for attaining superior lubrication will also be discussed in detail.

Published

2021

49. A review on failure mechanisms and analysis of multidirectional laminates

Author

Yihunie Mognhod Bezzie, Velmurugan Paramasivam, Samuel Tilahun, and Senthil Kumaran Selvaraj

Subjects

010302 applied physics, business.industry, Computer science, Composite number, Stress failure, Fatigue testing, Failure mechanism, High stiffness, 02 engineering and technology, Structural engineering, Composite laminates, 021001 nanoscience & nanotechnology, 01 natural sciences, 0103 physical sciences, Advanced composite materials, Material failure theory, 0210 nano-technology, business

Abstract

Advanced composite materials have excellent mechanical and physical properties, which are wide, used in aerospace, automobile, biomedical, recreational (sport), and structural industries. Because composite materials have high stiffness and strength, fatigue failure and corrosion resistance, and low density compared with meals and metals alloy. But, composite materials' properties became poor performance due to manufacturing defects, fiber-matrix stacking sequences, fiber orientations, and other factors. These factors lead to multidirectional (MD) composite laminates failure. This paper presents a review of recent work on failure analysis of multidirectional composite laminate from the last two decades of published researches. This review paper reported MD composite laminates' failure mechanism at various failure criteria, such as maximum strain/stress failure criteria, quadratic failure theory (Tsai-Wu theory), Tsai-Hill criteria, Hashin criteria, Puck failure criteria, and others criteria. Finally, this paper presents a meaningful conclusion.

Published

2021

50. Solution-based fabrication of mechanically transformative materials for implantable applications

Author

Yanyan Li, Kuikui Zhang, Desheng Kong, Xinxin Zhang, Bing Liu, Anwei Zhou, Gaohua Hu, and Xinghai Ning

Subjects

Fabrication, Materials science, Biocompatibility, Biomedical Engineering, chemistry.chemical_element, Nanotechnology, High stiffness, Prostheses and Implants, engineering.material, Elastomer, Transformative learning, Elastomers, Coating, chemistry, Needles, engineering, General Materials Science, Gallium

Abstract

Implantable probes and needles represent multifunctional biomedical platforms by integrating sensing, stimulation, and drug delivery capabilities. Conventional rigid probes often result in inflammatory responses due to large mechanical mismatch with soft biological tissues, whereas soft probes with improved long-term performances are difficult to be inserted deep into the compliant biological tissues. An emerging class of mechanically transformative materials addresses the challenge by embedding a phase-change material of gallium within an elastomeric matrix. These materials exhibit high stiffness under ambient conditions to enable facile insertion and compliant mechanical properties after implantations. The widespread implementation of mechanically transformative materials is primarily hindered by the lack of facile fabrication techniques for delicate gallium features. In this study, we introduce a solution-based approach for scalable fabrication of gallium-based mechanically transformative materials, which exhibit bistable mechanical properties with large modulations in the modulus by five orders of magnitude. In a solution-based coating process, gallium features are created based on a patterned copper film and then encapsulated with elastomers to form mechanically transformative materials. The height profile of the gallium feature is controlled by the two-dimensional design of the copper pattern, which provides access to delicate and complex three-dimensional features as exemplified by mechanically transformative indwelling needles with sharp tips. The practical suitability is demonstrated by the in vivo implementation of the indwelling needles for long-term chemotherapy. The excellent biocompatibility enables applications of mechanically transformative biomedical devices in chronic implantable systems.

Published

2021