Your search keyword '"Jizhuang Fan"' showing total 7 results

1. Robot dynamic calibration on current level: modeling, identification and applications

Author

Tian Xu, Jizhuang Fan, Qianqian Fang, Yanhe Zhu, and Jie Zhao

Subjects

Control and Systems Engineering, Applied Mathematics, Mechanical Engineering, Aerospace Engineering, Ocean Engineering, Electrical and Electronic Engineering

Published

2022

2. High-efficiency inspecting method for mobile robots based on task planning for heat transfer tubes in a steam generator

Author

Biying Xu, Xuehe Zhang, Yue Ou, Kuan Zhang, Zhenming Xing, Hegao Cai, Jie Zhao, and Jizhuang Fan

Subjects

Mechanical Engineering

Abstract

Many heat transfer tubes are distributed on the tube plates of a steam generator that requires periodic inspection by robots. Existing inspection robots are usually involved in issues: Robots with manipulators need complicated installation due to their fixed base; tube mobile robots suffer from low running efficiency because of their structural restricts. Since there are thousands of tubes to be checked, task planning is essential to guarantee the precise, orderly, and efficient inspection process. Most in-service robots check the task tubes using row-by-row and column-by-column planning. This leads to unnecessary inspections, resulting in a long shutdown and affecting the regular operation of a nuclear power plant. Therefore, this paper introduces the structure and control system of a dexterous robot and proposes a task planning method. This method proceeds into three steps: task allocation, base position search, and sequence planning. To allocate the task regions, this method calculates the tool work matrix and proposes a criterion to evaluate a sub-region. And then all tasks contained in the sub-region are considered globally to search the base positions. Lastly, we apply an improved ant colony algorithm for base sequence planning and determine the inspection orders according to the planned path. We validated the optimized algorithm by conducting task planning experiments using our robot on a tube sheet. The results show that the proposed method can accomplish full task coverage with few repetitive or redundant inspections and it increases the efficiency by 33.31% compared to the traditional planning algorithms.

Published

2023

3. Experimental Study on Frog-inspired Swimming Robot Based on Articulated Pneumatic Soft Actuator

Author

Yanhe Zhu, Jizhuang Fan, Qingguo Yu, and Shuqi Wang

Subjects

Swimming robot, Computer science, 0206 medical engineering, Soft actuator, Biophysics, Bioengineering, 02 engineering and technology, Torso, Propulsion, 021001 nanoscience & nanotechnology, 020601 biomedical engineering, medicine.anatomical_structure, medicine, Miniaturization, Torque, Robot, 0210 nano-technology, Actuator, Simulation, Biotechnology

Abstract

This paper presents a frog-inspired swimming robot based on articulated pneumatic soft actuator. To realize the miniaturization of the robot and enhance its environmental adaptability, combined with the advantages and characteristics of soft materials, an articulated pneumatic soft actuator is designed based on analysis of a frog’s propulsion characteristics. A structural model is established to analyse the mechanical properties of the soft actuator. With the goal of making full use of the driving torque of the actuator and enhancing the propulsion efficiency of the robot, the motion trajectories of each joint of the robot are planned. Based on the trajectory planning, the control strategy of the soft actuator is determined to realize the frog-like swimming of the robot. The torso size after assembly is 0.175 m × 0.100 m × 0.060 m, which realizes the miniaturization of the frog-inspired robot. During the movement of the robot, the torso moves stably and flexibly, and can realize continuous linear and turning movements. The rationality of the structure and trajectory planning are verified by prototype experiments.

Published

2020

4. Active knee joint exoskeleton for stair ascent augmentation

Author

Sikai Zhao, Hongzhe Jin, Jie Zhao, Ma Shun, Tianjiao Zheng, Jizhuang Fan, Yanhe Zhu, and Zongwei Zhang

Subjects

medicine.medical_specialty, Physical medicine and rehabilitation, General Computer Science, Computer science, Stair climbing, medicine, Knee Joint, Exoskeleton, Stair ascent

Published

2020

5. Design and Dynamic Model of a Frog-inspired Swimming Robot Powered by Pneumatic Muscles

Author

Kong Pengcheng, Gang-Feng Liu, Hegao Cai, Wei Zhang, and Jizhuang Fan

Subjects

0209 industrial biotechnology, Engineering, Swimming robot, Pneumatic actuator, business.industry, Mechanical Engineering, 02 engineering and technology, Industrial and Manufacturing Engineering, Mechanism (engineering), Nonlinear system, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, 0203 mechanical engineering, Control theory, Air pump, Robot, Pneumatic circuit, business, Simulation

Abstract

Pneumatic muscles with similar characteristics to biological muscles have been widely used in robots, and thus are promising drivers for frog inspired robots. However, the application and nonlinearity of the pneumatic system limit the advance. On the basis of the swimming mechanism of the frog, a frog-inspired robot based on pneumatic muscles is developed. To realize the independent tasks by the robot, a pneumatic system with internal chambers, micro air pump, and valves is implemented. The micro pump is used to maintain the pressure difference between the source and exhaust chambers. The pneumatic muscles are controlled by high-speed switch valves which can reduce the robot cost, volume, and mass. A dynamic model of the pneumatic system is established for the simulation to estimate the system, including the chamber, muscle, and pneumatic circuit models. The robot design is verified by the robot swimming experiments and the dynamic model is verified through the experiments and simulations of the pneumatic system. The simulation results are compared to analyze the functions of the source pressure, internal volume of the muscle, and circuit flow rate which is proved the main factor that limits the response of muscle pressure. The proposed research provides the application of the pneumatic muscles in the frog inspired robot and the pneumatic model to study muscle controller.

Published

2017

6. Chaotic CPG based locomotion control for modular self-reconfigurable robot

Author

Yanhe Zhu, Xiaolu Wang, Yu Zhang, Hongzhe Jin, Dongyang Bie, Jizhuang Fan, and Jie Zhao

Subjects

0209 industrial biotechnology, Engineering, business.industry, media_common.quotation_subject, SIGNAL (programming language), Biophysics, Chaotic, Central pattern generator, Bioengineering, Control engineering, 02 engineering and technology, Modular design, Adaptability, 020901 industrial engineering & automation, Operator (computer programming), Control theory, 0202 electrical engineering, electronic engineering, information engineering, Feature (machine learning), Robot, 020201 artificial intelligence & image processing, business, Biotechnology, media_common

Abstract

The most important feature of Modular Self-reconfigurable Robot (MSRR) is the adaption to complex environments and changeable tasks. A critical difficulty is that the operator should regulate a large number of control parameters of modules. In this paper, a novel locomotion control model based on chaotic Central Pattern Generator (CPG) is proposed. The chaotic CPG could produce various rhythm signals or chaotic signal only by changing one parameter. Utilizing this characteristic, a unified control model capable of switching variable locomotion patterns or generating chaotic motion for modular self-reconfigurable robot is presented. This model makes MSRR exhibit environmental adaptability. The efficiency of the control model is verified through simulation and experiment of UBot MSRR platform.

Published

2016

7. Biological Jumping Mechanism Analysis and Modeling for Frog Robot

Author

Xi-zhe Zang, Meng Wang, Jie Zhao, and Jizhuang Fan

Subjects

Engineering, business.industry, Biophysics, Bioengineering, Kinematics, Linkage (mechanical), medicine.disease_cause, Robot leg, law.invention, Computer Science::Robotics, Mechanism (engineering), Jumping, law, medicine, Jump, Robot, Ground reaction force, business, Simulation, Biotechnology

Abstract

This paper presents a mechanical model of jumping robot based on the biological mechanism analysis of frog. By biological observation and kinematic analysis the frog jump is divided into take-off phase, aerial phase and landing phase. We find the similar trajectories of hindlimb joints during jump, the important effect of foot during take-off and the role of forelimb in supporting the body. Based on the observation, the frog jump is simplified and a mechanical model is put forward. The robot leg is represented by a 4-bar spring/linkage mechanism model, which has three Degrees of Freedom (DOF) at hip joint and one DOF (passive) at tarsometatarsal joint on the foot. The shoulder and elbow joints each has one DOF for the balancing function of arm. The ground reaction force of the model is analyzed and compared with that of frog during take-off. The results show that the model has the same advantages of low likelihood of premature lift-off and high efficiency as the frog. Analysis results and the model can be employed to develop and control a robot capable of mimicking the jumping behavior of frog.

Published

2008