Your search keyword '"Chaoquan Tang"' showing total 74 results

1. Simultaneous Localization and Mapping Methods for Snake-like Robots Based on Gait Adjustment

Author

Chaoquan Tang, Zhipeng Zhang, Meng Sun, Menggang Li, Hongwei Tang, and Deen Bai

Subjects

snake robot, SLAM, typical gait, stability control, IMU, Technology

Abstract

Snake robots require autonomous localization and mapping capabilities for field applications. However, the characteristics of their motion, such as large turning angles and fast rotation speeds, can lead to issues like drift or even failure in positioning and map building. In response to this situation, this paper starts from the gait motion characteristics of the snake robot itself, proposing an improved gait motion method and a tightly coupled method based on IMU and visual information to solve the problem of poor algorithm convergence caused by head-shaking in snake robot SLAM. Firstly, the adaptability of several typical gaits of the snake robot to SLAM methods was evaluated. Secondly, the serpentine gait was selected as the object of gait improvement, and a head stability control method for the snake robot was proposed, thereby reducing the interference of the snake robot’s motion on the sensors. Thirdly, a visual–inertial tightly coupled SLAM method for the snake robot’s serpentine gait and Arc-Rolling gait was proposed, and the method was verified to enhance the robustness of the visual SLAM algorithm and improve the positioning and mapping accuracy of the snake robot. Finally, experiments proved that the methods proposed in this paper can effectively improve the accuracy of positioning and map building for snake robots.

Published

2024

2. A Multimodal Robust Simultaneous Localization and Mapping Approach Driven by Geodesic Coordinates for Coal Mine Mobile Robots

Author

Menggang Li, Kun Hu, Yuwang Liu, Eryi Hu, Chaoquan Tang, Hua Zhu, and Gongbo Zhou

Subjects

multimodal fusion SLAM, geodesic-coordinate transmission, coal mine robot, Science

Abstract

Mobile robots in complex underground coal mine environments are still unable to achieve accurate pose estimation and the real-time reconstruction of scenes with absolute geographic information. Integrated terrestrial-underground localization and mapping technologies have still not been effectively developed. This paper proposes a multimodal robust SLAM method based on wireless beacon-assisted geographic information transmission and lidar-IMU-UWB elastic fusion mechanism (LIU-SLAM). In order to obtain the pose estimation and scene models consistent with the geographic information, the construction of two kinds of absolute geographic information constraints based on UWB beacons is proposed. An elastic multimodal fusion state estimation mechanism is designed based on incremental factor graph optimization. A tightly coupled lidar-inertial odometry is firstly designed to construct the lidar-inertial local transformation constraints, which are further integrated with the absolute geographic constraints by UWB anchors through a loosely coupled approach. Extensive field tests based on coal mine robots have been conducted in scenarios such as underground garages and underground coal mine laneways. The results show that the proposed geodesic-coordinate driven multimode robust SLAM method can obtain absolute localization accuracy within 25 cm with practical robustness and real-time performance in different underground application scenarios. The wireless beacon-assisted geodesic-coordinate transmission strategy can provide a plug-and-play customized solution for precise positioning and scene modeling in complex scenarios of various coal mine robot application.

Published

2023

3. Research on Trajectory Planning and Tracking Methods for Coal Mine Mobile Robots

Author

Menggang Li, Kun Hu, Weiwei He, Eryi Hu, Chaoquan Tang, and Gongbo Zhou

Subjects

coal mine robots, trajectory planning, trajectory tracking, MINCO trajectory class, MPC, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Coal Mine Mobile Robots (CMRRs) are generally large in size and inertia, while narrow laneway space and bumpy terrain pose great challenges to CMRR’s planning and control. Aiming at the trajectory planning and tracking problems of CMRR, a new trajectory class MINCO is derived in detail based on the properties of differential flat systems. A trajectory planning method based on MINCO trajectory and safety corridor constraints constructed with underground environmental constraints is further proposed. A trajectory tracking method based on model predictive control (MPC) is further proposed. The prediction model of MPC is constructed by a kinematics model and transformed into a standard quadratic programming problem according to the cost function of a trajectory tracking target. Finally, large quantities of field tests were carried out for the proposed approaches. The results show that the proposed planning algorithm based on MINCO trajectory can achieve good avoidance effects within 10 planning attempts in different obstacle scenarios, and the trajectory is smoother compared to the Fast-Planner algorithm, with shorter trajectory length and less planning time. The tracking error of MPC is always less than 0.05 m in different underground scenarios, having a more adaptable trajectory tracking effect than PID.

Published

2023

4. Inspection Robot and Wall Surface Detection Method for Coal Mine Wind Shaft

Author

Chaoquan Tang, Erfei Gao, Yingming Li, Menggang Li, Deen Bai, Hongwei Tang, and Gongbo Zhou

Subjects

wind shaft, inspection robot, machine vision, defect detection, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The coal mine wind shaft is an important ventilation channel in coal mines, and it is of great significance to ensure its long-term safety. At present, the inspection of wind shafts still depends on manual work, which has low reliability and high risk. There are two main problems in the shaft wall detection of ventilation shafts: (1) The humidity and dust concentration in ventilation shafts are high, which makes imaging difficult; (2) the cracks on the shaft wall are long and irregular, so it is impossible to acquire the information of the whole crack from a single photo. Firstly, the mapping analysis between the concentration of water vapor and dust in the wind shaft and the image definition is determined by experiments. Then, the inspection robot is designed to move along the axial and circumferential directions to get close to the shaft wall, and the rack-and-rail drive design is adopted to ensure the real-time position feedback of the robot. Then, through the crack parameter detection method based on depth learning, the movement direction of the robot is controlled according to the crack direction so as to ensure that the complete crack parameters are obtained. Finally, the crack detection algorithm is verified by experiments.

Published

2023

5. Gait Generation Method of Snake Robot Based on Main Characteristic Curve Fitting

Author

Chaoquan Tang, Lulu Sun, Gongbo Zhou, Xin Shu, Hongwei Tang, and Hao Wu

Subjects

snake robot, backbone curve, gait generation method, snake robot control, Technology

Abstract

Gait generation method is one of the important contents of snake robot motion control. Different gait generation methods produce completely different forms of control functions, so snake robots need more complicated programming logic and processes to realize various gaits and their transformation. Therefore, we propose a new unified expression of gait method, The MCC (main characteristics control) method simplifies and unifies the control functions of different snake robots gaits by extracting the main features of the backbone curves of snake robots gaits. Since all periodic curves that meet the Dirichlet conditions can be formed by superposition of sinusoidal curves, taking the “lowest frequency” part that reflects the main characteristics of the curve as the target configuration can simplify the motion control function of snake robots’ gaits. Based on the MCC method, some snake robot gaits are reconstructed, including serpentine gait, rolling gait, helix rolling gait, and crawler gait. In addition, based on MCC method, an AEH-sidewinding gait control method is proposed. The backbone of the AEH-sidewinding gait is closer to the ideal elliptic helix, thus improving the accuracy of its kinematics modeling of snake robot sidewinding gait. Finally, the validity of this gait is verified by experiments. This unified gait expression of snake robots will be helpful to realize smooth gait switching between different gaits of snake robots.

Published

2023

6. Tracking System for a Coal Mine Drilling Robot for Low-Illumination Environments

Author

Shaoze You, Hua Zhu, Menggang Li, Yutan Li, and Chaoquan Tang

Subjects

visual object tracking, low illumination, image enhancement, computer vision, mobile drilling robot, coal mine robot, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

In recent years, discriminative correlation filters (DCF) based trackers have been widely used in mobile robots due to their efficiency. However, underground coal mines are typically a low illumination environment, and tracking in this environment is a challenging problem that has not been adequately addressed in the literature. Thus, this paper proposes a Low-illumination Long-term Correlation Tracker (LLCT) and designs a visual tracking system for coal mine drilling robots. A low-illumination tracking framework combining image enhancement strategies and long-time tracking is proposed. A long-term memory correlation filter tracker with an interval update strategy is utilized. In addition, a local area illumination detection method is proposed to prevent the failure of the enhancement algorithm due to local over-exposure. A convenient image enhancement method is proposed to boost efficiency. Extensive experiments on popular object tracking benchmark datasets demonstrate that the proposed tracker significantly outperforms the baseline trackers, achieving high real-time performance. The tracker’s performance is verified on an underground drilling robot in a coal mine. The results of the field experiment demonstrate that the performance of the novel tracking framework is better than that of state-of-the-art trackers in low-illumination environments.

Published

2022

7. Efficient Laser-Based 3D SLAM for Coal Mine Rescue Robots

Author

Menggang Li, Hua Zhu, Shaoze You, Lei Wang, and Chaoquan Tang

Subjects

CMRRs, SLAM, NDT, pose graph optimization, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

An accurate description of laneway space with self-localization is a key issue when coal mine rescue robots (CMRRs) perform post-disaster exploration and rescue missions. The 3D simultaneous localization and mapping (SLAM) is an effective but time-critical and highly challenging task in complex laneway scenarios, especially after disasters. In this paper, we propose a novel real-time 3D SLAM based on normally distributed transform (NDT) that employs pose graph optimization and loop closure to further improve mapping consistency. We innovatively extract floors and walls in the laneway as plane nodes to construct landmark constraints, in addition to applying pose nodes from the lidar odometry via NDT. A lightweight and effective loop detection method is conducted using odometry with an appearance-based approach to building a globally consistent map. The proposed method was evaluated on a public dataset, and field tests in an underground coal mine were performed. Results indicate that our algorithm can achieve lower computational complexity and drift, which can provide pose estimation and environment description for CMRRs to realize remote control assistance and automatic navigation in coal mine rescue missions.

Published

2019

8. Linear Permanent Magnet Eddy Current Brake for Overwinding Protection

Author

Panpan Yang, Gongbo Zhou, Zhencai Zhu, Chaoquan Tang, Zhenzhi He, and Penghui Wang

Subjects

Eddy current brake, linear permanent magnet, overwinding protection, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Overwinding protection devices are used to brake hoisting containers before these containers reach a limited height, thereby preventing the hoisting containers from impacting the hoisting system. However, in ultra-deep shafts (depth > 1000 m), traditional overwinding protection methods fail to protect the hoisting system, because this type of hoisting system has a greater mass, kinetic energy, and inertia than the traditional hoisting system, and also the environment of ultra-deep shafts is more complex. This paper presents a novel overwinding protection method that applies a linear permanent magnet eddy current brake (LPMECB) to the hoisting system in ultra-deep shafts. This paper also finds the optimum setting parameter of permanent magnets (PMs). First, an analytical model of the LPMECB is built, and the time-domain signals of the braking force are processed via fast Fourier transform, confirming the mechanism of the optimum setting parameter. Subsequently, the simulations are conducted by establishing a finite-element model of the LPMECB; the simulations prove the existence of the optimum setting parameter of PMs and demonstrate the influence of the air gap, velocity, and conductivity on this parameter. Finally, the experimental studies are carried out on a test bench of the LPMECB to validate the analytical model and the simulation results. The results show the existence of the optimum setting parameter of PMs and prove that the air gap has an effect on this parameter.

Published

2019

9. Adaptive Dynamic Surface Control of Pneumatic Servo Systems With Valve Dead-Zone Compensation

Author

Deyuan Meng, Aimin Li, Bo Lu, Chaoquan Tang, and Qingyang Li

Subjects

Pneumatic servo system, dynamic surface control, proportional directional control valve, valve dead zone, position tracking, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

An adaptive dynamic surface controller (ADSC), which comprises an online parameter estimator and a robust control law, is developed for the pneumatic servo systems driven by the proportional directional control valves. Departing from the use of time-consuming offline fitting of the orifice area to accommodate the effect of valve dead zone, this paper employs the least-square-type indirect parameter estimation algorithm with online condition monitoring to estimate the dead-zone parameters and some other important model parameters. These accurate estimates of model parameters are utilized in the development of a precise position tracking controller for the single-rod pneumatic actuator. By using the dynamic surface control technique to synthesize the robust control law, the problem of “explosion of complexity” in traditional backstepping design method is avoided. The stability of the closed-loop system is proved by the means of the Lyapunov theory. The obtained extensive comparative experimental results verify the effectiveness of the proposed valve dead-zone compensation strategy and the high-performance nature of the ADSC in practical implementation.

Published

2018

10. Impact cushioning device of wireless sensor node for emergency rescue system in underground coal mine

Author

Chaoquan Tang, Gongbo Zhou, Penghui Wang, Zhencai Zhu, Peng Zhang, Hao Chen, and Wei Li

Subjects

Mechanical engineering and machinery, TJ1-1570

Abstract

Because of the closed geographic conditions and the effect of uncertain factors during a catastrophe in an underground coal mine, a high failure rate of the sensor nodes after a disaster is a common phenomenon. To ensure normal communications after a disaster, an impact cushioning device is designed to ensure survival of the sensor nodes during the disasters like the tunnel collapse, gas explosion, and so on. First, a model for the spring absorbing system is built; an analysis based on the model shows that the impact cushioning device can survive the free impact due to the extremely short impact time and the small displacement despite the large force from the instantaneous impact. Second, a collision model between the impact cushioning device and the rock is built; an analysis based on the model shows that both the circuit boards and the shell of the device can survive a tunnel collapse because the maximum stress values of the shell material and the circuit boards during the collision process are much less than their yield strength values. Finally, we use a triangular wave to simulate the shock wave used to test the collision model. An analysis of the test shows that the shell of the device and circuit boards are still safe and reliable under the effects of a gas explosion for the same reason that the maximum stress values of the shell material and the circuit boards in the gas explosion process are much lower than their yield strength values.

Published

2018

11. Arboreal concertina locomotion of snake robots on cylinders

Author

Chaoquan Tang, Xin Shu, Deyuan Meng, and Gongbo Zhou

Subjects

Electronics, TK7800-8360, Electronic computers. Computer science, QA75.5-76.95

Abstract

This article proposes a novel gait on cylinders for a snake robot as well as arboreal concertina locomotion gait, including the generation method. The gait on the cylinder of a snake robot is a kind of spatial motion planning that is difficult in manual design. In this article, a planar gait of a snake robot is first constructed, followed by cylindrical gait via a transformation mechanism. In addition, a gait generating scheme of arboreal concertina locomotion gait of snake robots on cylinders is constructed and verified via a simulation platform. Such gait makes advantages on cylindrical motion capability of snake robots and the proposed generation approach for gait construction can be promoted to other cylindrical gaits, reducing design difficulty.

Published

2017

12. A Review of Non-Destructive Damage Detection Methods for Steel Wire Ropes

Author

Ping Zhou, Gongbo Zhou, Zhencai Zhu, Zhenzhi He, Xin Ding, and Chaoquan Tang

Subjects

non-destructive damage detection, steel wire ropes, review, electromagnetic detection, optical detection, ultrasonic guided wave, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

As an important load-bearing component, steel wire ropes (WRs) are widely used in complex systems such as mine hoists, cranes, ropeways, elevators, oil rigs, and cable-stayed bridges. Non-destructive damage detection for WRs is an important way to assess damage states to guarantee WR’s reliability and safety. With intelligent sensors, signal processing, and pattern recognition technology developing rapidly, this field has made great progress. However, there is a lack of a systematic review on technologies or methods introduced and employed, as well as research summaries and prospects in recent years. In order to bridge this gap, and to promote the development of non-destructive detection technology for WRs, we present an overview of non-destructive damage detection research of WRs and discuss the core issues on this topic in this paper. First, the WRs’ damage type is introduced, and its causes are explained. Then, we summarize several main non-destructive detection methods for WRs, including electromagnetic detection method, optical detection method, ultrasonic guided wave detection method, and acoustic emission detection method. Finally, a prospect is put forward. Based on the review of papers, we provide insight about the future of the non-destructive damage detection methods for steel WRs to a certain extent.

Published

2019

13. Health Monitoring for Balancing Tail Ropes of a Hoisting System Using a Convolutional Neural Network

Author

Ping Zhou, Gongbo Zhou, Zhencai Zhu, Chaoquan Tang, Zhenzhi He, Wei Li, and Fan Jiang

Subjects

health monitoring, hoisting system, balancing tail ropes, convolutional neural network, image processing, ANN-BP, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

With the arrival of the big data era, it has become possible to apply deep learning to the health monitoring of mine production. In this paper, a convolutional neural network (CNN)-based method is proposed to monitor the health condition of the balancing tail ropes (BTRs) of the hoisting system, in which the feature of the BTR image is adaptively extracted using a CNN. This method can automatically detect various BTR faults in real-time, including disproportional spacing, twisted rope, broken strand and broken rope faults. Firstly, a CNN structure is proposed, and regularization technology is adopted to prevent overfitting. Then, a method of image dataset description and establishment that can cover the entire feature space of overhanging BTRs is put forward. Finally, the CNN and two traditional data mining algorithms, namely, k-nearest neighbor (KNN) and an artificial neural network with back propagation (ANN-BP), are adopted to train and test the established dataset, and the influence of hyperparameters on the network diagnostic accuracy is investigated experimentally. The experimental results showed that the CNN could effectively avoid complex steps such as manual feature extraction, that the learning rate and batch-size strongly affected the accuracy and training efficiency, and that the fault diagnosis accuracy of CNN was 100%, which was higher than that of KNN and ANN-BP. Therefore, the proposed CNN with high accuracy, real-time functioning and generalization performance is suitable for application in the health monitoring of hoisting system BTRs.

Published

2018

14. An Inspection Robot-Based Health Monitoring Method for Monorail Crane Tracks in Underground Coal Mines.

Author

Chaoquan Tang, Ping Zhou, Zining Chen, Yang Zhang, Hongwei Tang, Menggang Li, and Gongbo Zhou

Published

2024

15. LIVER: A Tightly Coupled LiDAR-Inertial-Visual State Estimator With High Robustness for Underground Environments.

Author

Tianci Wen, Yongchun Fang, Biao Lu, Xuebo Zhang, and Chaoquan Tang

Published

2024

16. Deployment Method of Wireless Sensor Networks for Coal Mine Safety Monitoring Based on Multi Robot Systems.

Author

Hongwei Tang, Gongbo Zhou, Deen Bai, Menggang Li, Xia Zhang, and Chaoquan Tang

Published

2023

17. Current Reconstruction by One-Step Compensation for Permanent Magnet Synchronous Motor With Fixed Sampling Interval in Position Sensorless Control.

Author

Lisi Tian, Zaixiang Wang, Qiang Yu 0007, Chaoquan Tang, and Hao Zhang

Published

2023

18. Obstacle Avoidance for Trackless Rubber-Tired Vehicle Based on Risk-Grid Particle Swarm Optimization in Confined Space of Deep Well.

Author

Xin Zhang, Chunyu Yang 0001, Zhen Gu, Chaoquan Tang, Zhencai Zhu, Yidong Zhang, Jun Qian, and Xiaoqiang Li

Published

2023

19. Extension and Experimental Demonstration of Gait Transition Network for a Snake Robot.

Author

Xin Shu, Chaoquan Tang, Gongbo Zhou, Ping Zhou, Lulu Sun, and Xiaodong Yan

Published

2023

20. A mobile data collection method for balancing energy consumption and delay in strip-shaped wireless sensor networks with branches.

Author

Hongwei Tang, Chaoquan Tang, Menggang Li, and Gongbo Zhou

Published

2024

21. A Novel Wear Detection Method Based on FPC: A Case Study on the Hoisting Cage Sliding Sleeve.

Author

Zhenzhi He, Xiaodong Yan, Yuan Sun, Wei Wang 0302, Gongbo Zhou, Ping Zhou, Chaoquan Tang, and Fan Jiang 0006

Published

2021

22. IMU-Aided Ultra-wideband Based Localization for Coal Mine Robots.

Author

Menggang Li, Hua Zhu 0002, Shaoze You, Lei Wang 0114, Zheng Zhang, and Chaoquan Tang

Published

2019

23. Design and Magnetic Force Analysis of Patrol Robot for Deep Shaft Rigid Cage Guide.

Author

Hongwei Tang, Chaoquan Tang, Gongbo Zhou, Xin Shu, and Qiao Gao

Published

2019

24. Long-Term Real-Time Correlation Filter Tracker for Mobile Robot.

Author

Shaoze You, Hua Zhu 0002, Menggang Li, Lei Wang 0114, and Chaoquan Tang

Published

2019

25. Development and applications of rescue robots for explosion accidents in coal mines.

Author

Yutan Li, Menggang Li, Hua Zhu 0002, Eryi Hu, Chaoquan Tang, Peng Li 0019, and Shaoze You

Published

2020

26. A General Approach of Calculating Semantic Object Distances from Complex Point Clouds.

Author

Shuai Guo, Rongchuan Sun, Chaoquan Tang, and Yi Sun

Published

2018

27. A Novel Rail Inspection Robot and Fault Detection Method for the Coal Mine Hoisting System.

Author

Chaoquan Tang, Gongbo Zhou, Zhaoxing Gao, Xin Shu, and Pengpeng Chen

Published

2019

28. Modeling of a 6-DOF parallel manipulator driven by pneumatic muscles.

Author

Deyuan Meng, Wei Wei, Chaoquan Tang, Weiping Wang, and Xingwang Ding

Published

2017

29. Design of a sanding robot for wooden painted decoration box.

Author

Peng Li 0019, Enzhi Xu, Chaoquan Tang, Yang Zhou, Xin Jiang 0001, Congyi Lyu, David Navarro-Alarcon, Haigong Gai, Chusheng Liu, Yunjiang Lou, and Yunhui Liu 0001

Published

2017

30. Quadrotor helicopters trajectory tracking with stochastic model predictive control.

Author

Yanhua Yang, Yang Chen, Chaoquan Tang, and Li Chai 0001

Published

2017

31. Design and Magnetic Force Analysis of Patrol Robot for Deep Shaft Rigid Cage Guide

Author

Hongwei, Tang, primary, Chaoquan, Tang, additional, Gongbo, Zhou, additional, Xin, Shu, additional, and Qiao, Gao, additional

Published

2019

32. Tracking system of Mine Patrol Robot for Low Illumination Environment.

Author

Shaoze You, Hua Zhu 0002, Menggang Li, Lei Wang 0114, and Chaoquan Tang

Published

2019

33. Electromagnetic modeling and experimental study of can-effect on a canned switched reluctance machine

Author

Lisi Tian, Biyue Xu, Qiang Yu, and Chaoquan Tang

Subjects

Mechanics of Materials, Mechanical Engineering, Electrical and Electronic Engineering, Condensed Matter Physics, Electronic, Optical and Magnetic Materials

Abstract

This paper proposes a novel electromagnetic modelling method, with experimental study of the magnetic can-shield effect, based on a novel canned switched reluctance machine. Such model considers the characteristic electromagnetic coupling relation between magnetic flux and eddy current on cans, with harmonic analysis by analytical calculation in vector form. The model is structured with multiple concentrated layers in cylindrical coordinate and the main modeling process includes domain solution of the magnetic field, and an energy vector deduction for loss and energy. Comparative measurement with an indirect method demonstrates the electromagnetic features by the use of cans and meanwhile verifies the analytical model.

Published

2022

34. A novel H-type linear permanent magnet eddy current brake

Author

Panpan Yang, Gongbo Zhou, Zhenzhi He, Chaoquan Tang, and Zhencai Zhu

Subjects

Mechanics of Materials, Mechanical Engineering, Electrical and Electronic Engineering, Condensed Matter Physics, Electronic, Optical and Magnetic Materials

Abstract

To improve the braking force of the Linear Permanent Magnet Eddy Current Brakes (LPMECB) under a large Air Gap (AG) length, this paper presents a novel structure of the LPMECB, named H-type Linear Permanent Magnet Eddy Current Brake (H-type LPMECB). To begin with, the analytical model of the LPMECB is established by using the equivalent magnetic circuit method, and it is found that the AG reluctance is greater than that of the other parts of the LPMECB. Based on this, a novel H-type LPMECB is proposed in order to compensate the influence of the AG. The H-type LPMECB adds Iron Foils (IFs) in the AG. These IFs are rectangular sheets made of pure iron. Furthermore, the finite element model of the H-type LPMECB is established to optimize the geometry parameter of the IFs, then the braking performance of the H-type LPMECB is measured. The simulations show that the optimal geometry parameter of the IFs of the H-type LPMECB is 0.25 ∗ L, and the braking performance of the H-type LPMECB is superior to that of the LPMECB, around three times. Finally, experiments were conducted, which validated the simulations.

Published

2022

35. A Magnetic Network Model and Harmonic Analysis of a Canned Switched Reluctance Machine

Author

Qiang Yu, Biyue Xu, Lisi Tian, Chaoquan Tang, Yuhu Cheng, and Xuesong Wang

Subjects

Electrical and Electronic Engineering, Electronic, Optical and Magnetic Materials

Published

2022

36. A Novel Wear Detection Method Based on FPC: A Case Study on the Hoisting Cage Sliding Sleeve

Author

He Zhenzhi, Sun Yuan, Wang Wei, Chaoquan Tang, Gongbo Zhou, Fan Jiang, Zhou Ping, and Yan Xiaodong

Subjects

business.industry, Computer science, 020208 electrical & electronic engineering, 02 engineering and technology, Structural engineering, Edge (geometry), Flexible electronics, law.invention, Vibration, Mechanism (engineering), law, 0202 electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Resistor, business, Instrumentation, Voltage

Abstract

Under severe working conditions in mines, common wear detection methods are difficult to apply to the hoisting cage sliding sleeves. This article proposes a wear detection method based on flexible printed circuit (FPC), which is conceived for the wear detection of sliding sleeves or the edge of complex curved surfaces under severe conditions. First, a new type of sensor based on FPC is proposed, and its detection principle is presented. Then, according to the wear mechanism of sliding sleeves, a wear detection system is designed and manufactured. In order to express wear value, a formula about the relationship between the number of broken wires and wear value is established. Finally, a series of verification experiments are carried out, and the obtained results confirm the feasibility of proposed approach and explain the causes of voltage fluctuations.

Published

2021

37. UWB-Based Localization System Aided With Inertial Sensor for Underground Coal Mine Applications

Author

You Shaoze, Chaoquan Tang, Hua Zhu, and Li Menggang

Subjects

Positioning system, business.industry, Computer science, 010401 analytical chemistry, Real-time computing, Coal mining, Ranging, Kalman filter, 01 natural sciences, 0104 chemical sciences, Odometry, Inertial measurement unit, Electrical and Electronic Engineering, business, Instrumentation, Pose, Multipath propagation

Abstract

Robotic mining equipment plays an increasingly important role in the coal mining industry. Due to the complexity of the confined underground environment, available localization methods are limited, and restrict the development of coal mine robots (CMRs). Ultra-wideband (UWB) is a promising positioning sensor with high ranging accuracy. However, current applications about UWB positioning in coal mine focus mainly on position information, but rarely on orientation information. Positioning accuracy is often plagued by the loss of transmitted signals and multipath effects. In this paper, a pseudo-GPS positioning system in underground coal mine, composed by noisy UWB range measurements, is proposed to provide localization service for CMRs. An Error-State Kalman Filter (ESKF) is used for fusing measurements from the inertial measurement unit (IMU) and the established UWB positioning system. Then the complete six degree of freedom (6-DOF) state estimation can be realized. Meanwhile the biases of the IMU and the translation parameters of IMU w.r.t. UWB mobile node are also estimated online to adapt to long-term operation in harsh underground environments. In addition, an UWB anchor optimal deployment strategy is discussed to deploy UWB nodes appropriately in the laneway, and maintain realistic positioning accuracy for CMR in the meantime. A large number of field tests in different environments including the actual underground coal mine were conducted. The experimental results showed that our method could obtain the pose estimation performance close to the state-of-the-art lidar odometry approach that has been currently utilized in underground coal mine, providing robust and precise localization estimation for CMR applications.

Published

2020

38. Development and applications of rescue robots for explosion accidents in coal mines

Author

Li Peng, You Shaoze, Hu Eryi, Li Yutan, Li Menggang, Chaoquan Tang, and Hua Zhu

Subjects

Rescue robot, Mining engineering, Control and Systems Engineering, business.industry, Computer science, Coal mining, business, Computer Science Applications

Published

2020

39. Tactile perception of textile fabrics using event-related potentials and nonlinear methods

Author

Chaoquan Tang, Tengfei Zhuang, Xingxing Fang, Chuang Yu, and Wei Tang

Subjects

Polymers and Plastics, Chemical Engineering (miscellaneous)

Abstract

Tactile perception is processed in the somatosensory cortices of the brain. To study the electrical activity of the brain evoked by the tactile perceptions of fabric textures, electroencephalograph signals during tactile perception were evaluated using event-related potentials and recurrence quantification analysis methods. A support vector machine was used to realize the identification of electroencephalograph signals. The results showed that fabric surface with large surface roughness, critical buckling force, and fiber diameter, and low warp-weft density was preferentially perceived, need large attentional resources, and evoke strong nonstationary state of the electroencephalographic system during the tactile perception. The δ rhythm was the main rhythm of event-related potential signals evoked by tactile perception of fabrics and the main energy of the electroencephalograph rhythm was concentrated in the low frequency band. The electroencephalographic system was in a strong nonstationary and fluctuating state during the production stage of P200 and P300 components of the event-related potential wave. The combination of P200, P300, mean diagonal line length L, and trapping time TT can significantly improve the classification accuracy of the electroencephalograph signal of tactile perception to about 72%.

Published

2023

40. Design and Development of a Snake Robot with Wheeled Modules

Author

Hongwei Tang, Chaoquan Tang, Xin Shu, Gongbo Zhou, and Shuai Guo

Published

2021

41. A New Piezoelectric Bimorph Energy Harvester Based on the Vortex-Induced-Vibration Applied in Rotational Machinery

Author

Gongbo Zhou, Zhencai Zhu, Hao Benliang, Zhixiang Li, and Chaoquan Tang

Subjects

0209 industrial biotechnology, Wind power, Materials science, business.industry, Acoustics, Rotational speed, 02 engineering and technology, Piezoelectricity, Kármán vortex street, Computer Science Applications, Vibration, 020901 industrial engineering & automation, Electricity generation, Control and Systems Engineering, Vortex-induced vibration, Electrical and Electronic Engineering, business, Voltage

Abstract

An innovative wind-induced energy harvester utilizing a piezoelectric bimorph with a pulling strip was designed based on Karman vortex street theory to collect wind energy from a rotating machinery for powering some devices. A mathematical model was initially established for the model force analysis, and the voltage generated by the piezoelectric bimorph were calculated. The stress distribution on the piezoelectric bimorph was also examined to prevent the piezoelectric material from cracking. A series of experiments were conducted according to the results of the numerical analysis. Both the numerical analysis and the experiments demonstrate that: first, rotation speed is the most important factor that affects the power generation capacity of the piezoelectric bimorph, and with a suitable installing angle, an output power of 1 mW can be easily acquired when the rotation speed exceeds 140 r/min; and, second, choosing an appropriate installing angle can increase the power generation capacity more effectively than rectifying the diameter of the cylindrical obstacle.

Published

2019

42. Efficient Laser-Based 3D SLAM for Coal Mine Rescue Robots

Author

Hua Zhu, You Shaoze, Li Menggang, Chaoquan Tang, and Lei Wang

Subjects

General Computer Science, Computer science, Real-time computing, ComputerApplications_COMPUTERSINOTHERSYSTEMS, 02 engineering and technology, Simultaneous localization and mapping, 01 natural sciences, NDT, Odometry, Nondestructive testing, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Pose, Rescue robot, CMRRs, Landmark, business.industry, 010401 analytical chemistry, General Engineering, Coal mining, 0104 chemical sciences, Lidar, SLAM, 020201 artificial intelligence & image processing, lcsh:Electrical engineering. Electronics. Nuclear engineering, pose graph optimization, business, lcsh:TK1-9971

Abstract

An accurate description of laneway space with self-localization is a key issue when coal mine rescue robots (CMRRs) perform post-disaster exploration and rescue missions. The 3D simultaneous localization and mapping (SLAM) is an effective but time-critical and highly challenging task in complex laneway scenarios, especially after disasters. In this paper, we propose a novel real-time 3D SLAM based on normally distributed transform (NDT) that employs pose graph optimization and loop closure to further improve mapping consistency. We innovatively extract floors and walls in the laneway as plane nodes to construct landmark constraints, in addition to applying pose nodes from the lidar odometry via NDT. A lightweight and effective loop detection method is conducted using odometry with an appearance-based approach to building a globally consistent map. The proposed method was evaluated on a public dataset, and field tests in an underground coal mine were performed. Results indicate that our algorithm can achieve lower computational complexity and drift, which can provide pose estimation and environment description for CMRRs to realize remote control assistance and automatic navigation in coal mine rescue missions.

Published

2019

43. A Novel Rail Inspection Robot and Fault Detection Method for the Coal Mine Hoisting System

Author

Gongbo Zhou, Shu Xin, Chaoquan Tang, Pengpeng Chen, and Gao Zhaoxing

Subjects

0209 industrial biotechnology, Landmark, Computer science, business.industry, Mechanical Engineering, 020208 electrical & electronic engineering, Coal mining, Mobile robot, 02 engineering and technology, Fault detection and isolation, Automotive engineering, Computer Science Applications, Halbach array, 020901 industrial engineering & automation, Automotive Engineering, Rail inspection, 0202 electrical engineering, electronic engineering, information engineering, Robot, business, Block (data storage)

Abstract

Rail is an important part of coal mine hoisting system, and its fault detection is an important work of mine daily maintenance. In this paper, a new inspection robot system and corresponding detection method are proposed to detect the faults in the rail of coal mine hoisting system. The robot system will replace the manual inspection work in the mine, and will greatly improve the efficiency of inspection. The robot is driven by a magnetic wheel to ensure its smooth motion on a vertical rail. In order to increase the adsorption capacity of the magnetic wheel, the halbach array based on multi block magnets is adopted in the magnetic wheel, and the relationship between the number of magnets and the adsorption force is analyzed. In addition, aiming at the problem of rail fault detection, a new method is proposed to estimate the rail deformation by using the robot's attitude perception. A method of robot positioning on rail is also proposed by combining fault detection as landmark and mileage estimation. Finally, the proposed method is verified by experiments. This inspection robot system can improve the efficiency of rail inspection of mine hoisting system, and the proposed detection scheme can also be extended to railway rail inspection.

Published

2019

44. Linear Permanent Magnet Eddy Current Brake for Overwinding Protection

Author

Yang Panpan, Wang Penghui, Zhencai Zhu, Gongbo Zhou, He Zhenzhi, and Chaoquan Tang

Subjects

Eddy current brake, Test bench, General Computer Science, Computer science, media_common.quotation_subject, Fast Fourier transform, 02 engineering and technology, Inertia, 01 natural sciences, law.invention, Control theory, law, 0103 physical sciences, Brake, 0202 electrical engineering, electronic engineering, information engineering, Eddy current, General Materials Science, media_common, 010302 applied physics, 020208 electrical & electronic engineering, General Engineering, overwinding protection, linear permanent magnet, Magnet, lcsh:Electrical engineering. Electronics. Nuclear engineering, Air gap (plumbing), lcsh:TK1-9971

Abstract

Overwinding protection devices are used to brake hoisting containers before these containers reach a limited height, thereby preventing the hoisting containers from impacting the hoisting system. However, in ultra-deep shafts (depth > 1000 m), traditional overwinding protection methods fail to protect the hoisting system, because this type of hoisting system has a greater mass, kinetic energy, and inertia than the traditional hoisting system, and also the environment of ultra-deep shafts is more complex. This paper presents a novel overwinding protection method that applies a linear permanent magnet eddy current brake (LPMECB) to the hoisting system in ultra-deep shafts. This paper also finds the optimum setting parameter of permanent magnets (PMs). First, an analytical model of the LPMECB is built, and the time-domain signals of the braking force are processed via fast Fourier transform, confirming the mechanism of the optimum setting parameter. Subsequently, the simulations are conducted by establishing a finite-element model of the LPMECB; the simulations prove the existence of the optimum setting parameter of PMs and demonstrate the influence of the air gap, velocity, and conductivity on this parameter. Finally, the experimental studies are carried out on a test bench of the LPMECB to validate the analytical model and the simulation results. The results show the existence of the optimum setting parameter of PMs and prove that the air gap has an effect on this parameter.

Published

2019

45. Adaptive robust precision motion control of single PAM actuated servo systems with non-local memory hysteresis force compensation

Author

Aimin Li, Deyuan Meng, Chaoquan Tang, Shunli Li, and Wei Zhong

Subjects

Recursive least squares filter, 0209 industrial biotechnology, Computer science, Applied Mathematics, 020208 electrical & electronic engineering, 02 engineering and technology, Servomechanism, Motion control, Computer Science Applications, Compensation (engineering), law.invention, Tracking error, Hysteresis, 020901 industrial engineering & automation, Control and Systems Engineering, Control theory, law, 0202 electrical engineering, electronic engineering, information engineering, Feedback linearization, Electrical and Electronic Engineering, Instrumentation

Abstract

An adaptive robust controller with non-local memory hysteresis force compensation is investigated for the precision tracking control of pneumatic artificial muscle (PAM). The proposed controller presents a two-layer cascade structure, and each layer has an adaptive law part and a robust control law part. A modified operator based Prandtl-Ishlinskii (PI) model is employed in the development of the robust control algorithm with the hysteresis feedback linearization compensation. Moreover, in the robust control law part, the problem of unbounded uncertain nonlinearities introduced by the hysteresis force term is addressed by applying an on-line monitoring method. In the adaptive law part, model parameters including weights of the modified operator are updated online by the recursive least squares estimation (RLSE) method, and then the effect of the hysteresis non-local memory characteristic is further attenuated. The tracking error is guaranteed to converge to a small residual set. Comparative experimental results demonstrate the significance of the non-local memory hysteresis force compensation, then, a desired precision can be guaranteed.

Published

2020

46. Adaptive Dynamic Surface Control of Pneumatic Servo Systems With Valve Dead-Zone Compensation

Author

Aimin Li, Chaoquan Tang, Bo Lu, Deyuan Meng, and Qingyang Li

Subjects

Control valves, Lyapunov function, 0209 industrial biotechnology, General Computer Science, Computer science, Pneumatic servo system, 02 engineering and technology, Servomechanism, Servomotor, law.invention, symbols.namesake, 020901 industrial engineering & automation, Control theory, law, 0202 electrical engineering, electronic engineering, information engineering, proportional directional control valve, General Materials Science, Pneumatic actuator, position tracking, General Engineering, Condition monitoring, dynamic surface control, valve dead zone, Backstepping, symbols, 020201 artificial intelligence & image processing, lcsh:Electrical engineering. Electronics. Nuclear engineering, Actuator, lcsh:TK1-9971

Abstract

An adaptive dynamic surface controller (ADSC), which comprises an online parameter estimator and a robust control law, is developed for the pneumatic servo systems driven by the proportional directional control valves. Departing from the use of time-consuming offline fitting of the orifice area to accommodate the effect of valve dead zone, this paper employs the least-square-type indirect parameter estimation algorithm with online condition monitoring to estimate the dead-zone parameters and some other important model parameters. These accurate estimates of model parameters are utilized in the development of a precise position tracking controller for the single-rod pneumatic actuator. By using the dynamic surface control technique to synthesize the robust control law, the problem of “explosion of complexity” in traditional backstepping design method is avoided. The stability of the closed-loop system is proved by the means of the Lyapunov theory. The obtained extensive comparative experimental results verify the effectiveness of the proposed valve dead-zone compensation strategy and the high-performance nature of the ADSC in practical implementation.

Published

2018

47. A magnetic circuit network model for salient electrical machines with high power density

Author

Qiang Yu, Chaoquan Tang, and Lisi Tian

Subjects

010302 applied physics, Electrical load, Computer science, Mechanical Engineering, 020208 electrical & electronic engineering, 02 engineering and technology, High power density, Condensed Matter Physics, 01 natural sciences, Electronic, Optical and Magnetic Materials, Magnetic circuit, Mechanics of Materials, Salient, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Electrical and Electronic Engineering, Network model

Published

2017

48. Modeling and Mechanical Analysis of Snake Robots on Cylinders

Author

Shuai Guo, Deyuan Meng, Peng Li, Gongbo Zhou, Shu Xin, Zhixiong Li, and Chaoquan Tang

Subjects

0209 industrial biotechnology, Computer science, Mechanical Engineering, Mechanical engineering, 02 engineering and technology, Kinematics, 021001 nanoscience & nanotechnology, Computer Science::Robotics, Computer Science::Graphics, 020901 industrial engineering & automation, Computer Science::Computer Vision and Pattern Recognition, Physics::Accelerator Physics, Robot, 0210 nano-technology

Abstract

The narrow and redundant body of the snake robot makes it suitable for the inspection of complex bar structures, such as truss or tree structures. One of the key issues affecting the efficient motion of snake robots in complex bar structures is the development of mechanical models of snake robots on cylinders. In other words, the relationship between the payload and structural and performance parameters of the snake robot is still difficult to clarify. In this paper, the problem is approached with the Newton–Euler equations and the convex optimal method. Firstly, from the kinematic point of view, the optimal attitude of the snake robot wrapped around the cylinder is found. Next, the snake robot is modeled on the cylinder and transformed into a convex optimization problem. Then, the relationship between the payload of the snake robot on the cylinder and the geometric and attitude parameters of the body of snake robots is analyzed. Finally, the discussion for the optimal winding attitude and some advices for the design of the snake robot are proposed. This study is helpful toward the optimal design of snake robots, including geometry parameters and motor determination.

Published

2019

49. Dynamic surface control of the single-rod pneumatic actuator with disturbance rejection

Author

Fei Chen, Qingyang Li, Deyuan Meng, Haiyun Zhang, Chaoquan Tang, and Aimin Li

Subjects

Nonlinear system, Pneumatic actuator, Robustness (computer science), Computer science, Control theory, law, Backstepping, Disturbance observer, Servomechanism, Motion control, Parametric statistics, law.invention

Abstract

In this paper, An adaptive dynamic surface controller (ADSC) is developed for the pneumatic servo systems with the single-rod pneumatic actuator. The ADSC scheme contains a nonlinear feedback part, a parametric adaption part, and a disturbance observer part in the parallel structure. The nonlinear feedback part is synthesized by the backstepping method, while the explosion of complexity in traditional backstepping design is avoided by utilizing dynamic surface control technique. Since precision motion control of pneumatic servo system is always disturbed by unknown model parameters and disturbance, the gradient adaption laws are employed to further estimate and compensate those factors. Experimental results obtained verify the effectiveness of the proposed ADSC controller and its performance robustness to parameter variations and external disturbance in practical implementation.

Published

2019

50. IMU-Aided Ultra-wideband Based Localization for Coal Mine Robots

Author

Lei Wang, You Shaoze, Li Menggang, Hua Zhu, Chaoquan Tang, and Zhang Zheng

Subjects

0209 industrial biotechnology, Positioning system, Computer science, business.industry, 020208 electrical & electronic engineering, Real-time computing, Coal mining, Ultra-wideband, Ranging, 02 engineering and technology, Kalman filter, Extended Kalman filter, 020901 industrial engineering & automation, Inertial measurement unit, 0202 electrical engineering, electronic engineering, information engineering, Robot, business

Abstract

Robotic mining equipment is playing an increasingly important role in coal mine operations. Due to the complexity of underground occlusion environment, the localization methods available are limited, which restricts the development of coal mine robots (CMRs). Ultra Wideband (UWB) is a promising positioning sensor with accurate ranging capacity, but it needs to overcome the transient signal loss caused by multipath effect and metal block in coal mine. Range measurements from UWB can only provide 3 degrees of freedom (DOF) position without orientation, which is not enough to operation for CMRs under space-constrained coal mine. In this paper, a pseudo-GPS positioning system composed by UWB range measurements is proposed to provide the position of CMRs. Additionally, an Error State Kalman Filter (ESKF) is used for fusing measurements from Inertial Measurement Unit (IMU) and UWB positioning system. The complete 6 DOF state estimation is established, and the biases of IMU and the calibration parameters of IMU w.r.t. the UWB mobile node are also estimated online to accommodate the long-term operation in underground harsh environment. Experiments in different motion conditions show that our approach can provide robust and precise 6 DOF state estimation for CMRs.

Published

2019