Your search keyword '"multi-body dynamics"' showing total 802 results

1. Comparison of Bearing Behavior Between I-shaped and X-shaped Sleeper Using DEM Coupled Simulation

Author

Chen, Cheng, Tang, Yuyan, Zhang, Hongyi, Sun, Yifei, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Rujikiatkamjorn, Cholachat, editor, Xue, Jianfeng, editor, and Indraratna, Buddhima, editor

Published

2025

2. Head Impact Location, Speed and Angle from Falls and Trips in the Workplace.

Author

Yu, Xiancheng, Baker, Claire E., and Ghajari, Mazdak

Abstract

Traumatic brain injury (TBI) is a common injury in the workplace. Trips and falls are the leading causes of TBI in the workplace. However, industrial safety helmets are not designed for protecting the head under these impact conditions. Instead, they are designed to pass the regulatory standards which test head protection against falling heavy and sharp objects. This is likely to be due to the limited understanding of head impact conditions from trips and falls in workplace. In this study, we used validated human multi-body models to predict the head impact location, speed and angle (measured from the ground) during trips, forward falls and backward falls. We studied the effects of worker size, initial posture, walking speed, width and height of the tripping barrier, bracing and falling height on the head impact conditions. Overall, we performed 1692 simulations. The head impact speed was over two folds larger in falls than trips, with backward falls producing highest impact speeds. However, the trips produced impacts with smaller impact angles to the ground. Increasing the walking speed increased the head impact speed but bracing reduced it. We found that 41% of backward falls and 19% of trips/forward falls produced head impacts located outside the region of helmet coverage. Next, we grouped all the data into three sub-groups based on the head impact angle: [0°, 30°], (30°, 60°] and (60°, 90°] and excluded groups with small number of cases. We found that most trips and forward falls lead to impact angles within the (30°, 60°] and (60°, 90°] groups while all backward falls produced impact angles within (60°, 90°] group. We therefore determined five representative head impact conditions from these groups by selecting the 75th percentile speed, mean value of angle intervals and median impact location (determined by elevation and azimuth angles) of each group. This led to two representative head impact conditions for trips: 2.7 m/s at 45° and 3.9 m/s at 75°, two for forward falls: 3.8 m/s at 45° and 5.5 m/s at 75° and one for backward falls: 9.4 m/s at 75°. These impact conditions can be used to improve industrial helmet standards. [ABSTRACT FROM AUTHOR]

Published

2024

3. Coupled Modeling of Sea Surface Launch Flow and Multi-Body Motion.

Author

Liu, Haotian, Li, Shangming, Hou, Shilong, and Fu, Debin

Subjects

COMPUTATIONAL fluid dynamics, RELATIVE motion, WIND pressure, TORQUE, PROJECTILES

Abstract

To simulate the launching process of missile complex flow, movement, and constraint states, a multifield coupling model is put forward based on a computational fluid dynamics (CFD) method. In this coupled model, a CFD method is used to solve the three-dimensional compressible transient flow, and the six-degree motion of the launching platform is considered, and the virtual contact method is used to deal with the constraint states of the guideway and the slider. The active force and moment are applied to the launching platform to simulate its rolling, pitching, and heaving motions under the 5-level waves. Collision detection is carried out through the minimum clearance distance between the slider and the guideway, and the contact force is handled by a modified Herz collision model. In the problem of launching a missile from the water surface, the change characteristics of the flow field, the load response characteristics, and the relative motion laws of the missile and the launching platform during the catapulting process are investigated. The results show that the motion laws of the projectile and the launch tube in the constrained direction are the same, and the established coupling model is able to simulate the launch separation process of the missile in the constrained state. In addition, the effect of wind load on the missile ejection process is analyzed using the coupled model. [ABSTRACT FROM AUTHOR]

Published

2024

4. An Experimental and Numerical Study on the Lateral Stiffness Limits of Straddle-Type Monorail Tour-Transit Systems.

Author

Zhang, Hong, Wang, Pengjiao, Li, Qin, Jin, Junhui, Wei, Shiqi, Guo, Fengqi, Feng, Cheng, and Deng, Qun

Subjects

MULTIBODY systems, LATERAL loads, FINITE element method, WIND pressure, SENSITIVITY analysis

Abstract

The development of the straddle-type monorail tour-transit system (MTTS) has received keen attention. Regarding the unspecified regulations on the lateral stiffness limit of steel substructures, which is essential for the design of MTTSs, this work presents a comprehensive assessment of the issue. Firstly, a wind–vehicle–bridge coupling model was established, integrating multibody dynamics and finite element methods. This model was then validated against field test results, considering measured track irregularities and simulated wind loadings as the excitations. Afterwards, a trend analysis and a variance-based sensitivity analysis was performed to investigate the effect of various factors on the dynamic response of the MTTS. Results indicate that the pier height significantly impacts the lateral displacement of the pier top, accounting for 87% of the first-order sensitivity index and 75% of the total sensitivity index. In comparison, the lateral stiffness of track beams contributes over 70% to the maximum responses at the mid-span. Based on this, two responses, the lateral displacement of the pier top and the lateral deflection–span ratio of the track beam, were utilized as evaluation indicators. With the analysis of indicators in terms of lateral acceleration, Sperling index, and lateral wheel force, the limited values for the two indicators were determined as 8.04 mm and L/4200, respectively. These findings can serve as valuable references for future research and designs in this field. [ABSTRACT FROM AUTHOR]

Published

2024

5. Optimization of Potato Planter Soil Lifting Device Based on TRIZ Theory.

Author

Zhang, Hua, Li, Hongling, Sun, Wei, Li, Hui, Liu, Xiaolong, Sun, Gang, Lu, Yonggang, Chen, Yangzhou, and Xing, Wei

Subjects

TRIZ theory, SOLIFLUCTION, FOOD production, DYNAMIC models, MULCHING, POTATOES

Abstract

Aiming at the problems of low soil cover and serious wear and tear of transmission parts in the soil lifting device of potato planters, this paper carries out innovative optimization design of its key parts based on TRIZ theory. The discrete element model of the soil model and the multi-body dynamic model of the soil lifting device are established, the upper scraping and lower scraping soil lifting devices are simulated respectively through the method of DEM-MBD coupling, and the working mechanism of the soil lifting device is further explored. The simulation results show that the lower scraping type lifting device has a large conveying capacity and a stable flow rate at the soil outlet. The results of the soil tank performance comparison test show that: the improved soil lifting device has a simple structure, large conveying capacity, stable flow rate, and fast flow speed and is not easily congested. It meets the standard requirements of dryland potato seedling strip mulching planting technology on mulching parameters and is of great significance for improving dryland food production on the Loess Plateau. [ABSTRACT FROM AUTHOR]

Published

2024

6. 基于多体动力学的飞剪高速振动优化.

Author

夏志昊, 龚俊杰, 韦源源, 郝文峰, 陈扬东, and 王金荣

Subjects

SHEARS (Machine tools), TRANSIENTS (Dynamics), FLYING machines, VIBRATION tests, DYNAMIC simulation, MULTIBODY systems

Abstract

Copyright of Machine Tool & Hydraulics is the property of Guangzhou Mechanical Engineering Research Institute (GMERI) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

7. Innovative design and experimental validation of dynamic balance in rotary compressors based on particle damping energy dissipation technology.

Author

Arifin, Achmad, Wang, I-Cheng, and Wu, Yu-Ren

Subjects

*DISCRETE element method, *DYNAMIC balance (Mechanics), *ENERGY dissipation, *COEFFICIENT of restitution, *INELASTIC collisions

Abstract

Dynamic imbalance is one of the primary issues in rotary compressor applications, which can generate significant vibration. A dynamic balance design is required to minimize the moment and additional inertia force, which can be eliminated by adding a counterweight. This paper utilized a solid plate that has cavities filled with particle damper as a novel design to satisfy the dynamic balance. Vibrational energy is dissipated in collisions between particles through momentum exchange and is converted into energy for consumption that consists of inelastic collision energy and frictional energy. The discrete element method (DEM) and multi-body dynamics (MBD) were applied for two-way coupling for a dynamic balance simulation. The impact of particle size, friction coefficient, and restitution coefficient on energy dissipation in rotary compressors was evaluated, and the particle radius of 1 mm produced the most satisfactory. The experiment measured the vibrational acceleration in the tangential and radial directions at a particular duration and frequency to reflect the particle damper's dynamic balance and energy dissipation effect. Both simulation and experimental results confirmed that the novel design features are more acceptable than the original to satisfy the dynamic balance of a rotary compressor. [ABSTRACT FROM AUTHOR]

Published

2024

8. Simulation and Optimization of a Rotary Cotton Precision Dibbler Using DEM and MBD Coupling.

Author

Wang, Long, Ran, Xuyang, Shi, Lu, Xing, Jianfei, Wang, Xufeng, Hou, Shulin, and Li, Hong

Subjects

DISCRETE element method, DRILLS (Planting machinery), PLANT performance, COTTON quality, SEEDS

Abstract

Investigating the seeding mechanism of precision seeders is of great significance for improving the quality of cotton sowing operations. This paper designs a rotary type-hole cotton precision mulching dibbler. The main factors influencing the entry of cotton seeds into the seed wheel holes during the seeding process are then theoretically analyzed. Following this, an accurate discrete element model of coated cotton seeds is established and combined with a discrete element method (DEM) and multi-body dynamics (MBD)-coupled simulation model of the seed drill for seed picking and planting. Simulation experiments on the seeding performance of the precision dibbler were performed to study the influence of the seed wheel structure and motion parameters on the picking and planting performance under different speeds. The optimal parameter combination for the seed wheel is obtained through optimization experiments, and a precision dibbler is manufactured for bench testing. The bench test results are consistent with the simulation test results. At the precision dibbler rotation speed of 16 r/min, the qualified index reaches a maximum value of 93.28%, the skip sowing index increases with the precision dibbler rotation speed, and the re-sowing index decreases as the speed increases. These optimization results significantly improved seeding precision and efficiency and are of great significance for the reliability and effectiveness of cotton sowing operations. [ABSTRACT FROM AUTHOR]

Published

2024

9. Formation Mechanism of Rail Corrugation for Modern Tram Lines.

Author

Zhiqiang Wang, Zhenyu Lei, and Jianyue Zhu

Subjects

*WAVELENGTHS, *DIAMETER, *VELOCITY, *PROBABILITY theory, *WHEELS, *BOGIES (Vehicles)

Abstract

In order to explain the phenomenon of corrugation on measured line sections of the modern tram, a numerical model of modern tram-track coupling has been established by utilizing the multi-body dynamics method, and the formation mechanism of corrugation has been studied from the perspective of wheel-rail contact creep. The results show that the smaller the curve radius is, the greater the probability of corrugation occurs. The corrugation wavelength range is 40 mm~50 mm, the wave depth range is 0.05 mm~0.1 mm, and the wave depth is relatively small compared with the corrugation wave depth of metro lines, which is in line with the characteristics of the light-load operation of the tram. The formation mechanism of corrugation on modern tram sharp curves can be described as wheel-rail contact creep saturation leads to the generation of corrugation, and the source of creep is related to the guiding mechanism of the longitudinally coupled independent wheelset bogie. The formation of corrugation on the straight line of the modern tram is related to the difference in wheel diameters between the front and rear wheelsets on the same side, which can lead to different longitudinal velocities, thus generating longitudinal creep forces and inducing rail corrugation. [ABSTRACT FROM AUTHOR]

Published

2024

10. Digital twin model of a large scale hot molten metal ladle pouring system.

Author

Popov, Ivan and Griffiths, Christian A.

Subjects

*GANTRY cranes, *LIQUID metals, *DIGITAL twins, *CRANES (Machinery), *BUILDING design & construction

Abstract

In steel-making processes, large quantities (frequently exceeding 300 t) of liquid metal are transferred between vessels. In Basic Oxygen Steel (BOS) making process, metal is poured from Hot Metal (HM) ladles, utilising overhead gantry cranes, into furnaces for further processing. Due to the large quantities of liquid metal poured, this operation poses significant safety concerns associated with metal spillage and releases of heat emissions. This can further lead to damage being caused to surrounding infrastructure. Pouring automation can reduce the likelihood of metal spillage, optimising ladle movement for reduction in heat emission releases. Given the hazardous nature of this operation, robust testing and evaluation of automated crane pouring movements is required prior to their application. A digital twin (DT) model of an overhead gantry crane/HM ladle system is presented here, intended to provide a safe testing environment for controlled pouring movement and serve as a testbed for control system design studies. Accurate crane movement is achieved using multi-body dynamics, solving for non-linearities present due to rigid joint frictional components. The flow rate of HM is estimated through the application of a dynamic model, allowing the modelling of system dynamics due to differences in HM pouring weights. The devised DT model is evaluated by simulating real crane movement and making a comparison on the resultant changing HM weight inside the ladle. The devised DT removes the need for construction of a physical model or performing tests directly on the HM pouring system. [ABSTRACT FROM AUTHOR]

Published

2024

11. Integrated FEM-Multibody Co-Simulation of Additively Manufactured Hip Prosthesis containing cracks.

Author

Domenico Gentile, Roberto Di Bona, Giuseppe Peter Vanoli, Gabriel testa, and Sara Ricci

Subjects

Fracture mechanics, Co-simulation, Multi-body Dynamics, FEM, Additive manufacturing, Hip prosthesis, Mechanical engineering and machinery, TJ1-1570, Structural engineering (General), TA630-695

Abstract

The increase in life expectancy and attention to the quality of life of elderly people spurred the need, in the last decades, to increase the capabilities of medical and surgical techniques. Among these, the development of prosthetic implants has been a staple of biomedical engineering research since the 70’s. In order to satisfy the challenging demands, the latest novelties in industrial engineering are being tested in their applicability to subjects. The 3D printing of metal alloys can produce a highly customizable product, which, after the proper heat treatments, can possess adequate mechanical properties to ensure a satisfactory component life. Defective products are often the results of wrong or absent post-processing treatments which may cause an uncontrolled crack propagation and a premature total failure of the implant. The behavior of such a product, with various critical crack conditions, was investigated by an integrated MBD-FEM co-simulation environment, focused on a femur subjected to total hip replacement. It was concluded that the Stress Intensity Factor (SIF) computed by the model is compatible with the premature failures experienced by patients, and as such, this model opens the possibility for further analyses aimed at understanding the role of defects on the durability of prothesis

Published

2024

12. Experimental Testing for the Validation of a Multi-body Dynamics Model for a Novel Electric Bus

Author

Kehoe, Patrick, Jafroudi, Nima, Oubahou, Rayane Ait, Toma, Elton, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Tolio, Tullio A. M., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Schmitt, Robert, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Huang, Wei, editor, and Ahmadian, Mehdi, editor

Published

2024

13. Research on Wading Mobility of a Certain Type of Special Vehicle Based on MPS Method

Author

Hao, Yiyang, Zhou, Yunbo, Zhang, Ming, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Tolio, Tullio A. M., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Schmitt, Robert, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Halgamuge, Saman K., editor, Zhang, Hao, editor, Zhao, Dingxuan, editor, and Bian, Yongming, editor

Published

2024

14. Dynamics Characteristics Analysis of Rack Railway Guiding Equipment of Mountain Rack Railway Train with Considering Wheel-Rail Contact

Author

Wang, Haowen, Xiang, Quanming, Liu, Weiping, Gao, Chang, Liu, Jialin, Wang, Shisong, Deng, Xingqiao, Ceccarelli, Marco, Series Editor, Corves, Burkhard, Advisory Editor, Glazunov, Victor, Advisory Editor, Hernández, Alfonso, Advisory Editor, Huang, Tian, Advisory Editor, Jauregui Correa, Juan Carlos, Advisory Editor, Takeda, Yukio, Advisory Editor, Agrawal, Sunil K., Advisory Editor, Tan, Jianrong, editor, Liu, Yu, editor, Huang, Hong-Zhong, editor, Yu, Jingjun, editor, and Wang, Zequn, editor

Published

2024

15. Dynamic Modeling and Simulation of a Crocodile-Like Robot

Author

Kuang, Le, Zhuo, Zhiqin, Zeng, Qin, Jiang, Jianping, Luo, Jiahui, Xu, Xiaoming, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Rui, Xiaoting, editor, and Liu, Caishan, editor

Published

2024

16. Wind Turbine Dynamic Response in an Offshore Wind Farm with Wake Effects

Author

Cen, Sheng, Qiu, Yingning, Li, Mengfei, Feng, Yanhui, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Rui, Xiaoting, editor, and Liu, Caishan, editor

Published

2024

17. Critical Length Analysis for Linear Growth of Frictional Resistance of Moving Flexible Screen String in Horizontal Borehole

Author

Wang, Yong-hong, Gao, Xiang, Liu, Xin-yang, Hu, Zhong-zhi, Wu, Wei, Series Editor, and Lin, Jia'en, editor

Published

2024

18. A Novel Dynamic and Aerodynamic Intelligent Morphing System (DA-IMS) for the Stability of an Autonomous Utility Truck with the Boom Equipment

Author

Patel, Parth Y., Koomullil, Roy, Vantsevich, Vladimir, and Azimov, Dilmurat, editor

Published

2024

19. Multibody dynamics system with energy dissipation by hardening and softening plasticity.

Author

Ljukovac, Suljo, Ibrahimbegovic, Adnan, Imamovic, Ismar, and Mejia-Nava, Rosa-Adela

Abstract

In this work we present a multibody dynamics system composed of geometrically exact nonlinear beams with inelastic behavior, representing flexible system components. The main focus of the work is to introduce advanced energy dissipation models using hardening and softening plasticity into such beam models and to show how they can also recover a vibration amplitude decay typical of viscous damping. The damping model is represented by the constitutive behavior of the flexible beam element chosen as an elasto-viscoplastic response with linear isotropic hardening and subsequent softening plasticity. The formulation is cast within the mixed variational framework, where the strong embedded discontinuity is introduced into displacement/rotation fields in the softening phase leading to localized plastic deformation. We also aim to ensure model capabilities to deliver results for long-term loading simulations, which is of interest for quantifying the risk of fatigue failure for such flexible system component. The corresponding numerical implementation combines the space discretization based on the finite element method with the time discretization based upon energy-conserving or energy-decaying integration schemes. The results of several numerical simulations are presented in the dynamics of flexible-rigid multi-body systems to illustrate a very satisfying performance of the proposed model. [ABSTRACT FROM AUTHOR]

Published

2024

20. 三大件式转向架斜楔建模方法及其对车辆 动力学性能仿真结果的影响.

Author

陈龙飞, 王 勇, 缪 昆, and 李 龙

Abstract

Copyright of Rolling Stock (1002-7602) is the property of Rolling Stock Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

21. Modelling of a 12-DoF Parachute–Riser–Payload system dynamics using Kane's method.

Author

Iyer, Prashant G.

Abstract

The dynamic behaviour of parachutes is highly complex and characterised by non-linear, time-dependant, Fluid–Structure Interactions, which is computationally intensive and hence not a viable option for incorporating into trajectory simulations. The paper describes modelling of a "Computationally efficient, High Fidelity Multi-Body" Parachute–Elastic Riser–Payload system, capable of simulating trajectory from parachute deployment to parachute separation. The matrix form of Kane's method is used to derive the kinematic and dynamic equations of motion for the system, which avoids the complications of symbolically deriving these equations. The developed model is validated with published literature results formulated using the Newton–Euler method and simulation results describing the typical trajectory and attitude of the system during the descent phase are presented. [ABSTRACT FROM AUTHOR]

Published

2024

22. Dynamic analysis of cislunar suspension tether swings.

Author

Weiwei, Wang, Zhigang, Wu, and Jiafu, Liu

Subjects

*LUNAR surface, *MULTIBODY systems, *ROTATION of the earth, *SURFACE of the earth, *EULER-Lagrange equations, *LAGRANGE equations

Abstract

The Cislunar Suspension Tether is a kind of ultra-long tether anchored to the Moon's surface and extending to the Earth's vicinity, looks like hanging from the Moon above the Earth. The tether is expected to be used for transportation between the Earth and Moon. The feasibility of constructing such a long tether in the cislunar space far away from the Earth has been validated by studying the statics of the tether with distributed mass by the current authors. In addition, dynamics of such tethered system with various initial conditions and small perturbations should be investigated. In this paper, the main dynamic characteristics of the tether are analyzed using the multi-body dynamic model. In the framework of elliptic Earth-Moon restricted three-body system, the tethered system with distributed mass is discretized using lumped masses connected by massless viscoelastic springs. The dynamic equations of the space tethered system are derived using the Lagrange method after obtaining the global potential and kinetic energies of the system. The tethered system is regarded as a Rooted-Tree System in the Earth-Moon restricted three-body system since the Moon with known motion is taken as the root of the system. The dynamic responses of each lumped mass are examined and the springs merely experiencing tensile forces rather than compressional forces are considered. The in-plane libration and elongation of the tether for the circular and elliptic cases with various initial (position and velocity) conditions are explored. Various dynamic characteristics of the tethered system influenced by the eccentricity and initial conditions are addressed and the results indicate that the extremely long lunar anchored tethered system is feasible as long as the initial conditions of the system fall into proper ranges. Some other conclusions are also presented based on the numerical experiments. • Simulation of ultra-long tether swings in the Earth-Moon restricted three-body system. • A Rooted-Tree System and its dynamic equations derived using the Euler-Lagrange equation method. • Various dynamic characteristics of the CST system influenced by the eccentricity and initial conditions. • The CST can maintain stable motion with the Moon by proper condition, but collapse or chaos by bad situation. [ABSTRACT FROM AUTHOR]

Published

2024

23. Multi-body dynamics in vehicle engineering.

Author

Rahnejat, H., Johns-Rahnejat, P.M., Dolatabadi, N., and Rahmani, R.

Abstract

Since Euler's original gyro-dynamic analysis nearly two and a half centuries ago, the use of multi-body dynamics (MBD) has spread widely in application scope from large displacement rigid body dynamics to infinitesimal amplitude elastodynamics. In some cases, MBD has become a multi-physics multi-scale analysis, comprising contact mechanics, tribo-dynamics, terramechanics, thermodynamics, biomechanics, etc. It is an essential part of all analyses in many engineering disciplines, including vehicle engineering. This paper provides an overview of historical developments with emphasis on vehicle development and investigation of observed phenomena, including noise, vibration and harshness. The approach undertaken is comprehensive and provides a uniquely focused perspective, one which has not hitherto been reported in the literature. [ABSTRACT FROM AUTHOR]

Published

2024

24. Development of longitudinal vibration isolator between carbody and bogie for railway vehicle (Study on characteristics of the device by multi-body dynamics model)

Author

Ryo FUNADA, Yuki AKIYAMA, Tadao TAKIGAMI, and Yasunobu MAKITA

Subjects

railway vehicle, multi-body dynamics, elastic vibration, hunting, running resistance, Mechanical engineering and machinery, TJ1-1570, Engineering machinery, tools, and implements, TA213-215

Abstract

Carbody elastic vibration of a railway vehicle negatively affects the ride comfort of passengers. One of the sources of the vibration is excitation force induced by the longitudinal vibration of the bogies. The excitation force transmits to the carbody through longitudinal coupling devices between the bogie and the carbody, such as traction links and yaw dampers. Since the longitudinal coupling devices can affect running stability of the vehicle, it is necessary to develop a device which copes with both vibration reduction and running stability. The purpose of this study is to develop a device which achieves both vibration reduction and the running stability. To confirm the vibration isolation performance and also to evaluate the running stability, using multi-body dynamics software, we construct a simulation model of a test vehicle equipped with traction links and yaw dampers with rubber bushes. The simulation reveals that the elastic vibration can be reduced by the traction links equipped with soften rubber bushes. On the other hand, running stability decreases under the condition that the rubber bush of the traction link is soft, especially under the condition when another damper fails. In the simulation, we investigate the desirable displacement-load characteristics of a rubber bush for the traction link in order to reduce the carbody elastic vibration and to secure the running stability. As a result, we confirm that it is possible to cope with both vibration reduction and the running stability by configuring parameters on displacement-load characteristics of rubber bush so that the rubber bushes vibrate in small stiffness at micro amplitude and in large stiffness at large amplitude. Furthermore, we propose a design method of the vibration isolator considering running resistance, and confirm the effectiveness of the method on both vibration reduction and security of the running stability.

Published

2024

25. Coupled Modeling of Sea Surface Launch Flow and Multi-Body Motion

Author

Haotian Liu, Shangming Li, Shilong Hou, and Debin Fu

Subjects

water surface launch, gas ejection, coupling effect, separation motion, multi-body dynamics, Naval architecture. Shipbuilding. Marine engineering, VM1-989, Oceanography, GC1-1581

Abstract

To simulate the launching process of missile complex flow, movement, and constraint states, a multifield coupling model is put forward based on a computational fluid dynamics (CFD) method. In this coupled model, a CFD method is used to solve the three-dimensional compressible transient flow, and the six-degree motion of the launching platform is considered, and the virtual contact method is used to deal with the constraint states of the guideway and the slider. The active force and moment are applied to the launching platform to simulate its rolling, pitching, and heaving motions under the 5-level waves. Collision detection is carried out through the minimum clearance distance between the slider and the guideway, and the contact force is handled by a modified Herz collision model. In the problem of launching a missile from the water surface, the change characteristics of the flow field, the load response characteristics, and the relative motion laws of the missile and the launching platform during the catapulting process are investigated. The results show that the motion laws of the projectile and the launch tube in the constrained direction are the same, and the established coupling model is able to simulate the launch separation process of the missile in the constrained state. In addition, the effect of wind load on the missile ejection process is analyzed using the coupled model.

Published

2024

26. Optimization of Potato Planter Soil Lifting Device Based on TRIZ Theory

Author

Hua Zhang, Hongling Li, Wei Sun, Hui Li, Xiaolong Liu, Gang Sun, Yonggang Lu, Yangzhou Chen, and Wei Xing

Subjects

TRIZ theory, innovative design, discrete elements, multi-body dynamics, coupled DEM-MBD simulation, Agriculture (General), S1-972

Abstract

Aiming at the problems of low soil cover and serious wear and tear of transmission parts in the soil lifting device of potato planters, this paper carries out innovative optimization design of its key parts based on TRIZ theory. The discrete element model of the soil model and the multi-body dynamic model of the soil lifting device are established, the upper scraping and lower scraping soil lifting devices are simulated respectively through the method of DEM-MBD coupling, and the working mechanism of the soil lifting device is further explored. The simulation results show that the lower scraping type lifting device has a large conveying capacity and a stable flow rate at the soil outlet. The results of the soil tank performance comparison test show that: the improved soil lifting device has a simple structure, large conveying capacity, stable flow rate, and fast flow speed and is not easily congested. It meets the standard requirements of dryland potato seedling strip mulching planting technology on mulching parameters and is of great significance for improving dryland food production on the Loess Plateau.

Published

2024

27. An Experimental and Numerical Study on the Lateral Stiffness Limits of Straddle-Type Monorail Tour-Transit Systems

Author

Hong Zhang, Pengjiao Wang, Qin Li, Junhui Jin, Shiqi Wei, Fengqi Guo, Cheng Feng, and Qun Deng

Subjects

monorail tour-transit system, lateral stiffness, finite element modelling, multi-body dynamics, dynamic response, sensitivity analysis, Building construction, TH1-9745

Abstract

The development of the straddle-type monorail tour-transit system (MTTS) has received keen attention. Regarding the unspecified regulations on the lateral stiffness limit of steel substructures, which is essential for the design of MTTSs, this work presents a comprehensive assessment of the issue. Firstly, a wind–vehicle–bridge coupling model was established, integrating multibody dynamics and finite element methods. This model was then validated against field test results, considering measured track irregularities and simulated wind loadings as the excitations. Afterwards, a trend analysis and a variance-based sensitivity analysis was performed to investigate the effect of various factors on the dynamic response of the MTTS. Results indicate that the pier height significantly impacts the lateral displacement of the pier top, accounting for 87% of the first-order sensitivity index and 75% of the total sensitivity index. In comparison, the lateral stiffness of track beams contributes over 70% to the maximum responses at the mid-span. Based on this, two responses, the lateral displacement of the pier top and the lateral deflection–span ratio of the track beam, were utilized as evaluation indicators. With the analysis of indicators in terms of lateral acceleration, Sperling index, and lateral wheel force, the limited values for the two indicators were determined as 8.04 mm and L/4200, respectively. These findings can serve as valuable references for future research and designs in this field.

Published

2024

28. Mechanism of manual tamping operation for ballast bed based on DEM–MBD coupling

Author

Qian, Zhongxia, Xiao, Hong, Feng, Ruiling, Zhang, Zhihai, Nadakatti, Mahantesh M, and Fang, Jia

Published

2024

29. MBD-CFD Coupled Analysis for Design Verification of Aircraft Flap Mechanism

Author

Chung, Min Gyu, Han, Jong Yun, Kim, Kyu Beom, and Yun, Gun Jin

Published

2024

30. A study on theoretical predictive model and experimental findings of melt‐electrospinning process.

Author

Wubneh, Abiy, Kim, Chun‐Il, and Ayranci, Cagri

Subjects

POLYLACTIC acid, PREDICTION models, MANUFACTURING processes, EXPERIMENTAL design

Abstract

The current study extends a previous work published by the authors in which an analytical predictive model is proposed to simulate the melt‐electrospinning process. The analytical model is specifically designed to predict the various behaviors of the melt‐electrospun fiber under different material and processing conditions. A brief discussion of this model is presented here to establish context and help the reader capture the modeling philosophy employed. The current study complements the previous work by focusing on the experimental aspects of the research. Correlations between the independent process parameters and the topological attributes of the melt‐electrospun fibers are investigated and compared with findings from the theoretical model. The effects of changes in the process parameters on average fiber diameters and the collection diameter are experimentally analyzed using the design of experiments (DOE) techniques. Toward this end, polylactic acid (PLA) is melt‐electrospun at different treatment levels of the processing parameters in a controlled environment. Two regression‐based models—one for predicting the collection diameter and the other for the fiber diameter—are derived from the DOE data for benchmarking and quantitative evaluation of the predictive performance of the theoretical model. The theoretical model is run based on the same treatment levels as the experiment. The elastic parameter values used in the theoretical simulation are extracted from rheological tests. Comparison between the simulated and the observed fiber characteristics revealed that the collector diameter predictions by the theoretical model exhibited approximately a 16.7% difference compared to 24.2% for the average fiber diameter. Finally, a discussion is presented on the challenges and potential factors contributing to the observed differences. Overall, given the identified challenges and gaps in material characterization, the results of the theoretical predictive model are encouraging. [ABSTRACT FROM AUTHOR]

Published

2024

31. Dynamic Performance Optimization of Monorail Rapid Transit Formation Vehicles Based on Improved Artificial Potential Field Algorithm.

Author

Haoxin WU, Zixue DU, Zhen YANG, and Xiaoxia WEN

Subjects

*ALGORITHMS, *ACCELERATION (Mechanics), *VEHICLE models, *DYNAMIC models

Abstract

This paper presents a new type of monorail rapid transit vehicle, which can operate in formation. In order to optimize the dynamic performance of the formation vehicles when passing through the small radius curve, this paper first analyzes the structure of the new monorail rapid transit vehicle, and establishes the vehicle dynamic model and multibody dynamics simulation model. Then the improved artificial potential field algorithm is used to build the formation vehicle operation controller. Finally, the dynamic performance evaluation index of the new monorail rapid transit formation vehicle is formulated, and the formation vehicle passing through the small radius curve scene is simulated. The simulation results show that the controller of the formation vehicle with dynamic optimization control can effectively optimize the load transfer coefficient of running wheels, unbalanced centrifugal acceleration and roll angle of vehicle body when passing through the curve. Through this control method, the dynamic performance of formation vehicles passing through small radius curve lines can be optimized. [ABSTRACT FROM AUTHOR]

Published

2024

32. Prediction and Analysis of Vehicle Interior Road Noise Based on Mechanism and Data Series Modeling.

Author

Pang, Jian, Mao, Tingting, Jia, Wenyu, Jia, Xiaoli, Dai, Peisong, and Huang, Haibo

Subjects

TRAFFIC noise, AUTOMOBILE noise, DYNAMIC models, PREDICTION models, DATA quality

Abstract

Currently, the inexorable trend toward the electrification of automobiles has heightened the prominence of road noise within overall vehicle noise. Consequently, an in-depth investigation into automobile road noise holds substantial practical importance. Previous research endeavors have predominantly centered on the formulation of mechanism models and data-driven models. While mechanism models offer robust controllability, their application encounters challenges in intricate analyses of vehicle body acoustic-vibration coupling, and the effective utilization of accumulated data remains elusive. In contrast, data-driven models exhibit efficient modeling capabilities and can assimilate conceptual vehicle knowledge, but they impose stringent requirements on both data quality and quantity. In response to these considerations, this paper introduces an innovative approach for predicting vehicle road noise by integrating mechanism-driven and data-driven methodologies. Specifically, a series model is devised, amalgamating mechanism analysis with data-driven techniques to predict vehicle interior noise. The simulation results from dynamic models serve as inputs to the data-driven model, ultimately generating outputs through the utilization of the Long Short-Term Memory with Autoencoder (AE-LSTM) architecture. The study subsequently undertakes a comparative analysis between different dynamic models and data-driven models, thereby validating the efficacy of the proposed series vehicle road noise prediction model. This series model, encapsulating the rigid-flexible coupling dynamic model and AE-LSTM series model, not only demonstrates heightened computational efficiency but also attains superior prediction accuracy. [ABSTRACT FROM AUTHOR]

Published

2024

33. HE63 卧式加工中心多体动力学仿真分析.

Author

卢强, 陆会鉴, and 李军强

Abstract

Copyright of Machine Tool & Hydraulics is the property of Guangzhou Mechanical Engineering Research Institute (GMERI) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

34. Determinant of Dynamics and Interfacial Forces in Ultraprecision Machining of Optical Freeform Surface through Simulation-Based Analysis.

Author

Khaghani, Ali, Ivanov, Atanas, and Cheng, Kai

Subjects

INTERFACE dynamics, WORKPIECES, METALLIC composites, MACHINING, DIAMOND turning, FLUID-film bearings, MOTION control devices

Abstract

This study delves into the intricacies of ultraprecision machining, particularly in the context of machining optical freeform surfaces using Diamond Turning Machines (DTMs). It underscores the dynamic relationship between toolpath generation, hydrostatic bearing in DTMs, and the machining process. Central to this research is the innovative introduction of Metal Matrix Composites (MMCs) to replace the traditional materials used in designing linear bearings. This strategic substitution aims to dynamically enhance both the accuracy and the quality of the machined optical freeform surfaces. The study employs simulation-based analysis using ADAMS to investigate the interfacial cutting forces at the tooltip and workpiece surface and their impacts on the machining process. Through simulations of STS mode ultraprecision machining, the interfacial cutting forces and their relationship with changes in surface curvatures are examined. The results demonstrate that the use of MMC material leads to a significant reduction in toolpath pressure, highlighting the potential benefits of employing lightweight materials in improving the dynamic performance of the system. Additionally, the analysis of slideway joints reveals the direct influence of interfacial cutting forces on the linear slideways, emphasising the importance of understanding and controlling these forces for achieving higher-precision positioning and motion control. The comparative analysis between steel and MMC materials provides valuable insights into the effects of material properties on the system's dynamic performance. These findings contribute to the existing body of knowledge and suggest a potential shift towards more advanced precision forms, possibly extending to pico-engineering in future systems. Ultimately, this research establishes a new standard in the field, emphasising the importance of system dynamics and interfacial forces in the evolution of precision manufacturing technologies. [ABSTRACT FROM AUTHOR]

Published

2023

35. Multi-body dynamics model for spent nuclear fuel transportation system under normal transport test conditions

Author

Seongji Han, Gil-Eon Jeong, Hyeonbeen Lee, Woo-Seok Choi, and Jin-Gyun Kim

Subjects

Spent nuclear fuel, Normal transport, KORAD-21, Multi-body dynamics, Durability, Nuclear engineering. Atomic power, TK9001-9401

Abstract

The transportation of spent nuclear fuel is an important process that involves road and sea transport from an interim storage facility to storage and final disposal sites. As spent nuclear fuel poses a significant risk, carefully evaluating its vibration and shock characteristics under normal transport conditions is essential. In this regard, full-scale multi-modal transport tests (MMTT) have been conducted domestically and internationally. In this paper, we discuss the process of developing a multi-body dynamics (MBD) model to analytically simulate conditions that cannot be considered in tests. The MBD model is based on the KORAD-21 transportation system was validated using the Korean MMTT results from 2020 to 2021. This paper summarizes the details of the development and verification of the MBD model for the KORAD-21 transportation system under normal transport test conditions. This approach can be applicable to various transportation scenarios and systems, and the results of this study will help to ensure that nuclear fuel transportation is conducted safely and effectively.

Published

2023

36. Simulation and Optimization of a Rotary Cotton Precision Dibbler Using DEM and MBD Coupling

Author

Long Wang, Xuyang Ran, Lu Shi, Jianfei Xing, Xufeng Wang, Shulin Hou, and Hong Li

Subjects

discrete element method, multi-body dynamics, coupling simulation, dibbler, Agriculture (General), S1-972

Abstract

Investigating the seeding mechanism of precision seeders is of great significance for improving the quality of cotton sowing operations. This paper designs a rotary type-hole cotton precision mulching dibbler. The main factors influencing the entry of cotton seeds into the seed wheel holes during the seeding process are then theoretically analyzed. Following this, an accurate discrete element model of coated cotton seeds is established and combined with a discrete element method (DEM) and multi-body dynamics (MBD)-coupled simulation model of the seed drill for seed picking and planting. Simulation experiments on the seeding performance of the precision dibbler were performed to study the influence of the seed wheel structure and motion parameters on the picking and planting performance under different speeds. The optimal parameter combination for the seed wheel is obtained through optimization experiments, and a precision dibbler is manufactured for bench testing. The bench test results are consistent with the simulation test results. At the precision dibbler rotation speed of 16 r/min, the qualified index reaches a maximum value of 93.28%, the skip sowing index increases with the precision dibbler rotation speed, and the re-sowing index decreases as the speed increases. These optimization results significantly improved seeding precision and efficiency and are of great significance for the reliability and effectiveness of cotton sowing operations.

Published

2024

37. Multi-body Dynamics Simulations of Spacecraft Docking by Monte Carlo Technique

Author

Chand, V. Sri Pavan Ravi, Rai, Vijay Shankar, Ramana, M. Venkata, Srivastava, Anoop Kumar, Kapoor, Abhinandan, Narayana, B. Lakshmi, Nagaraj, B. P., Kumar, H. N. Suresha, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Li, Yong, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Oneto, Luca, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zamboni, Walter, Series Editor, Zhang, Junjie James, Series Editor, Tan, Kay Chen, Series Editor, Sharma, Sanjay, editor, Subudhi, Bidyadhar, editor, and Sahu, Umesh Kumar, editor

Published

2023

38. Modeling and Design of a Bilaterally Statically Balanced Passive Exoskeleton

Author

Victorette, André W. D. B., Simas, Henrique, de Souza Vieira, Rodrigo, da Silva, Esdras S., Martins, Daniel, Ceccarelli, Marco, Series Editor, Agrawal, Sunil K., Advisory Editor, Corves, Burkhard, Advisory Editor, Glazunov, Victor, Advisory Editor, Hernández, Alfonso, Advisory Editor, Huang, Tian, Advisory Editor, Jauregui Correa, Juan Carlos, Advisory Editor, Takeda, Yukio, Advisory Editor, and Okada, Masafumi, editor

Published

2023

39. Numerical Estimation of Base Reactions of an Underwater Manipulator with Variable Drag Coefficients

Author

Kumar, Chandan, Reddy, N. Srinivasa, Chatterjee, Dipankar, Saha, Pratik, Nandy, Sambhunath, Sen, Soumen, Chaari, Fakher, Series Editor, Gherardini, Francesco, Series Editor, Ivanov, Vitalii, Series Editor, Haddar, Mohamed, Series Editor, Cavas-Martínez, Francisco, Editorial Board Member, di Mare, Francesca, Editorial Board Member, Kwon, Young W., Editorial Board Member, Trojanowska, Justyna, Editorial Board Member, Xu, Jinyang, Editorial Board Member, Sharma, Rohit, editor, Kannojiya, Ravindra, editor, Garg, Naveen, editor, and Gautam, Sachin S., editor

Published

2023

40. Review on Simulation and Optimization of Vehicle Ride Comfort Based on Suspension Model

Author

Jianghu, Tang, Qing, Xiong, Yingmou, Zhu, Zhuoyu, He, Ceccarelli, Marco, Series Editor, Agrawal, Sunil K., Advisory Editor, Corves, Burkhard, Advisory Editor, Glazunov, Victor, Advisory Editor, Hernández, Alfonso, Advisory Editor, Huang, Tian, Advisory Editor, Jauregui Correa, Juan Carlos, Advisory Editor, Takeda, Yukio, Advisory Editor, Zhang, Hao, editor, Feng, Guojin, editor, Wang, Hongjun, editor, Gu, Fengshou, editor, and Sinha, Jyoti K., editor

Published

2023

41. Multi-body dynamics modeling and test of an articulated steering half-track tractor.

Author

Baocheng Zhou, Shiyu Chen, Jianing Hu, Yong You, Decheng Wang, and Qing Zhang

Subjects

*FARM tractors, *MULTIBODY systems, *TRACTORS, *DYNAMIC models, *AUTOMOBILE steering gear, *PAVEMENTS

Abstract

With the benefits of small turning radius and high trafficability, the articulated steering half-track tractor had been widely utilized in orchard and small spaced farmland. To study the dynamic performance of the articulated steering half-track tractor and provide a model basis for studying the path tracking control, an accurate multi-body dynamic model of the tractor was required. In this study, the crucial parameters in the dynamic model construction of the tractor were investigated. Firstly, the topology model of the components of the half-track tractor was built by RecurDyn, in which the movement subs and driver functions were given. Secondly, considering the difference of dynamic characteristic of the articulated steering tractor with respect to different pavement hardnesses, the soft and hard pavement models were constructed by employing the harmonic superposition method. Finally, the simulations of the half-track tractor under straight-line and swerve had been conducted on the two types of pavements, and the simulation results were compared with the experimental and theoretical results. The results indicated that the average speed error of the dynamic model on hard pavement and farmland soft pavement were 2.7% and 2.1% compared with the real tractor tests. At the same time, the straight-line driving offset errors of the dynamic model on the two pavements were 1.6% and 3.8% for the front wheels and the rear wheels offset errors were 3.9% and 2.4%, respectively. Furthermore, the turning radius error under front wheel steering was 8.2% and the error under articulated steering was 5.3%. It is proved that the established dynamic model had high accuracy, which provides an efficient approach to analyze the dynamic features of the half-track tractor. [ABSTRACT FROM AUTHOR]

Published

2023

42. 基于多体动力学的多轴载人离心机强度校核计算方法.

Author

岳琮镇, 牛红攀, 王鹏飞, 范志庚, and 尹娇妹

Abstract

Copyright of Journal of Mechanical Strength / Jixie Qiangdu is the property of Zhengzhou Research Institute of Mechanical Engineering and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

43. Investigation of Track Condition Effects on Fatigue of High-Speed Train Bogie Frames.

Author

Permana, Adhi Dharma and Putera, Rama Primadi

Subjects

BOGIES (Vehicles), HIGH speed trains, FATIGUE cracks, FINITE element method, LATERAL loads, RAILROAD trains

Abstract

The bogie is one of the critical components of a railway vehicle, especially that of a high-speed train. Fatigue damage and life prediction of a railway bogie frame for high-speed operation are performed based on multibody dynamics and the finite element method. The multibody dynamics incorporate track conditions, that include track irregularities in the vertical and lateral direction, for both left and right rails. This study also considers the track's curve radius and cant condition, and train speed of up to 100 m/s. The study findings show that the greater the speed, the tighter the curves, and the greater the cant difference to the equilibriumcant results in a higher damage level. In addition, the lateral damage due to combined vertical and lateral loading contributes more towards the overall combined damage level than that of the vertical. [ABSTRACT FROM AUTHOR]

Published

2023

44. 捕捉缓冲机构刚柔耦合多体动力学仿真研究.

Author

刁家宇, 李卫民, 袁学庆, 姜凯, and 赵一峰

Subjects

STRUCTURAL dynamics, DYNAMIC simulation, MULTIBODY systems, RESEARCH methodology, PERFORMANCE theory

Abstract

Copyright of Machine Tool & Hydraulics is the property of Guangzhou Mechanical Engineering Research Institute (GMERI) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

45. Dynamic behaviors of an integrated crawler mobile parallel robot in obstacle-crossing.

Author

An, Zhiguo, Zhou, Zhihong, Li, Dailin, and Gao, Zhengyuan

Abstract

A crawler mobile parallel robot equipped with swing arms has been proposed to improve the parallel robot's limited workspace and poor mobility. The robot's obstacle performance in the condition of step-climbing, gap-crossing, and hill-climbing was investigated through multi-body system simulation. The flexible body finite segment model method is used to model the crawler to simulate the dynamic behaviors. The results show that the motion of the parallel manipulator along the modified path is stable and continuous. The maximum step height for the robot in the forward and backward step-climbing is 170 and 160 mm, respectively. The maximum gap widths in the forward and backward gap-crossing are 420 and 615 mm, respectively. The maximum slope gradient is 20° in the hill-climbing. In the three circumstances of obstacle-crossing, with the increase in step height, gap width, and slope gradient, the crawler slip rate increases with a more significant fluctuation, resulting in a greater force and impact on the crawler. Compared with the forward step-climbing and gap-crossing, the robot moves more smoothly with less impact in backward conditions. The initial speed is critical to improving the forward gap-crossing and hill-climbing movement. The integrated crawler mobile parallel robot has the advantages of simple structure and excellent obstacle-crossing performance. [ABSTRACT FROM AUTHOR]

Published

2023

46. Dynamic characteristics analysis of long stroke reciprocating pump combined crank-linkage with rack-pinion mechanism.

Author

Huang, Qiyue, Hou, Yongjun, and Xi, Jianqiu

Abstract

Drilling pump is the heart of drilling rig, its core structure is crank-linkage mechanism. However, the drilling pump is criticized for its short stroke and high stroke frequency. Aiming at these defects, a long stroke reciprocating (LSR) pump combined the crank-linkage with a rack-pinion mechanism is proposed, and its dynamic and flow characteristics are researched. The results reveal that the stroke of the LSR pump is extended twice when the crank radius stays the same. The stroke frequency and flow pulsation rate are lowered under the same rated power. A new multi-fulcrum crankshaft is designed to extend its fatigue life, and the reaction forces of each fulcrum are solved by simulation. The influence of the fulcrums position on the crankshaft modal frequency is further investigated. The flexible characteristics of the multi-fulcrum crankshaft are studied by rigid-flexible coupled analysis. The results show that more fulcrums can effectively reduce the stress of crankshaft, and the maximum stress of the multi-fulcrum crankshaft is only 178.6 MPa. The modal frequency of the multi-fulcrum crankshaft is increased due to more fulcrums, which proved its stiffness and stability are improved. The fatigue life of the multi-fulcrum crankshaft is predicted to reach 30,000 h by finite element analysis. This study would provide a theoretical basis for further development of the LSR pump. [ABSTRACT FROM AUTHOR]

Published

2023

47. Numerical and experimental investigation on parameters determination of the suspension system for a high-speed train aiming at cross-line operation.

Author

Li, Yixiao, Sun, Jianfeng, Dai, Liangcheng, Guo, Zhaotuan, and Chi, Maoru

Abstract

Cross-line operation that can improve the utilization of railway equipment and transportation efficiency is expected to be the development of the future, and the key to realizing this is to guarantee the dynamics performance of high-speed trains operating on different railway lines. To this end, this study focuses on determining the parameters of a suspension system for a high-speed train equipped with semi-active dampers. Multi-body dynamics method is used to establish a mathematical model of a high-speed vehicle, and a numerical integration method is applied to calculate the system response. An improved genetic algorithm adopting the dynamic Hamming distance, dynamic crossover, and mutation coefficients is integrated into the numerical simulation process to determine the parameters. Based on the numerical analysis, the optimized damping values for various hydraulic dampers in their passive modes are obtained. Finally, an experimental validation based on roller-rig and field loop-line tests is performed, and the test results verify the effectiveness of the optimized parameters. Thus, the study findings can serve as a reference to enhance the realization of cross-line operation. [ABSTRACT FROM AUTHOR]

Published

2023

48. Optimized Design and Experiment of a Self-Covering Furrow Opener for an Automatic Sweet Potato Seedling Transplanting Machine.

Author

Wu, Guangwei, Wang, Shoujiang, Zhang, Anqi, Xiao, Yuejin, Li, Liwei, Yin, Yanxin, Li, Hanqing, Wen, Changkai, and Yan, Bingxin

Abstract

The yield and quality of sweet potatoes are significantly influenced by the transplantation posture of sweet potato seedlings. The performance of the sweet potato seedling transplanting opener directly affects the transplantation posture of sweet potato seedlings. In order to improve the yield and quality of sweet potatoes, this study proposes a joint simulation method based on discrete element and flexible multi body dynamics (DEM-FMBD), which optimizes the structure of a self-covering soil opener. By exploring the influence of self-covering soil trenchers on the planting depth and posture of sweet potato seedlings during horizontal transplantation, it was determined that the influencing factors of the experiment were wing spacing, soil reflux height, and soil reflux length. Based on the DEM-FMBD coupling simulation platform, single factor, and quadratic rotation orthogonal experiments were carried out. According to the results of the simulation test, the effect of the interaction of test factors on planting depth and planting attitude was analyzed by the response surface method. Finally, the optimal structural parameter combination was obtained by a multi-objective optimization method: the spacing of the wings was 58 mm, the height of the soil backflow port was 71 mm, and the length of the soil backflow port was 163 mm; thus, the quality of transplanting is improved effectively. This study provides the method and theory reference for the study of sweet potato transplanting. [ABSTRACT FROM AUTHOR]

Published

2023

49. Study on Metamorphic Ejection Mechanism for Air-to-Air Missile

Author

Liu Hao, Shen Xin

Subjects

air-to-air missile, metamorphism, launch safety, adaptivity, ejection mechanism, multi-body dynamics, intelligence structure, Motor vehicles. Aeronautics. Astronautics, TL1-4050

Abstract

The separation attitude of air-to-air missile to fighter should be adjusted adaptively in wide range to meet the missile-aircraft separation requirements under different flight states, but current ejection separation mechanism with fixed separation attitude could not meet the requirements. To solve this problem, a metamorphic ejection separation mechanism is proposed. Metamorphic PR-R kinematic pair is used to replace traditional hinge kinematic pair in the key hinge of ejection separation mechanism, the ejection forces of the front and rear push arm to missile are changed in real time, then missile ejection separation attitude could be adjusted adaptively in wide range. Multi-body dynamics model of metamorphic ejection separation mechanism is established, and the dynamics simulation analysis is carried out. Simulation results shows that the proposed metamorphic ejection separation mechanism could adjust separation attitude in wide range, which lays a foundation for the further realization of real-time intelligent control of the airborne missile ejection mechanism.

Published

2023

50. Vibration prediction and experimental validation of a rotary compressor based on multi-body dynamics.

Author

Wang, I-Cheng, Wu, Yu-Ren, and Fuh, Yiin-Kuen

Subjects

*CYCLIC loads, *COMPRESSORS, *ECCENTRIC loads, *ELECTRIC torque motors, *ECCENTRICS (Machinery), *PERMANENT magnets, *VIBRATION tests, *EXPERIMENTAL design

Abstract

In this study, an equivalent multi-body dynamics model of a rotary compressor for a household air-conditioner is established to predict its vibration responses when eccentric masses on the crankshaft, cyclic gas loads, torque ripple of the motor, connections with rubber washers, and the intake tube and exhaust tube are considered. Practical experiments for measuring the vibration acceleration of the compressor are conducted to validate the reliability and equivalence of the established model. The design of experiments method is employed to determine the optimal counterweights. This study determines the gas loads required to be considered in the counterweight design to attenuate the compressor vibration effectively. In addition, an optimal assembly angle for two counterweights is attained to reduce the compressor vibration. [ABSTRACT FROM AUTHOR]

Published

2023