Optimal design of passenger vehicle seat with the use of negative stiffness elements

A seat that provides good vibration isolation is of prime importance for passenger’s safety and health. The main conflict in seat suspensions implies that the increasing initial deformation of the system (increase in “static discomfort”) leads to better isolation of accelerations (increase in “dynamic comfort”). Many researchers have focused on overcoming or at least suppressing this conflict between load support capacity and vibration isolation by modeling new suspension systems, such as the so-called negative suspension systems. However, apart from the modeling of new suspension systems, optimization is an important part in designing a seat and finding the best compromise between these two objectives. Thus, in this work, four types of seat suspension systems with embedded negative stiffness elements are implemented and optimized in order to be benchmarked. Three of them have already been tested either in passenger or in an off-road vehicle seat. All the vibration isolators are optimized with genetic algorithms in respect to static and dynamic factors of ride comfort by applying constraints oriented to the objectives and the design of the structure. The optimization is implemented for two excitations, which correspond to a vehicle driving over road profiles of Classes A and B, and the common solutions are outlined.

[1]  Hui Liu,et al.  Beneficial stiffness design of a high-static-low-dynamic-stiffness vibration isolator based on static and dynamic analysis , 2018, International Journal of Mechanical Sciences.

[2]  M J Griffin,et al.  Qualitative models of seat discomfort including static and dynamic factors , 2000, Ergonomics.

[3]  H. Hua,et al.  Application of a dynamic vibration absorber with negative stiffness for control of a marine shafting system , 2018 .

[4]  Evangelos J. Sapountzakis,et al.  KDamper concept in seismic isolation of bridges with flexible piers , 2017 .

[5]  V. N. Goverdovskiy,et al.  Helicopter vibration isolation: Design approach and test results , 2016 .

[6]  M. Griffin,et al.  Discomfort of seated persons exposed to low frequency lateral and roll oscillation: Effect of backrest height. , 2016, Applied ergonomics.

[7]  Neil J. Mansfield,et al.  Human Response to Vibration , 2004 .

[8]  Seung-Bok Choi,et al.  Vibration control of a vehicle’s seat suspension featuring a magnetorheological damper based on a new adaptive fuzzy sliding-mode controller , 2016 .

[9]  M M Frechin,et al.  ACTISEAT: Active vehicle seat for acceleration compensation , 2004 .

[10]  H J Yao,et al.  Semi-active control of seat suspension with MR damper , 2013 .

[11]  Thanh Danh Le,et al.  Low frequency vibration isolator with adjustable configurative parameter , 2017 .

[12]  Seung-Bok Choi,et al.  Ride quality investigation of an electrorheological seat suspension to minimize human body vibrations , 2006 .

[13]  Michael J. Brennan,et al.  Static analysis of a passive vibration isolator with quasi-zero-stiffness characteristic , 2007 .

[14]  Kyoung Kwan Ahn,et al.  Improvement of Vibration Isolation Performance of Isolation System Using Negative Stiffness Structure , 2016, IEEE/ASME Transactions on Mechatronics.

[15]  Fuxing Yang,et al.  Hybrid modelling of driver seat-cushion coupled system for metropolitan bus , 2017 .

[16]  Timothy P. Waters,et al.  Force and displacement transmissibility of a nonlinear isolator with high-static-low-dynamic-stiffness , 2012 .

[17]  H. Kim,et al.  Optimization of the static properties of seat foam to improve the seating comfort , 2017 .

[18]  Kyoung Kwan Ahn,et al.  Active pneumatic vibration isolation system using negative stiffness structures for a vehicle seat , 2014 .

[19]  C.-M. Lee,et al.  A multi-stage high-speed railroad vibration isolation system with “negative” stiffness , 2012 .

[20]  Natasa Trisovic,et al.  Optimization of Semi-active Seat Suspension , 2013 .

[21]  D E Gyi,et al.  Interface pressure and the prediction of car seat discomfort. , 1999, Applied ergonomics.

[22]  Diane E Gyi,et al.  Interface pressure data and the prediction of driver discomfort in road trials. , 2003, Applied ergonomics.

[23]  Jasbir S. Arora,et al.  Survey of multi-objective optimization methods for engineering , 2004 .

[24]  Mike Fray,et al.  Effect of long term driving on driver discomfort and its relationship with seat fidgets and movements (SFMs). , 2017, Applied ergonomics.

[25]  Omer Gundogdu Optimal seat and suspension design for a quarter car with driver model using genetic algorithms , 2007 .

[26]  Nong Zhang,et al.  Integrated Seat and Suspension Control for a Quarter Car With Driver Model , 2012, IEEE Transactions on Vehicular Technology.

[27]  Kyoung Kwan Ahn,et al.  A vibration isolation system in low frequency excitation region using negative stiffness structure for vehicle seat , 2011 .

[28]  W. Sun,et al.  Ride-Comfort-Oriented Suspension Optimization Using the Pseudo-Excitation Method , 2010 .

[29]  Bing Zhu,et al.  Modeling and Analysis of Static and Dynamic Characteristics of Nonlinear Seat Suspension for Off-Road Vehicles , 2015 .

[30]  Mike Kolich Automobile seat comfort: occupant preferences vs. anthropometric accommodation. , 2003, Applied ergonomics.

[31]  Shuaishuai Sun,et al.  An active seat suspension design for vibration control of heavy-duty vehicles , 2016 .

[32]  E. Papadopoulos,et al.  Hyper-Damping Behavior of Stiff and Stable Oscillators with Embedded Statically Unstable Stiffness Elements , 2017 .

[33]  Michael J. Brennan,et al.  On the design of a high-static-low-dynamic stiffness isolator using linear mechanical springs and magnets , 2008 .

[34]  M. Shafiqur Rahman,et al.  Investigation of Vibration and Ride Characteristics of a Five Degrees of Freedom Vehicle Suspension System , 2014 .

[35]  M. Collet,et al.  Enhancement of wave damping within metamaterials having embedded negative stiffness inclusions , 2015 .

[36]  V. Spitas,et al.  Hyper-damping properties of a stiff and stable linear oscillator with a negative stiffness element , 2015 .

[37]  Igor Maciejewski,et al.  Modelling and multi-criteria optimisation of passive seat suspension vibro-isolating properties , 2009 .

[38]  Xinlong Wang,et al.  Nonlinear dynamic characteristics of a quasi-zero stiffness vibration isolator with cam–roller–spring mechanisms , 2015 .

[39]  Ossama B. Abouelatta,et al.  Optimal Seat and Suspension Design for a Half-Car with Driver Model Using Genetic Algorithm , 2013 .

[40]  Ö. Gündoğdu Optimal seat and suspension design for a quarter car with driver model using genetic algorithms , 2007 .

[41]  Kyoung Kwan Ahn,et al.  Experimental investigation of a vibration isolation system using negative stiffness structure , 2011, 2011 11th International Conference on Control, Automation and Systems.

[42]  M. Griffin,et al.  Quantitative prediction of overall seat discomfort , 2000, Ergonomics.

[43]  Georgios Papaioannou,et al.  An approach for minimizing the number of objective functions in the optimization of vehicle suspension systems , 2018, Journal of Sound and Vibration.

[44]  Konstantinos Gryllias,et al.  KDamping: A stiffness based vibration absorption concept , 2018 .

[45]  Thanh Danh Le,et al.  Dynamic simulation of seat suspension system with virtual prototyping technology , 2017 .