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Sundeep Aanand, J.
- PC Modeling and Simulation of Car Suspension System
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Authors
Affiliations
1 Department of Automobile Engineering, Bharath University, Chennai-73
2 Department of Electronics, Bharath University, Chennai-73
3 Department of Computer Science Engineering, Bharath University, Chennai-73
1 Department of Automobile Engineering, Bharath University, Chennai-73
2 Department of Electronics, Bharath University, Chennai-73
3 Department of Computer Science Engineering, Bharath University, Chennai-73
Source
Indian Journal of Science and Technology, Vol 6, No S5 (2013), Pagination: 4629-4632Abstract
The car suspension system of this model contains two parts. The first part deals with the formulation of a mathematical model for a conventional full car passive suspension system. Typically, the mathematical modeling is done on the basis of mechanical network analysis. The second part deals with simulation of the mathematical model of the suspension system. Simulation is carried out using MATLAB. Program was carried out for MATLAB and the simulation results were obtained in the form of graphical plots.Keywords
Passive Suspension Sprung Mass, Unsprung Mass, Dampers, SpringFull Text
References
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- Williams R A (1997). Automotive active suspensions, Part-1: basic principles, Proceedings of the Institution of Mechanical Engineers Conference, vol 211, No. 6, 415–426.
- Crouse W H, and Anglin D L (2002). Automotive Mechanics, 9th Edn., Tata McGraw Hill Edition.
- Thermal Properties of Doped Azopolyester and its Application
Abstract Views :437 |
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Authors
Affiliations
1 Electronics Communication Engineering, Bharath University, Chennai-600073, IN
2 Automobile Engineering, Bharath University, Chennai, IN
3 Computer Science Engineering, Bharath University, Chennai, IN
4 Information Technology, Bharath University, Chennai, IN
1 Electronics Communication Engineering, Bharath University, Chennai-600073, IN
2 Automobile Engineering, Bharath University, Chennai, IN
3 Computer Science Engineering, Bharath University, Chennai, IN
4 Information Technology, Bharath University, Chennai, IN
Source
Indian Journal of Science and Technology, Vol 6, No S6 (2013), Pagination: 4722-4725Abstract
The thermal properties of doped Azopolyester were obtained by solution casting technique. Many theories have been suggested by various thermal stability mechanisms in organic solids. Since the polymers of the present study behave like semiconductors, these theories may be extended to explain thermal stability. In this section, the thermal stability theories proposed by O'Dwyer, TGA analysis, and measurements were discussed. The thermal stability properties reveal that the conductivity is appreciable in the temperature ranging from 30°C to 70°C (303 to 343K) and when it is more than 70°C (343 K) the conductivity is drastically reduced and polymeric blends undergo a gradual weight loss in the temperature ranging from 400-800°C due to attributed loss of volatile solvents trapped in the polymer. These studies are done with the help of O'Dwyer basic theory of thermal stability.Keywords
TGA, Thermal Properties, Azopolyester, Conductivity, TGA AnalysisFull Text
References
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- Optical Performance of Doped Azopolyester and its Application
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Authors
Source
Indian Journal of Science and Technology, Vol 6, No S6 (2013), Pagination: 4783-4788Abstract
Theoretical and experimental investigations on the optical behavior of thin films mainly deal with band gap, optical reflection, transmission, absorption and their relation to the optical constants. The optical transmittance spectra are recorded from 100 to 1000nm wavelength using a Hitachi UV-VIS-NIR spectrophotometer (Model-JASCO V-570) using a doped Azopolyester thin films were observed. Unpolarized radiation at room temperature with a resolution of 2nm was used in this study. Unpolarized radiation at room temperature with a resolution of 2nm was used in this study. The measurements were made on films of typical uniform thickness of 5μm deposited on glass substrate. The substrate absorption was corrected by introducing an uncoated cleaned glass substrate in the reference beam. The study of optical absorption / transmittance is a useful method for the investigation of optically induced transitions which provide information on the band structure and energy gap in both crystalline and non-crystalline materials. Finally optical applications of doped Azopolyester in fiber optic cable were used in telecommunication is discussed.Keywords
Optical Parameters, Doped Azopolyester, Band Gap, Lattice Bonding, Band StructureFull Text