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Online since: April 2022
Authors: Zhi Guo Gao
Journal of Materials Engineering and Performance,11(2002),667-674
Journal of Materials Engineering and Performance,6(1997),619-627
Journal of Materials Engineering and Perfoemance,30(2021),661-684
Journal of Materials Engineering and Performance,2(1993),589-596
Materials Science Forum, 1041(2021),47-56.
Journal of Materials Engineering and Performance,6(1997),619-627
Journal of Materials Engineering and Perfoemance,30(2021),661-684
Journal of Materials Engineering and Performance,2(1993),589-596
Materials Science Forum, 1041(2021),47-56.
Online since: November 2012
Authors: Shao Jun Bo, Kui Ji, Juan Tian
With the backlash dynamics simulation of
a crank-slider mechanism of the Internal combustion engine
Shaojun Bo1, a, Kui Ji2, b, Juan Tian3, c
1 School of Mechanical Engineering Inner Mongolia University of Science and Technology
Baotou, Inner Mongolia, China
2 School of Mechanical Engineering Inner Mongolia University of Science and Technology
Baotou, Inner Mongolia, China
3Institute of Mechanical Engineering Inner Mongolia University of Science and Technology
Baotou, China
absjsdkd@163.com, b245173065@qq.com, celainetianjuan@163.com
Keywords: Dynamics; Backlash; Slider-crank; Simulation; Internal-combustion engine
Abstract: On the basis of flexible multi-body system dynamics theory, we built flexible multi-body system dynamics models which include a backlash, and to a slider-crank mechanism as the research object, we made a preliminary study on the effect on the flexible components and the backlash of the kinematic pair on mechanical system dynamics characteristics.
Dynamics simulation with clearance of slider-crank mechanism Fig.2 ADAMS model of the slider-crank mechanism In Fig.2 shows slider-crank mechanism, put all parts material for steel, the size of the crank for ,the size of the connecting rod for , the size of the slider for ; k= , = , = ; the rotation of the crank at a constant speed and ,At crank and connecting rod take the backlash between their kinematic pair.
References [1] Hunt K H,et al.Coefficient of Restitution Interpreted as Damping in Vibroimpact[J].Journal of Applied Mechanics.1975,42E:440-445 [2] Herbert R G,et al.Shape and Frequency Composition of Pulses from an Impact Pair[J].Journal of Engineering for Industry.1977,99B(8):513-518 [3] Yigit A S,et al.Spring-dashpot Models for the Dynamics of a Radially Rotating Beam with Impact[J].Journal of sound and Vibration.1990,142(3):515-525 [4] Lee T W,et al.On the Dynamic Interactions of Interm Intent Motion Mechanisms, part 1:Dynamic model and response[J].Journal of Mechanisms,Transmissions, and Automation in Design,1983,105(3):527-539 [5] Wang Yu,et al.Dynamic Analysis of Flexible Mechanisms with Clearance[J] Journal of Mechanical Design.1996,118:592-594
Dynamics simulation with clearance of slider-crank mechanism Fig.2 ADAMS model of the slider-crank mechanism In Fig.2 shows slider-crank mechanism, put all parts material for steel, the size of the crank for ,the size of the connecting rod for , the size of the slider for ; k= , = , = ; the rotation of the crank at a constant speed and ,At crank and connecting rod take the backlash between their kinematic pair.
References [1] Hunt K H,et al.Coefficient of Restitution Interpreted as Damping in Vibroimpact[J].Journal of Applied Mechanics.1975,42E:440-445 [2] Herbert R G,et al.Shape and Frequency Composition of Pulses from an Impact Pair[J].Journal of Engineering for Industry.1977,99B(8):513-518 [3] Yigit A S,et al.Spring-dashpot Models for the Dynamics of a Radially Rotating Beam with Impact[J].Journal of sound and Vibration.1990,142(3):515-525 [4] Lee T W,et al.On the Dynamic Interactions of Interm Intent Motion Mechanisms, part 1:Dynamic model and response[J].Journal of Mechanisms,Transmissions, and Automation in Design,1983,105(3):527-539 [5] Wang Yu,et al.Dynamic Analysis of Flexible Mechanisms with Clearance[J] Journal of Mechanical Design.1996,118:592-594
Online since: March 2012
Authors: Qian Sheng Zhang, Zhen Hua Zhang, You Pei Ye, Jing Yu Yang, Yong Hu
Yang: International Journal of Approximate Reasoning, vol. 46(2007),
p120-136
[12] Zeshui Xu: International Journal of Approximate Reasoning, vol.48 (2008), p246-262
[16] Zhenhua Zhang, Jingyu Yang, Youpei Ye and Min Wang: International Journal of Applied Mechanics and Materials, vol.121-126(2011), p3993-3997
[17] Qiansheng Zhang, Haixiang Yao and Zhenhua Zhang: International Journal of Applied Mechanics and Materials, vol.44-47 (2011), p: 3888-3892
[18] Qiansheng Zhang, Haixiang Yao and Zhenhua Zhang: Advanced Materials Research, vol.143-144 (2011), p161-165
[12] Zeshui Xu: International Journal of Approximate Reasoning, vol.48 (2008), p246-262
[16] Zhenhua Zhang, Jingyu Yang, Youpei Ye and Min Wang: International Journal of Applied Mechanics and Materials, vol.121-126(2011), p3993-3997
[17] Qiansheng Zhang, Haixiang Yao and Zhenhua Zhang: International Journal of Applied Mechanics and Materials, vol.44-47 (2011), p: 3888-3892
[18] Qiansheng Zhang, Haixiang Yao and Zhenhua Zhang: Advanced Materials Research, vol.143-144 (2011), p161-165
Online since: September 2024
Authors: Yun Qing Liu, Wen Yi Zhu, Nian Wei Yang, Tian Xing Wang, Zhi Zhen Yin
Materials and m Methods
2.1 Materials
The reagents used in the study were of analytical reagent grade.
Khadom, Electron transport in dye-sanitized solar cell with tin-doped titanium dioxide as photoanode materials.
Journal of materials science-materials in electronics. 33. 8 (2022) 5009-5023
Journal of colloid and interface science. 509 (2018) 219-234
International journal of molecular sciences. 23. 21 (2022) 13221
Khadom, Electron transport in dye-sanitized solar cell with tin-doped titanium dioxide as photoanode materials.
Journal of materials science-materials in electronics. 33. 8 (2022) 5009-5023
Journal of colloid and interface science. 509 (2018) 219-234
International journal of molecular sciences. 23. 21 (2022) 13221
Online since: July 2011
Authors: Qi Qing Huang, Wei Xie, Shao Wei Tu, Ya Zhi Li
The material mechanical property is given in Table 1.
References: [1] Tang Li, Qingyuan Wang: Journal of Southwest university of Science and Technology.
(In Chinese) [2] Zhiqiao Zheng, Yuanyuan Chen, etc: The Chinese Journal of Nonferrous Metals.
Vol. 314 (2001), p.118-130 [4] Srivatsan TS, Kolar D, Magnusen P: Materials and Design.
Vol. 21 (1999), p.2ll-2l9 [7] Jialin Guo, Zhiming Yin, etc.: Journal of Aeronautical Materials.
References: [1] Tang Li, Qingyuan Wang: Journal of Southwest university of Science and Technology.
(In Chinese) [2] Zhiqiao Zheng, Yuanyuan Chen, etc: The Chinese Journal of Nonferrous Metals.
Vol. 314 (2001), p.118-130 [4] Srivatsan TS, Kolar D, Magnusen P: Materials and Design.
Vol. 21 (1999), p.2ll-2l9 [7] Jialin Guo, Zhiming Yin, etc.: Journal of Aeronautical Materials.
Online since: February 2011
Authors: Xue Bing Liu, Yun Feng Qiao, Dong Fang Pan, Cheng Shuai Sun
With the micro defects forming, extending and combining under the loads and weather actions the materials and the structures degrades, the decreasing of the strength, the stiffness, the toughness and the life span.
The damage is defined as the microstructure leading to the degradation of the mechanical properties in structures and materials.
Materials are summit to the normal rule
References [1] Li Jinyu, Cao Jianguo, Xu Wenyu: Journal of hydraulic engineering.
Vol. 1 (1999), p. 41 In Chinese [2] Shi Shisheng: China Civil Engineering Journal.
The damage is defined as the microstructure leading to the degradation of the mechanical properties in structures and materials.
Materials are summit to the normal rule
References [1] Li Jinyu, Cao Jianguo, Xu Wenyu: Journal of hydraulic engineering.
Vol. 1 (1999), p. 41 In Chinese [2] Shi Shisheng: China Civil Engineering Journal.
Online since: August 2013
Authors: Man Cun Song, Pu Cheng Pei, Peng Cheng Li, Xia Zeng
Proton exchange membrane fuel cell from low temperature to high temperature: Material challenges[J].
Journal of Power Sources. 2007, 167: 235-242
Progress in Polymer Science, 2011, 36(6):813-843
Journal of Fuel Cell Science and Technology. 2009, 041006 (8 pp
Journal of Power Sources, 2009, 190: 83-85
Journal of Power Sources. 2007, 167: 235-242
Progress in Polymer Science, 2011, 36(6):813-843
Journal of Fuel Cell Science and Technology. 2009, 041006 (8 pp
Journal of Power Sources, 2009, 190: 83-85
Online since: April 2019
Authors: Martin Stolárik, Jan Nedoma
In previous research (please see our articles of our team OPTICE), we tested a methodology for the placement of measuring and reference fibers, also used couplers, attachment and covering materials, optical fiber protections, photodetectors and lasers.
Marsalek, Analysis of load of the tunnel definitive lining due to vibrations of various sources, Advanced Materials Research. 1020 (2014), 429-434
Pinka, Seismic impact of the railway on the geotechnical constructions, IOP Conference Series: Materials Science and Engineering, (2017) 012049
Novotny, Seismic load analysis around the temporary bridge construction before and after vibration mats installation, Advanced Materials Research. 1020 (2014) 441-446
Road vehicle information collection system based on distributed fiber optics sensor, Advanced Materials Research. 1030 (2014) 2105-2109
Marsalek, Analysis of load of the tunnel definitive lining due to vibrations of various sources, Advanced Materials Research. 1020 (2014), 429-434
Pinka, Seismic impact of the railway on the geotechnical constructions, IOP Conference Series: Materials Science and Engineering, (2017) 012049
Novotny, Seismic load analysis around the temporary bridge construction before and after vibration mats installation, Advanced Materials Research. 1020 (2014) 441-446
Road vehicle information collection system based on distributed fiber optics sensor, Advanced Materials Research. 1030 (2014) 2105-2109
Online since: September 2025
Authors: Stefania Stucci, Benjamin J. Sekely, Yashas Satapathy, Tao Yang, Greg Allion, Phillip Barletta, Carl Haber, Steve Holland, Spyridon Pavlidis, John F. Muth
Materials 2022, 15, 123.
Kato, "Surface recombination velocities for 4H-SiC: Dependence of excited carrier concentration and surface passivation", Materials Science in Semiconductor Processing, Vol. 170, 2024, doi: 10.1016/j.mssp.2023.107980 [14] M.
Diamond & Related Materials, 14 (2005) pp 1138 - 1141, doi: 10.1016/j.diamond.2004.12.020
Spera et al., Materials 2019, 12, 3468; doi:10.3390/ma12213468 [19] F.
International Journal of Fundamental Physical Sciences, 4(3), 95-100. https://doi.org/10.14331/ijfps.2014.330071 [22] L.
Kato, "Surface recombination velocities for 4H-SiC: Dependence of excited carrier concentration and surface passivation", Materials Science in Semiconductor Processing, Vol. 170, 2024, doi: 10.1016/j.mssp.2023.107980 [14] M.
Diamond & Related Materials, 14 (2005) pp 1138 - 1141, doi: 10.1016/j.diamond.2004.12.020
Spera et al., Materials 2019, 12, 3468; doi:10.3390/ma12213468 [19] F.
International Journal of Fundamental Physical Sciences, 4(3), 95-100. https://doi.org/10.14331/ijfps.2014.330071 [22] L.
Online since: September 2013
Authors: Worapong Boonchouytan, Prapas Muangjunburee, Surasit Rawangwong, Jaknarin Chatthong, Romadorn Burapa
Materials and Design, 18: pp. 269-273
Material Science and Engineering, A415: pp. 250-254 [9] O.
Journal of Materials Processing Technology, 209: pp. 4822-4829
Journal of Materials Science, 40: pp. 3669-3676
Materials and Design, 30: pp. 609-616
Material Science and Engineering, A415: pp. 250-254 [9] O.
Journal of Materials Processing Technology, 209: pp. 4822-4829
Journal of Materials Science, 40: pp. 3669-3676
Materials and Design, 30: pp. 609-616