«Previous Article|Table of Contents|Next Article»

长安大学学报（自然科学版）[ISSN:1006-6977/CN:61-1281/TN]

Issue:

2010年04期

Page:

23-27

Research Field:

Publishing date:

2010-08-20

Info

Title:

Load stress of composite airport pavement

Author(s):

MA Xiang;  NI Fu-jian;  CHEN Rong-sheng

School of Transportation, Southeast University, Nanjing 210096, Jiangsu, China

Keywords:

road engineering;  composite airport pavement;  critical loading position;  three-dimensional finite element;  loading stress

PACS:

U416.224

DOI:

-

Abstract:

In order to analyze the load stress of composite airport pavement, a 3D finite element model of nine full-scale slabs is established. Choosing B777-200 as the computational loading, the tensile stress of asphalt concrete, shear stress of asphalt concrete and the tensile stress of cement concrete were calculated as analytic index. The critical loading position is determined, and the effect of pavement structural parameters to the stress is analyzed by the orthogonal design method. The results show that the tensile stress of cement concrete is the key index of load stress of composite airport pavement, and the middle axis loading of three axes loading as the edge loading case was identified to be the critical loading position. With the increase of modulus of subgrade, the tensile stress of cement concrete and asphalt concrete decreases, while increasing the modulus of concrete will have adverse effect on the tensile stress of cement concrete. During the design of this kind of structure, subgrade should be regarded to improve the strength of subgrade, and can not excessively emphasize the modulus of cement concrete, it is necessary to comprehensively consider the flexural strength to choose proportioning design of cement concrete. 9 tabs, 5 figs, 8 refs.

References:

[1] 孙建斌,翁兴中.军用机场沥青混凝土道面结构设计指标确定[J].空军工程大学学报:自然科学版,2005,6(1):8-10. SUN Jian-bin,WENG Xing-zhong.Research on structure design criteria of asphalt concrete pavement for military airport[J].Journal of Air Force Engineering University:Natural Science Edition,2005,6(1):8-10.
[2]MHJ 5004—95,民用航空运输机场水泥混凝土道面设计规范[S].
[3]GJB 1278—91,军用机场水泥混凝土道面设计规范[S].
[4]王 维.现行刚性道面计算方法的局限性及其改进[J].中国民航学院学报,2003,21(6):48-51. WANG Wei.Limitations of currently used methodology for designing airport rigid pavement and its improvement[J].Journal of Civil Aviation University of China,2003,21(6):48-51.
[5]许 巍,岑国平,戴经梁.简易机场道面结构的疲劳特性试验[J].交通运输工程学报,2008,8(6):40-43. XU Wei,CEN Guo-ping,DAI Jing-liang.Fatigue characteristic experiments of field airfield pavement structure[J].Journal of Traffic and Transportation Engineering,2008,8(6):40-43.
[6]岑国平,马国强,王硕太,等.机场道面合成纤维混凝土的耐久性[J].交通运输工程学报,2008,8(3):43-45. CEN Guo-ping,MA Guo-qiang,WANG Shuo-tai,et al.Durability of synthetic fiber reinforced concrete for airport pavement[J].Journal of Traffic and Transportation Engineering,2008,8(3):43-45.
[7]凌建明,刘 文,赵鸿铎.大型军用机场多轮荷载作用下水泥混凝土道面的结构响应[J].土木工程学报,2007,40(4):60-65. LING Jian-ming,LIU Wen,ZHAO Hong-duo.Mechanical responses of rigid airport pavement to multiple-gear military aircraft loadings[J].China Civil Engineering Journal,2007,40(4):60-65.
[8]Brill D R,Parsons I D.Three-dimensional finite element analysis in airport pavement design[J].The International Journal of Geomechanics,2001,1(3):273-290.

Memo

Memo:

-

Common functions

Last Update: 2010-08-20