河海大学学报(自然科学版)
河海大學學報(自然科學版)
하해대학학보(자연과학판)
JOURNAL OF HOHAI UNIVERSITY (NATURAL SCIENCES)
2014年
5期
427-432
,共6页
杨沐野%吉伯海%傅中秋%徐汉江%陈策
楊沐野%吉伯海%傅中鞦%徐漢江%陳策
양목야%길백해%부중추%서한강%진책
钢箱梁%实测车流%车辆荷载谱%振动响应%动力放大系数%南京长江第三大桥
鋼箱樑%實測車流%車輛荷載譜%振動響應%動力放大繫數%南京長江第三大橋
강상량%실측차류%차량하재보%진동향응%동력방대계수%남경장강제삼대교
steel box girder%measured vehicle flow%vehicle load spectrum%vibration response%dynamic magnification factor%Nanjing Third Yangtze River Bridge
依据南京长江第三大桥的实测交通流统计数据,结合等效疲劳损伤原理建立随机状态下的车辆荷载谱,基于有限元数值仿真程序进行全桥动力响应分析。通过计算大桥在实测车流作用下主梁不同位置位移和内力的动力响应时程曲线,分析车辆运营时程内主梁截面内力变化及动力放大系数。结果表明:随机车流作用下大桥主梁塔根处弯矩及轴力绝对值最大,跨中处弯矩及轴力变化幅值最大,而在1/4跨位移动力响应最大。跨中、1/4跨和塔根附近截面在时程内的最大应力幅值处,动力放大系数在1.00~1.03之间,动力放大系数比单考虑弯矩或轴力时稳定,且动应力放大系数与国内现行规范的动力放大系数较为吻合。
依據南京長江第三大橋的實測交通流統計數據,結閤等效疲勞損傷原理建立隨機狀態下的車輛荷載譜,基于有限元數值倣真程序進行全橋動力響應分析。通過計算大橋在實測車流作用下主樑不同位置位移和內力的動力響應時程麯線,分析車輛運營時程內主樑截麵內力變化及動力放大繫數。結果錶明:隨機車流作用下大橋主樑塔根處彎矩及軸力絕對值最大,跨中處彎矩及軸力變化幅值最大,而在1/4跨位移動力響應最大。跨中、1/4跨和塔根附近截麵在時程內的最大應力幅值處,動力放大繫數在1.00~1.03之間,動力放大繫數比單攷慮彎矩或軸力時穩定,且動應力放大繫數與國內現行規範的動力放大繫數較為吻閤。
의거남경장강제삼대교적실측교통류통계수거,결합등효피로손상원리건립수궤상태하적차량하재보,기우유한원수치방진정서진행전교동력향응분석。통과계산대교재실측차류작용하주량불동위치위이화내력적동력향응시정곡선,분석차량운영시정내주량절면내력변화급동력방대계수。결과표명:수궤차류작용하대교주량탑근처만구급축력절대치최대,과중처만구급축력변화폭치최대,이재1/4과위이동력향응최대。과중、1/4과화탑근부근절면재시정내적최대응력폭치처,동력방대계수재1.00~1.03지간,동력방대계수비단고필만구혹축력시은정,차동응력방대계수여국내현행규범적동력방대계수교위문합。
According to measured traffic flow statistics from the Nanjing Third Yangtze River Bridge, in Jiangsu Province, a vehicle load spectrum in a random state was developed based on the theory of fatigue damage equivalence, and a full-bridge dynamic response analysis was conducted using finite element numerical simulation. Through calculation of the displacements and vibration response time-history curves of internal forces in different sections of the main beam of the bridge under the influence of measured vehicle flow, the changes of internal forces and dynamic magnification factors were analyzed. The results show that, under the influence of random traffic, the absolute values of the bending moment and axial force were at their maximum at the bottom of the tower of the main beam. The mid-span bending moment and axial force changed most significantly. At one quarter of the span, the displacement vibration was most intense. The dynamic magnification factor ranged from 1. 00 to 1. 03 at the maximum stress amplitude at mid-span, one quarter of the span, and near the tower bottom. The dynamic magnification factor was more stable than in the case considering only the bending moment or the axial force, and was consistent with that of the current specifications in China.