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1.
青藏铁路冻土路基沉降变形现场试验研究 总被引:3,自引:0,他引:3
Based on the field data of ground temperature and roadway settlement observed during the construction of the experimental embankments over permafrost along the Qinghai-Tibetan Railway, this paper discusses the differences of frost process on the roadway surface from that on the natural ground surface, the changes of permafrost table under the roadway embankment, and the peculiarities of roadway settlement. Analyses of the test results show : 1) The differences of the freezing indexes between the roadway surfaces and the natural ground surfaces are less than those of the thawing indexes for all the test sections; 2) Since the measures of permafrost protection were taken, the permafrost tables under the embankments have raised after the roadway was constructed. The minimum is about 0.4 m and the maximum is 1.2 m; 3) the settlements of the roadway are mainly from the compression and creep of the icerich frozen soils under the original permafrost tables and the maximum has reached 6 ~ 8 cm during the first year after the embankments were constructed. Moreover, concerning the processes of roadway settlement, the deformation of the embankments has no obvious trend of attenuation at present. Especially,for the roadway with high embankments, the settlement may reach a remarkable value and much consideration must be given for this problem. 相似文献
2.
Permafrost along the Qinghai-Tibet railway is featured by abundant ground ice and high ground temperature. Under the influence of climate warming and engineering activities, the permafrost is under degradation process. The main difficulty in railway roadbed construction is how to prevent thawing settlement caused by degradation of permafrost. Therefore the proactively cooling methods based on controlling solar radiation, heat conductivity and heat convection were adopted instead of the traditional passive methods, which is simply increasing thermal resistance. The cooling methods used in the Qinghai-Tibet railway construction include sunshine-shielding roadbeds, crushed rock based roadbeds, roadbeds with rock revetments, duct-ventilated roadbeds, thermosyphon installed roadbeds and land bridges. The field monitored data show that the cooling methods are effective in protecting the underlying permafrost, the permafrost table was uplifted under the embankments and therefore the roadbed stability was guaranteed. 相似文献
3.
Using the long-term ground temperature monitoring data of the permafrost zone along the Qinghai-Tibet Railway from 2006 to 2020,three types of typical roadbed structures were analyzed. Traditional embankment(TE),U-shaped crushed rock embankment(UCRE)and crushed rock revetment embankment(CRRE)were included the three types of typical roadbed,which were selected to the long-term monitoring sections within the warm permafrost zones. The evolution of ground temperature field,mean annual ground temperature (MAGT)and annual maximum ground temperature(AMGT)in the depth range of 20 m under the embankment were analyzed and studied since 15 years of operation. The monitoring and analysis results show that:the growth rate of MAGT under the left and right shoulders of the TE is always higher than that of the same depth in the natural site. The MAGT under the UCRE is always lower than the natural site and always maintains a certain difference,whereas,the difference in ground temperature under the left and right shoulders is also not negligible. The MAGT of the left shoulder in the CRRE is not much different from that of the natural hole,while the MAGT of the right shoulder is always lower than that of the natural hole,and the differ in ground temperature between the left and right shoulders is smaller than that of the UCRE. The artificial permafrost table(APT)under the TE is always lower than that of in the natural site. Both the UCRE and CRRE,the APT in the left and right shoulders of them has been elevated into the embankment,and the differ of APT between the left and right shoulders is about 1. 0~1. 5 m. the differ of APT between the left and right shoulders in the CRRE is slightly lower than that of UCRE. Overall,because of the influence of thermal disturbance about engineering and climate warming,the TE in the warm permafrost zones cannot keep the thermal stability of permafrost under the embankment. Some active-cooling and reinforcement measures need to be taken. Both of the UCRE and CRRE,have a certain active-cooling effect on the permafrost under embankment,but the differ in ground temperature between the left and right shoulders still needs to be taken seriously. © 2022 Science Press (China). 相似文献
4.
冻土地区三角形块石路基与水平块石路基的保冷效果研究 总被引:2,自引:2,他引:0
Time varying temperatures and pore-air velocities in two gravel embankments, horizontal and triangular gravel embankments, are studied using the "Rock-Block model" and the results are visualized in the form of isotherms and velocity vectors for different times of the year. Simulation results show that for both the two embankments there is a counter-clockwise rotation of pore-air extending throughout most of the embankment during winter months, whereas in summer the pore-air rotation changes to the opposite. The pore-air velocities in the triangle gravel embankment are somewhat higher than those obtained from the horizontal gravel embankment. The stronger convection in winter enhances the upward transport of heat out of the triangle gravel embankment, thus having more apparent cooling effect than the horizontal gravel embankment. During summer months, the pore-air velocities are nearly the same for both the two embankments. The results of the present study show that though the two gravel embankments have the effect of cooling the permafrost beneath, the temperature fields in the triangle gravel embankment are a little lower and more stable compared with those gotten from the horizontal gravel embankment, showing that the triangle gravel embankment has more apparent cooling effect than the horizontal one. 相似文献
5.
In permafrost regions, many methods about active cooling embankment are put forward, one of these representations is ventilated embankment, its cooling effect is the result of the air convection in the duct, and this leads to reducing the annual average ground temperature. The present work in this article is to determine the boundary conditions of the ventilated embankment and natural ground in numerical work. There are several effects which influence boundary conditions, they are: radiation, evaporation,phase change, convection and embankment material etc. Radiation and convection are the main effects in those. We mainly consider sun radiation in this article. The added-surface effect in ventilated embankment lowers its temperature, so the temperature on the wall of the ventilated embankment is different from the temperature in atmosphere. There are two methods in determining the surface temperature, experimental method and experiential method. Detailed research is discussed in the article. 相似文献
6.
In permafrost regions of Qinghai-Tibetan Plateau, the critical embankment height must be considered in the process of the construction of highway, especially for the global climatic warming. In this paper, the two-dimensional numerical analysis for the critical embankment height (for gravel road surface and coarse-grained soil) has been performed by using thefinite element method. In the calculation, we think that the service life of the construction is at least 50 years. The mean annual air temperatures applied to the calculation model are -6.5 ℃, -6.0 ℃, -5.5 ℃, -5.0 ℃, -4.5 ℃ and -4.0 ℃, respectively, and the value of temperature rise are taken as 1.10℃ in the coming 50 years. The minimum embankment heights derived from the analysis are 0.85 m, 0.92 m, 1.01 m, 1.18 m, 1.60 m and 2.66 m for the different mean annual air temperatures and the maximum embankment heights are 7.68 m,7.55 m, 7.34 m, 7.00 m, 6.45 m and 5.85m, accordingly. On condition that the service life of embankment is 50 years, the critical value of the mean annual air temperature is -3.5 ℃. Namely, in the areas where the mean annual air temperature is higher than -3.5 ℃, the critical embankment height does not exist. 相似文献
7.
Aiming at the stabilization of Qinghai-Tibetan Railway embankment during its construction and run, the method using tilt pipes to keep the permafrost embankment stabilization is put forward in the paper. By gathering natural cold energy in the winter and release it in the summer the tilt pipes can keep the permafrost embankment stabilizing. The temperature fields of the embankment and the stratums below are studied according to the condition of pipes diameter 250mm, length 7. 0m and tilt angle 30°,45°, 60° until the railway working for 20 years. It is shown that the embankment field using tilt pipes will eliminate the thawing core and come into subzero temperature phase ahead of 9 years compared with the original model. Different tilt angles have different efforts on the embankment and stratums, synthesis analysis of thermal income and expenses of the embankment and stratums should be carried out 相似文献
8.
Abstract: Permafrost (perennially frozen ground) appears widely in the Golmud-Lhasa section of the Qinghai-Tibet railway and is characterized by high ground temperature (≥ ?1°C) and massive ground ice. Under the scenarios of global warming and human activity, the permafrost under the railway will gradually thaw and the massive ground ice will slowly melt, resulting in some thaw settlement hazards, which mainly include longitudinal and lateral cracks, and slope failure. The crushed rock layer has a thermal semiconductor effect under the periodic fluctuation of natural air. It can be used to lower the temperature of the underlying permafrost along the Qinghai-Tibet railway, and mitigate the thaw settlement hazards of the subgrade. In the present paper, the daily and annual changes in the thermal characteristics of the embankment with crushed rock side slope (ECRSS) were quantitatively simulated using the numerical method to study the cooling effect of the crushed rock layer and its mitigative ability. The results showed that the ECRSS absorbed some heat in the daytime in summer, but part of it was released at night, which accounted for approximately 20% of that absorbed. Within a year, it removed more heat from the railway subgrade in winter than that absorbed in summer. It can store approximately 20% of the “cold” energy in subgrade. Therefore, ECRSS is a better measure to mitigate thaw settlement hazards to the railway. 相似文献
9.
应用等效纬度-海拔模型进行地温及多年冻土制图 总被引:2,自引:2,他引:2
KenjiYoshikawa PrasadGogineni 《冰川冻土》2002,24(5):526-531
This research presents a method for permafrost mapping in discontinuous permafrost regions based on equivalent latitude/elevation concept in interior Alaska. In winter months, study site has a strong temperature inversion in air up to 700 m elevation. Air temperature data and the effects of slope, aspect and elevation were used to create an equivalent latitude/elevation model. This model was well correlated with mean annual surface temperature (0.79). In this watershed, the thawing index (It≈1 400 ℃*days) at the ground surface and snow depth do not vary greatly from south facing to north facing slopes. The primary controlled factor that determines the mean annual surface temperature was the winter surface temperature. The permafrost stability is effectively controlled by the freezing index. We determined 37.5% of Caribou-Poker Creeks Research Watershed has unstable or thawing permafrost. At least 2.1% of the permafrost in this watershed may have disappeared in the last 90 years due to climate warming. This method makes it possible to evaluate the permafrost stability in the present, past and future. 相似文献
10.
青藏铁路设计与建设——第六届国际冻土工程会议回顾 总被引:1,自引:1,他引:0
The 6^th International Symposium on Permafrost Engineering was successfully held in China in September 2004. About 150 scientists and engineers from 7 countries attended the symposium in Lanzhou on 5~7 September, and about 35 people from 6 countries participated in the field trip along the QinghaiTibet Highway/Railway on 8~13 September and the seminar in Lhasa on 14 September 2004. During the Symposium, the latest progress on permafrost engineering and the surveys, design and construction of the Qinghai-Tibet Railway were exchanged and inspected. Fifty-eight technical papers in English from the Symposium were published in the first volume of the Proceedings of the Symposium, as a supplement of the Journal of Glaciology and Geocryology, before the symposium. About 6 papers from the symposium are published in the second volume in the volume 27(1) of the Journal of the Glaciology and Geocryology, after the symposium. The Qinghai-Tibet Railway (QTR) under construction will traverse 632 km of permafrost, and the engineers are facing unprecedented engineering and environmental challenges. With the QTR under construction and to be completed in 2007, permafrost engineering has become the research focus of permafrost scientists and engineers in China. Many encouraging and promising achievements in permafrost engineering have been obtained during the past three years. However, there are still numerous engineering and environmental problems needing to be solved or resolved. In the discussions, some experts pointed out that methods, such as removal of snow cover on the embankments and toe areas, light-color embankments and side slope surfaces, awnings for shading the solar radiation, hairpin or tilted thermosyphons, could be applied to actively cool the roadbed of the QTR. Some new ideas on utilization of the natural cold reserves were proposed to protect the QTR permafrost roadbed from thawing. Many questions and answers on the survey, design, construction, operations, maintenance and environmental protection were exchanged in situ and in the Lhasa seminar with participation by some major railway designers, regulators and administrators. 相似文献
11.
青藏铁路多年冻土区普通路基热状况监测分析 总被引:1,自引:1,他引:0
基于现场地温监测数据,选取年平均地温不同的监测断面对青藏铁路普通路基的热状况进行分析,包括多年冻土上限变化及其地温变化、下伏多年冻土温度变化、原天然地表附近热收支等方面. 结果表明:在低温多年冻土区,路基下部多年冻土上限均有所提升,且新近形成的人为上限较为稳定,冷季时负温积累显著;路基下伏多年冻土总体热稳定性较好. 而在高温多年冻土区,左(阳坡)路肩下部多年冻土上限多表现为下降,右(阴坡)路肩下部多年冻土上限有升有降,但是新近形成的上限均温度较高且有进一步升温的趋势;与天然场地地温相比,路基下部多年冻土均出现一定的升温. 尤其在高温极不稳定多年冻土区,天然场地多年冻土自身处于吸热升温状态;路基修筑后,下部多年冻土已经出现了融化夹层及双向退化的情况,路基热稳定性较差. 对于普通路基来说,由于青藏高原强烈的太阳辐射及青藏铁路总体走向原因,普通阴阳坡效应显著,左、右路肩下部多年冻土热稳定性差异较大. 相似文献
12.
基于多孔介质中流体热对流的连续性方程、非达西流动量方程和能量方程,对强通风条件下青藏铁路典型抛石护坡路基内温度场和流速场的分布形态进行数值研究。研究结果表明,抛石护坡路基对多年冻土保护作用显著,抛石护坡路基的存在使夏季多年冻土上限明显提高,冬季抛石护坡路基下部土体回冻速度较天然地表下部土体更快,由于降温作用主要集中在护坡附近有限范围之内,对路基中部的降温作用相对较弱。整体而言,抛石护坡对冻土路基本体的保护作用有限,从长期降温效果来看,由于全球气候变暖的影响,强通风条件下抛石护坡路基中线以下土体的内部可能产生“似眼球状”融化夹层,不利于路基的稳定。迎风抛石护坡层中空气运动方向大致为沿护坡斜向上,背风抛石护坡层中空气运动方向以从下到上运动为主,抛石层内空气的运动形式为“绕流”,抛石层表面空气速度最大,内部较小,空气速度分布区间为1.24×10-3~12.8 m/s,数值结果与现场试验测得的风速区间基本一致。 相似文献
13.
青藏公路下伏多年冻土的融化分析 总被引:14,自引:6,他引:8
基于青藏公路沿线高温冻土区和低温冻土区2组地温观测孔5 a的地温观测资料, 研究了路基下伏多年冻土的融化状态, 定量分析了进入路基下多年冻土内的热状况. 结果表明: 路基近地表地温明显高于对应天然地表下的地温, 路基近地表经历的融化期长于对应天然地表, 高温冻土区路基内已形成贯穿融化夹层;进入高温冻土区路基下伏多年冻土内的热收支处于持续不断的吸热状态, 进入低温多年冻土区的热收支也呈现出吸热明显大于放热的周期性变化;高温冻土区接近0℃的地温及其持续不断的热积累是引起下伏多年冻土不断融化的主要原因. 低温冻土区进入多年冻土的热积累暂时以增高地温耗热为主, 随着地温的增高, 低温冻土区也可能发生强烈的冻土融化. 相似文献
14.
青藏铁路多年冻土区路基变形特征及其来源 总被引:3,自引:0,他引:3
基于青藏铁路多年冻土区34个路基监测断面2005-2011年的变形与地温资料,分析路基的变形特征及其来源。监测结果表明:①监测期累计变形量大于100 mm的断面均为普通路基,其变形主要来自路基下部因冻土上限下降而引起的高含冰量冻土的融沉变形以及融土的压密变形,其次为路基下部多年冻土因地温升高而产生的高温冻土的压缩变形。②监测期累计变形量小于100 mm的普通路基与块石结构路基断面,其变形主要来自路基下部多年冻土的压缩变形。③总体而言,块石结构路基变形量明显小于普通路基,从而验证了主动冷却措施的长期有效性。其研究结果可为冻土区路基稳定性判断及病害预警提供数据支持。 相似文献
15.
基于修正拉格朗日(U.L)描述下的大变形固结理论和考虑相变作用的温度场得到大变形融化固结理论,对不同路堤高度下填土路基温度场和融沉变形进行研究. 结果表明:高温冻土区合理高度的路堤在5~10 a内使冻土上限略微抬升,但冻土有明显升温. 冻土上限在未来的5~10 a后会急剧下降,且路堤高度越小,下降量越大. 与小变形融化固结理论相比,大变形融化固结理论预测高含量冻土融沉变形的精度更高. 融沉量与路堤高度成正比,且随着时间的增长,融沉变形呈阶梯型发展,路堤越高,阶梯现象越显著. 定义融沉量与路堤高度之比为沉降比,研究发现路堤越低,其沉降比越大,且随时间线性增长. 沉降比是冻土融深增量的单值函数,与路堤高度无关,通过沉降比函数可以快速而实用的求出融沉变形量. 相似文献
16.
17.
为了研究透壁式通风管-块石复合气冷路基的降温效果,针对年均气温约-3.5℃,平均风速2.5 m·s-1,主导风向为西北方向的高原环境条件开展室内模型试验,分析了单一块石气冷路基和透壁式通风管-块石复合气冷路基的孔隙空气对流速度、特征点地温变化过程以及模型整体温度场变化过程.结果表明:在透壁式通风管的疏导作用下,透壁式通风管与块石层的复合结构能够起到强化路基体对流的效果,复合路基块石孔隙中的空气流速比单一块石路基提高约20%,由此导致复合路基模型底部的降温幅度是单一块石路基模型的2.2倍.模型整体温度场表明,复合路基能够起到储存冷量、降低下伏多年冻土地温的作用. 相似文献
18.
青藏铁路多年冻土区路基变形裂缝发生机理及其防治 总被引:16,自引:0,他引:16
青藏铁路多年冻土区路基工程的修建,改变了路基基底多年冻土的热量平衡状态.通过对青藏铁路多年冻土区试验工程和已经施工的路基工程所发生的变形裂缝的调查和分析,认为多年冻土区路基几何尺寸不对称和路基边坡坡向不同导致的路基人为上限形态不同,是造成多年冻土区路基温度场不对称以及基底土体冻结融化过程不同步的主要原因,也是造成路基变形裂缝的主要原因.文章在此基础上提出了减少或消除路基温度场不对称,从而减少或消除这类变形裂缝的主要工程结构形式和工程措施,作者的看法和结论已经在2003年青藏铁路冻土区路基工程设计和成形路基补强工程措施设计中得到广泛应用. 相似文献
19.
青藏铁路抛石护坡和保温材料复合路基温度场特征非线性分析 总被引:1,自引:1,他引:0
采用多孔介质中流体的连续性方程、动量方程及能量方程,针对青藏铁路的气温和地质条件,对抛石护坡路基(无保温材料)及其在靠近路基顶部增设保温材料后的温度场特征进行了分析和比较.结果表明:在年平均气温为-4.0℃的青藏高原多年冻土区,考虑未来50 a气温上升2.6℃条件下,抛石护坡路基对其下部多年冻土可起到一定的保护作用;但由于气温升高的影响,路基中心处出现终年融化夹层;计算中发现当抛石护坡达到一定厚度时,单纯依靠增加抛石护坡厚度并不能明显增加其对路基中心处的降温效果;而增设保温材料后的抛石护坡路基可有效减小路基中出现的融化夹层,确保冻土路基的稳定.因此,建议在高温多年冻土区使用抛石护坡路基结构时,应考虑使用保温材料作为一种对抛石护坡路基进行保温补强的措施. 相似文献