农业工程学报
農業工程學報
농업공정학보
2015年
9期
57-62
,共6页
力学特性%冻土%剪应力%接触界面层%单调剪切%峰值剪应力
力學特性%凍土%剪應力%接觸界麵層%單調剪切%峰值剪應力
역학특성%동토%전응력%접촉계면층%단조전절%봉치전응력
mechanical properties%frozen soils%shear stress%interface layer%monotonic shear%peak shearing stress
为了解在荷载作用下,接触界面层发生的力学响应区别于冻土和结构材料本身力学特性,使用新研制的冻土与结构接触界面层力学试验仪,比较系统地研究人工冻黏土与粗糙钢板接触界面层单调剪切力学特性。分别从宏观和细观2个角度出发,分析冻土界面层的基本力学特性和受力变形机理。结果表明:随着法向荷载增大,接触界面的峰值剪应力、稳定剪应力、初始剪切劲度也增大,接触界面的抗剪强度与法向应力呈线性关系,可用摩尔-库仑准则来描述;冻土颗粒的剪切位移随冻土深度增大而减小,同一冻土深度内,剪切位移随法向应力的增大而增大,不同粗糙度的结构接触界面层变形特性基本相似,试验条件范围内接触界面层厚度为0.5~3.5 mm;界面层变形可分为冻土与结构接触界面上滑移变形和受结构约束的冻土剪切变形两部分;结构面粗糙度、冻土温度和法向应力等因素对接触界面层的力学特性具有显著影响。
為瞭解在荷載作用下,接觸界麵層髮生的力學響應區彆于凍土和結構材料本身力學特性,使用新研製的凍土與結構接觸界麵層力學試驗儀,比較繫統地研究人工凍黏土與粗糙鋼闆接觸界麵層單調剪切力學特性。分彆從宏觀和細觀2箇角度齣髮,分析凍土界麵層的基本力學特性和受力變形機理。結果錶明:隨著法嚮荷載增大,接觸界麵的峰值剪應力、穩定剪應力、初始剪切勁度也增大,接觸界麵的抗剪彊度與法嚮應力呈線性關繫,可用摩爾-庫崙準則來描述;凍土顆粒的剪切位移隨凍土深度增大而減小,同一凍土深度內,剪切位移隨法嚮應力的增大而增大,不同粗糙度的結構接觸界麵層變形特性基本相似,試驗條件範圍內接觸界麵層厚度為0.5~3.5 mm;界麵層變形可分為凍土與結構接觸界麵上滑移變形和受結構約束的凍土剪切變形兩部分;結構麵粗糙度、凍土溫度和法嚮應力等因素對接觸界麵層的力學特性具有顯著影響。
위료해재하재작용하,접촉계면층발생적역학향응구별우동토화결구재료본신역학특성,사용신연제적동토여결구접촉계면층역학시험의,비교계통지연구인공동점토여조조강판접촉계면층단조전절역학특성。분별종굉관화세관2개각도출발,분석동토계면층적기본역학특성화수력변형궤리。결과표명:수착법향하재증대,접촉계면적봉치전응력、은정전응력、초시전절경도야증대,접촉계면적항전강도여법향응력정선성관계,가용마이-고륜준칙래묘술;동토과립적전절위이수동토심도증대이감소,동일동토심도내,전절위이수법향응력적증대이증대,불동조조도적결구접촉계면층변형특성기본상사,시험조건범위내접촉계면층후도위0.5~3.5 mm;계면층변형가분위동토여결구접촉계면상활이변형화수결구약속적동토전절변형량부분;결구면조조도、동토온도화법향응력등인소대접촉계면층적역학특성구유현저영향。
With the increasing of the number of structures in permafrost regions or structures (such as urban underground and mine shaft engineering) using freezing method, the properties of interface layer between frozen soil and structure are receiving more attention. Under the action of loads, the mechanical responses of interface layer are different from frozen soil and structure material. The interface layer between frozen soil and structure is vulnerable to severe damage under the loads of gravity, construction and earthquake, and thus will affect the safety and durability of structures. The newly developed mechanical testing apparatus is used to test the mechanical characteristics of interface layers between frozen soil and structure. Based on the existing apparatus called large-scale frozen soil direct shear system (DDJ-1) in our laboratory, the shearing box of frozen soil is modified to highlight the interface layer of frozen soil, and the measuring system of tiny deformation is developed, which thus constitute the experimental system. Micro deformation measuring system is composed of digital imaging system (DIS) and digital image processing software system (DIPSS). DIS consists of high definition and resolution camera (JHSM1400) and 7.2 mm distortionless industry fixed-focus camera, and DIPSS has functions of calibration setting, measurement setting and data display. The data received from the system are accurate and the error is about only 1μm. The newly developed mechanical testing apparatus is used to test the mechanical characteristics of interface layers between frozen soil and rough steel plate under the monotonic load. The mechanism of basic forces and deformation of the interface layers is analyzed from the perspectives of macro mechanics and micro deformation. The results show that the peak shearing stress, stable shearing stress and initial shearing stiffness increase with normal stress, and shearing strength of the interface layer is correlated with normal stress. The relationship between this maximum shear stress and normal stress follows the Mohr–Coulomb law. The value of friction angle increases with the roughness of interface at each temperature, and the value of friction angle of interface with the same roughness increases with the decrease of temperature. The value of friction angle of interface is close to that of frozen layer, which demonstrates that the shearing failure occurs in the internal of frozen soil. The shearing displacement of frozen soil particles decreases with the increase of interface layer depth, and increases with the increase of normal stress in the same depth of interface layer; and deformation characteristics of interface layer is similar among the structures with different roughness. The thickness of interface layer is about 0.5-3.5 mm within experimental conditions. The deformation of frozen soil can be decomposed into 2 parts, i.e. slide deformation at the interface and shearing deformation under constraint. The shearing strength of interface layer increases with the decrease of frozen soil temperature and when the temperature is below -10℃, the freezing force is raised significantly. Meanwhile, the shearing strength of interface layer increases with the roughness of structures and when the roughness is above 0.8 mm, the increase rate of shearing stress reduces. The roughness of interface, the temperature of frozen soil and the normal stress have profound effect on mechanic properties of interface layer.
