姓名: |
邵珠山 |
职称: |
教授 |
|
职务: |
理学院院长 |
导师类别: |
硕士研究生/博士研究生导师 |
邮箱: |
shaozhushan@xauat.edu.cn |
研究方向: |
岩石力学与工程,固废循环利用 |
1987.9~1991.6, 兰州大学力学系, 工学学士;
1997.9~2000.3, 西安交通大学建力学院(现航天航空学院), 工学硕士;
2001.1~2005.3, 西安交通大学建力学院(现航天航空学院), 工学博士。
2020.10~至今, 西安建筑科技大学, 理学院院长;
2018.12~至今, 西安建筑科技大学, 陕西省岩土与地下空间工程重点实验室副主任;
2021.12~至今, 西安建筑科技大学, 西安市建筑材料力学重点实验室主任;
2008.10~至今, 西安建筑科技大学, 教授, 博导;
2000.4~2008.7, 西安交通大学建力学院, 讲师;
1991.6~1997.8, 陕西飞机制造公司设计院, 结构强度工程师;
留学经历:
2005.8~2006.12, 新加坡国立大学(National University of Singapore), 博士后(Postdoctoral Research Fellow);
2007.1~2008.12, 南洋理工大学国家防护工程中心(Nanyang Technological University, PTRC ), 研究员(Research Fellow);
2012.7~2012.8, 南洋理工大学(Nanyang Technological University ), 访问教授(Visiting Professor);
2015.12~2016.05, 英国曼彻斯特大学, 访问教授(Visiting Professor).
长期致力于复合材料热弹性与多场断裂力学行为、岩石变形与失效的时效性理论等工程力学的教学与科研工作。 近5年主持国家自然科学基金等各类项目40余项, 出版学术专著2部, 申请发明专利70余项, 先后在国际行业顶级期刊、中文权威期刊等发表学术论文200余篇。
主要纵向科研:
[1]主持 微波辅助混凝土骨料资源化回收中的多场效应研究, 国家自然科学基金(面上项目)11872287, 2019~2022.
[2]主持 先进复合材料薄壁结构的高温振动特性研究,国家自然科学基金(10772143), 2007-2010.
[3]参与 超高速铣削材料的应力波去除机理研究,国家自然科学基金(51375373), 2014-2017.
[4]主持 微波辅助废弃混凝土骨料高效再资源化的技术开发与设备研制, 65万元, 陕西省重点研发计划重点产业创新链(群)-工业领域2019ZDLGY01-10, 2019~2021.
[5]主持 西安轨道交通运营沉降智能监测与评价设备的研制与开发,陕西省科技统筹创新工程计划项目(2013KTCQ01-16), 2013-2014.
[6]主持 西安地铁施工智能监测和预警系统的研制与开发, 陕西省工业重点合作单位项目(科技统筹), 2015~2016.
[7]主持 爆炸冲击作用下黄土地区浅埋地下结构和邻近建筑物的灾害响应和破坏机理研究,教育部留学归国人员基金(教外司留[2010]1174号),2009-2011.
学术专著:
[1]邵珠山, 隧道工艺力学, 科学出版社, 2015.
[2]Li XZ, Shao ZS, Qi CZ. Static Creep Micro-Macro Fracture Mechanics of Brittle Solids[M]. Singapore: Springer Nature Singapore, 2023.
近5年主要论文:
[1]Wu K, Shao ZS, Jiang YL, Zhao NN, Qin S, Chu ZF. Determination of stiffness of circumferential yielding lining considering the shotcrete hardening property[J]. Rock Mechanics and Rock Engineering, 2023, 56(4): 3023-3036.
[2]Xiao YH, Shao ZS, Wei W. Investigation of thermally-induced separation in mortar-aggregate under microwave irradiation[J]. Composite Structures, 2023, 316: 117035.
[3]Xiao YH, Shao ZS. Numerical analysis of mortar-aggregate separation induced by microwave heating[J]. International Journal of Thermal Sciences, 2023, 184: 107957.
[4]Xiao YH, Shao ZS, Wei W, et al. Effect of microwave pretreatment on mechanical behavior of concrete and aggregate recovery[J]. Construction and Building Materials, 2023, 387: 131647.
[5]Zhao NN, Shao ZS, Wu K. Analytical approach to evaluating the influence of the compressible layer on the time-dependent response of deep soft-rock tunnels[J]. International Journal of Geomechanics, 2023, 23(6): 04023070.
[6]Zhao NN, Shao ZS, Yuan B, et al. Analytical approach to estimating the influence of friction slip contact between surrounding rock and concrete lining on mechanical response of deep rheological soft rock tunnels[J]. Applied Mathematical Modelling, 2023, 113: 287-308.
[7]Cheng JC, Shao ZS, Wang Y, Wei W, Yuan Y. The current status and future of solid waste recycled building bricks[J]. Environmental Science and Pollution Research, 2023, 30(48): 105119-105148.
[8]Qin S, Shao ZS, Yuan B, et al. A simple prediction model for mechanical response of lined tunnels incorporating yielding elements[J]. International Journal of Applied Mechanics, 2023, 15(05): 2350031.
[9]Hong Y, Shao ZS, Wu K, et al. An extended 3D limit analysis of slope stability considering prestressed anchor cables reinforcement[J]. Archives of Civil and Mechanical Engineering, 2023, 23(1): 59.
[10]Xiao YH, Shao ZS, Wei W, et al. Study on mechanism of strength weakening of concrete subjected to microwaves in microwave-assisted concrete recycling[J]. International Journal of Heat and Mass Transfer, 2023, 213: 124353.
[11]Wu K, Song JN, Zheng XM, Zhao NN, Shao ZS, Zhu ZF. The deformation coordination-dominated design of yielding supports applied in large deformation tunnels[J]. Acta Geotechnica, 2024: 1-15.
[12]Wu K, Zheng XM, Zhao NN, Shao ZS. Effect of compressible layer on time-dependent behavior of soft-rock large deformation tunnels revealed by mathematical analytical method[J]. Applied Mathematical Modelling, 2024, 126: 457-481.
[13]Wu K, Sharifzadeh M, Shao Z, et al. Analytical model for soft rock tunnel with large deformation using stiff and yielding lining solutions[J]. International Journal of Geomechanics, 2023, 23(11): 04023207.
[14]Geng Q, Kong LY, Yang XW, Shao Z, Li YM. Phononic crystal pipe with periodically attached sleeves for vibration suppression[J]. International Journal of Mechanical Sciences, 2023, 251: 108344.
[15]Wu K, Song JN, Zhao NN, Shao Z. Study on the time‐dependent interaction between surrounding rock and yielding supports in deep soft rock tunnels[J]. International Journal for Numerical and Analytical Methods in Geomechanics, 2024, 48(2): 566-587.
[16]Cheng JX, Shao ZS, Wang Y, et al. Experimental study and performance improvement of recycled building bricks based on microwave sintering technology[J]. Journal of Building Engineering, 2024, 82: 108312.
[17]Cheng JX, Shao ZS, Wang Y, et al. Experimental study and performance improvement of recycled building bricks based on microwave sintering technology[J]. Journal of Building Engineering, 2024, 82: 108312.
[18]Cheng JX, Shao ZS, Wang Y, et al. Simulation analysis of microwave sintering of recycled building bricks based on three-phase porous medium model[J]. Construction and Building Materials, 2024, 414: 134956.
[19]Wu K, Xing CZ, Yang YZ, Shao ZS, Zhao NN, Zhu ZF. A unified design model for estimating tunnel performance considering multiple excavation stoppages[J]. Archives of Civil and Mechanical Engineering, 2023, 23(4): 260.
[20]Xiao YH, Shao ZS. Numerical analysis of mortar-aggregate separation induced by microwave heating. International Journal of Thermal Science, 2023, 184: 107957
[21]Zhao NN, Shao ZS, Yuan B, Chen XY, Wu K. Analytical approach to estimating the influence of fricition slip contact between surrounding rock and concrete lining on mechanical response of deep rheological soft rock tunnels. Applied Mathematical Modelling, 2022, 113:287-308.
[22]Wu K, Shao ZS, Sharifzadeh M, Hong SY, Qin S. Analytical computation of support characteristic curve for circumferential yielding lining in tunnel design. Journal of Rock Mechanics and Geotechnical Engineering, 2022, 14(1):144-152.
[23]Wu K, Shao ZS, Sharifzadeh M, Chu Z, Qin S. Analytical approach to estimating the influence of shotcrete hardening property on tunnel response. Journal of Engineering Mechanics, 2022, 148(1): 04021127.
[24]Zhao NN, Shao ZS, Chen XY, Yuan B, Qin S. Prediction of mechanical response of “a flexible support system” supported tunnel in viscoelastic geomaterials. Archives of Civil and Mechanical Engineering, 2022, 22: 160.
[25]Zhao NN, Shao ZS, Yuan B, Chen X, Wu K. Analytical approach to the coupled efects of slope angle and seepage on shallow lined tunnel response. International Journal of Applied Mechanics 2022, 14(2):2250003.
[26]Zhang HL, Wei W, Shao ZS, Qiao RJ. The investigation of concrete damage and recycled aggregate properties under microwave and conventional heating. Construction and Building Materials, 2022, 341: 127859.
[27]Geng Q, Fong PK, Ning J, Shao ZS, Li YM. Thermally-induced transitions of multi-frequency defect wave localization and energy harvesting of phononic crystal plate. International Journal of Mechanical Sciences, 2022, 222: 107253.
[28]Chen HZ, Shao ZS, Zhang Z. Impact of brittle creep failure on time-delayed characteristics of rockburst. Materials, 2022, 15(9): 3035.
[29]Yuan Y, Shao ZS, Qiao RJ, Guo X, Wang WT. Crack damage evolution in concrete coarse aggregates under microwave-induced thermal stress. Archives of Civil and Mechanical Engineering, 2022, 22(3): 1-23.
[30]Zhang PJ, Wei W, Shao ZS. Multifield coupling study on random aggregate concrete under microwave irradiation. Construction and Building Materials, 2022, 318: 126025.
[31]Wu K, Shao ZS, Qin S, Wei W, Chu Z. A critical review on the performance of yielding supports in squeezing tunnels, Tunnelling and Underground Space Technology, 2022, 115: 103815.
[32]Wu K, Shao ZS, Qin S, Zhao NN, Chu Z. An improved nonlinear creep model for rock applied to tunnel displacement prediction. International Journal of Applied Mechanics, 2021, 13(8):2150094.
[33]Qin S, Shao ZS, Wu K. Analytical assessment of coupled influences of surrounding rock reinforcement and deformation release on tunnel response. 2021, 26(6): 541-550.
[34]Zhao NN, Shao ZS, Wu K, Chu Z, Qin S. Time-dependent solutions for lined circular tunnels considering rockbolts reinforcement and face advancement effects. International Journal of Geomechanics, 2021, 21(10): 04021179.
[35]Wei W, Shao ZS, Zhang PJ, Zhang HL, Chen JX, Yuan Y. Thermally assisted liberation of concrete and aggregate recycling: comparison between microwave and conventional heating. Journal of Materials in Civil Engineering, 2021, 33(12): 04021370.
[36]Wang B, Li HB, Shao ZS, Chen SH, Li XF. Investigating the mechanism of rock fracturing induced by high-pressure gas blasting with a hybrid continuum-discontinuum method. Computers and Geotechnics, 2021, 140: 104445.
[37]Qiao RJ, Shao ZS, Yuan Y, Zhou H, Guo YB. An analysis model for the temperature and residual stress of tunnel liner exposed to fire. Archives of Civil and Mechanical Engineering, 2021, 21(4): 1-11.
[38]Liu LW, Li HB, Chen SH, Shao ZS, Zhou CB, Fu SY. Effects of bedding planes on mechanical characteristics and crack evolution of rocks containing a single pre-existing flaw. Engineering Geology, 2021, 293: 106325.
[39]Wei W, Shao ZS, Chen WW, Qiao RJ, Yuan Y, Chen JX. Heating process and damage evolution of microwave absorption and transparency materials under microwave irradiation. Geomechanics and Geophysics for Geo-Energy and Geo-Resources, 2021, 7(3): 1-17.
[40]Wei W, Shao ZS, Zhang PJ, Chen WW, Qiao RJ, Yuan Y. Experimental assessment of microwave heating assisted aggregate recycling from dried and saturated concrete. Materials and Structures, 2021, 54(4): 1-14.
[41]Cheng JX, Shao ZS, Xu T, Wei W, Qiao RJ, Yuan Y. Experimental research on sintering construction spoil bricks based on microwave heating technology. Environmental Science and Pollution Research, 2021, 28(48): 69367-69380.
[42]Wu D, Li HB, Shao ZS, Chen SH, Zhou CAB, Liu LW. Effects of infilling materials on mechanical behaviors and cracking process of pre-cracked rock: Insights from a hybrid continuum-discontinuum method. Engineering Fracture Mechanics, 2021, 253: 107843.
[43]Chen WW, Shao ZS, Wei W. Experimental study of the heating potential of mortar-aggregate under microwave irradiation. Journal of Materials in Civil Engineering, 2021, 33(7): 04021153.
[44]Yuan Y, Shao ZS, Qiao RJ, Fei XS, Wu DD. Quantifying damage evolution within olivine basalt based on crack propagation behavior under microwave irradiation. International Journal of Damage Mechanics, 2021, 30(10): 1617-1641.
[45]Chen WW, Shao ZS, Wei W, Zhang PJ, Hong Y. Properties of concrete incorporating microwave treated coarse aggregate: an experimental study, Structures, 2021, 33: 693-702.
[46]Yuan Y, Shao ZS, Qiao RJ, Fei XS, Chen JX, Wei W. Fracture behavior of concrete coarse aggregates under microwave irradiation influenced by mineral components. Construction and Building Materials, 2021, 286: 122944.
[47]Wei W, Shao ZS, Qiao RJ, Chen WW, Zhou H, Yuan Y. Recent development of microwave applications for concrete treatment. Construction and Building Materials, 2021, 269: 121224.
[48]Wei W, Shao ZS, Qiao RJ, Chen WW, Zhang PJ, Cheng JX. Workability and mechanical properties of microwave heating for recovering high quality aggregate from concrete. Construction and Building Materials, 2021, 276: 122237.
[49]Wei W, Shao ZS, Chen WW, Zhang PJ, Cheng JX. Experimental study on thermal and mechanical behavior of mortar-aggregate under microwave irradiation. Journal of Building Engineering, 2021, 34: 101947.
[50]Wu K, Shao ZS, Hong SY, Qin S. Analytical solutions for mechanical response of circular tunnels with double primary linings in squeezing grounds. Geomechanics and Engineering, 2020, 22(6): 509-518.
[51]Wu K, Shao ZS, Qin S. A solution for squeezing deformation control in tunnels using foamed concrete: a review. Construction and Building Materials, 2020, 257:119539.
[52]Wu K, Shao ZS, Qin S, Li B. Determination of deformation mechanism and countermeasures in silty clay tunnel. Journal of Performance of Constructed Facilities-ASCE, 2020, 34(1): 04019095.
[53]Wu K, Shao ZS, Qin S. An analytical design method for ductile support structures in squeezing tunnels. Archives of Civil and Mechanical Engineering, 2020, 20(3): 91.
[54]Wu K, Shao ZS, Qin S, Zhao NN. Analytical-based assessment of effect of highly deformable elements on tunnel lining within viscoelastic rocks. International Journal of Applied Mechanics, 2020, 12 (3): 2050030.
[55]Li XZ, Qu XL, Qi CZ, Shao ZS. An analytical model of multi-stress drops triggered by localized microcrack damage in brittle rocks during progressive failure. International Journal of Damage Mechanics, 2020, 29(9): 1345-1360.
[56]Li XZ, Qi CZ, Ban LR, Shao ZS. An analytical microcrack-based rock model with implications for earthquake mechanisms induced by stress changes. Mathematical Geosciences, 2021, 53(4): 689-710.
[57]Li XZ, Ma C, Qi CZ, Shao ZS. Crack velocity-and strain rate-dependent dynamic compressive responses in brittle solids. Theoretical and Applied Fracture Mechanics, 2020, 105: 102420.
[58]Li XZ, Shao ZS, Qi CZ. An analytical micro-macro model of stress drops during brittle creep in rocks. Engineering Fracture Mechanics, 2020, 223: 106794.
[59]Li XZ, Xia C, Qi CZ, Shao ZS. Dynamic localized shear failure influenced by changing rates in brittle solids containing initial microcracks. International Journal of Impact Engineering, 2020, 135: 103408.
[60]Wu K, Shao ZS. Study on the effect of flexible layer on support structures of tunnel excavated in viscoelastic rocks. Journal of Engineering Mechanics, 2019, 145(10): 04019077.
[61]Wu K, Shao ZS, Qin S, Zhao NN. Mechanical analysis of tunnels supported by yieldable steel ribs in rheological rocks. Geomechanics and Engineering, 2019, 19(1): 61-70.
[62]Wu K, Shao ZS. Visco-elastic analysis on the effect of flexible layer on mechanical behavior of tunnels. International Journal of Applied Mechanics, 2019, 11(03): 1950027.
[63]Wei W, Shao ZS, Zhang YY, Qiao RJ, Gao JP. Fundamentals and applications of microwave energy in rock and concrete processing-a review. Applied Thermal Engineering, 2019, 157: 113751.
[64]Li XZ, Qu XL, Qi CZ, Shao ZS. A unified analytical method calculating brittle rocks deformation induced by crack growth. International Journal of Rock Mechanics and Mining Sciences, 2019, 113: 134-141.
[65]Li XZ, Qi CZ, Shao ZS. A study on the creeping failure related to crack inclination of brittle rocks. KSCE Journal of Civil Engineering, 2019, 23(1): 444-451.
[66]Qiao RJ, Shao ZS, Liu FY, Wei W. Damage evolution and safety assessment of tunnel lining subjected to long-duration fire. Tunnelling and Underground Space Technology, 2019, 83: 354-363.
主要发明专利
[1]邵珠山,乔汝佳,张林涛,王明卿,郑钦文, 刘涛. 一种基于PSD传感器隧道拱顶沉降的自动化监测装置.专利类型:发明, 专利号:ZL201611029744.1/2017.05.24
[2]邵珠山, 王新宇, 熊阳阳, 范艳国.一种岩土工程注浆效果评价装置.专利类型: 发明, 专利号: ZL201410626075.0/ 2017.04.19
[3]邵珠山, 郑钦文, 乔汝佳, 刘涛, 王明卿, 张林涛.一种用于地表沉降监控的铟钢尺自动升降监测装置及方法. 专利类型: 发明, 专利号: ZL201610825341.1/2018.09.28
[4]邵珠山, 宋林, 王新宇. 一种隧道施工信息化动态监测系统及其监测方法. 专利类型: 发明, 专利号:ZL201210063334.4/2013.12.25.
[5]邵珠山, 王新宇, 桂学, 张艳玲. 一种发泡混凝土夹芯的防爆保温多功能板材的制备方法. 专利类型: 发明, 专利号:ZL201210241187.5/2014.08.20
[6]邵珠山, 陈浩哲, 乔汝佳, 张媛媛, 张硕成. 一种循环动载土体沉降的模型试验装置及试验方法. 专利类型: 发明, 专利号:ZL201711206134.9/ 2020.07.07
[7]邵珠山, 陈浩哲, 乔汝佳, 刘云鹏, 张喆. 一种微幅振动岩土动力沉降实验仪器及使用方法. 专利类型: 发明, 专利号:ZL201810210562.7/2020.04.2
[8]邵珠山, 袁媛, 吴奎, 魏玮. 一种建筑物废弃混凝土高品质再生骨料回收设备专利类型: 发明, 专利号:ZL201811314373.0/2023.06.09
[9]邵珠山, 高帆, 吴回获, 乔汝佳, 席慧慧, 周航, 郭银波. 利用微波加热实现混凝土自裂破碎和骨料回收装置及方法. 专利类型:发明, 专利号:ZL 2022 1 0668229.7/2024.03.01
[10]邵珠山, 张喆, 张振龙, 张鹏举, 张宇鹏. 基于地震干涉法的隧道超前地质预报方法及系统. 专利类型:发明, 专利号:ZL 2021 1 0722762.2/2024.03.01
[11]邵珠山;周航;乔汝佳;郭银波;袁媛;陈文文. 基于微波技术的高品质沥青混合料粗骨料再生装置及方法. 专利类型:发明, 专利号:ZL 2020 1 0292133.6/2024.02.27
[12]邵珠山,郭银波,刘韡,乔汝佳,周航,袁媛,郭轩. 一种基于微波技术的振动离心式沥青骨料再生装置及方法. 专利类型:发明, 专利号:ZL2020102915231/2020.04.1
[1]功能材料与结构的多场效应与破坏理论,国家自然科学奖,二等,2013.
[2]高地应力软岩隧道柔性支护体系的力学理论基础研究与应用. 中国岩石力学与工程学会自然科学一等奖, 2023年.
[3]邻近既有线的隧道爆破开挖振动控制技术与工程应用, 陕西省科学技术进步奖, 二等, 2021.
[4]岭南富水崩坡积堆积体综合治理与进洞关键技术研究, 山西省科学技术奖, 三等, 2021.
[5]一二阶地间特长隧道综合施工关键技术研究, 工程建设科学技术进步奖(中国施工企业管理协会), 二等, 2020.
[6]高地应力软岩隧道柔性支护体系的力学理论基础研究与应用, 陕西高等学校科学技术奖, 一等奖, 2023年.
[7]功能梯度结构的热弹性问题与非线性响应,陕西省高校科技进步一等奖, 2012.
中国岩石力学与工程学会工程安全与防护分会副理事长
第八届中国岩石力学与工程学会理事
中国岩石力学与工程学会岩石动力学专业委员会常务委员
陕西省岩石力学与工程学会常务理事