梁儒全，男，博士，教授，东北大学博士生导师、临沂大学与辽宁科技大学硕士生导师。国际期刊《Current Chinese Science》副主编、《Current Mechanics and Advanced Materials》编委，中文国际期刊《力学研究》、《流体力学》、《冶金工程》编委。2012年获辽宁省十百千高端引进人才称号；2017年获沈阳市高层次人才称号；2018年获英国教育与研究者国际学会 IEEE计算、电子与通信工程国际会议论文奖；2020年沂蒙惠才钻石卡获得者；2011年获沈阳市自然科学学术成果一等奖；2001-2002年日本学术振兴会外国人研究员、2002-2007年加拿大多伦多大学研究助理。第五届国家微重力科学与应用专业委员会委员；国家自然科学基金委-中科院空间科学卫星联合基金会议评审专家；国家科技进步奖评审专家；教育部学位中心学位论文评审专家；中国力学会高级会员。近年，牵头组建了临沂大学热能工程研究所和临沂市节能减排研究中心。

    作为项目负责人主持国家自然科学基金项目4项、教育部/外国专家局学校重点外专引智项目2项及多项省部级项目。承担过日本学术振兴会重大项目-未来开拓学术研究推进事业、加拿大宇航局基金、日本宇航局基金、日本学术振兴会外国人特别研究员基金。目前主持国家自然科学基金项目1项、河东区重大专项1项、教育部产学研协同育人项目1项。以第一作者及通讯作者在《Exp. Thermal Fluid Sci..》、《Int. J. Heat Fluid Flow》、《J. Heat Transfer》等刊物发表SCI收录论文40篇，英文专著独立章节4部，授权发明专利12项、实用新型11项、软件著作权1项。与加拿大、美国、英国及日本等国大学与研究机构具有长期合作与交流。

基本信息

办公地点：汽车实训中心201室      邮箱：tpjsli@163.com   手机：19863913897

研究方向：

1、单晶硅性能控制系统开发；

2、多相流理论及控制技术；

3、节能减排技术应用。

代表性科研项目：

[1] 国家自然科学基金面上项目（51976087），热致扩散效应基础理论与关键技术，2020年，59万元，主持。

[2] 国家自然科学基金面上项目（51676031），考虑自由面动态变形的振荡热-溶质毛细对流研究，2016年，60万元，主持。

[3] 国家自然科学基金面上项目（51376040），微重力下周围剪切气流引入气液自由面动态变形研究，2013年，80万元，主持。

[4] 国家自然科学基金面上项目（11072057），重力颤动与磁场耦合作用下高 Prandtl 数流体热毛细对流研究，2010年，38万元，主持。

代表性学术论文：

[1] Liang  R. Q., Jin X. C., Yang S., Shi J. H., Zhang S., Study on flow structure transition in thermocapillary convection under parallel gas flow, Experimental Thermal and Fluid Science, 113, 110037, 2020

[2] Liang R. Q., Zhao  S., Fan J. G., Zhang S., Effect of horizontal vibrations on thermos-solutocapillary convection and free surface of liquid bridge, Microgravity Science and Technology, 32, 847-855, 2020

[3] Song Y. M., Liang  R. Q., Wang F., Zhang D. H., Yang L., Zhang D. B., Enhanced methane hydrate formation in the highly dispersed carbon nanotubes-based nanofluid, Fuel, 285, 119234, 2021

[4] Chen X., Liang R. Q., Wang Y., Xia Z., Wu L. C., Liang Y., Cui G., A theoretical study of the temperature gradient effect on the Soret coefficient in n-pentane/n-decane mixtures using non-equilibrium molecular dynamics, Journal of Non-Equilibrium Thermodynamics, 45(4), 319-332, 2020

[5] Song Y. M., Liang  R. Q., Wang F., Shi J. H., Zhang D. B., Yang L., Enhancement of clathrate hydrate formation kinetics using carbon-based material promotion, Frontiers in Chemistry, 8(464), 1-7, 2020

[6] Zhang D. B., Tang  Y. Q., Liang R. Q., Yang L., Chen L. Q., Dynamic stability of an axially transporting beam with two-frequency parametric excitation and internal resonance, European Journal of Mechanics/A Solids, 104084, 2020

[7] Zhang D., Liang  R. Q., Liu Z. K., Yang H. B., Shi J. H., Song Y. M., Zhang D. B., Liu A. M., Research on the interfacial interaction between polyacetylene and silver nanowire, Macromolecular Theory and Simulations, 139(12), 2000034(1-8), 2020

[8] Zhang D. H., Liang  R. Q., Liu Z. K., Yang H. B., Shi J. H., Song Y. M., Liu A. M., Formation of polynylon 12/carbon nanotubes composites through self-coiling process: a molecular dynamic simulation, Journal of Nanoparticle Research, 22(173), 1-10, 2020

[9]Zhang D. H., Liu Z. K. Yang H. B., Liang R. Q., Shi J. H., Liu A. M., Investigation of the interaction between graphene and fullerene C70: a molecular dynamics simulation, Indian Journal of Physics, doi.org/10.1007/s12648-020-01740-4

[10] Yang L., Yang S. P., Liang R. Q., Zhang D. B., Song Y. M., Vibration analysis of locomotive transmission system, Engineering Research Express, 2, 035001, 2020

[11] Shi J. H., Bian L. P., Liang R. Q., Xiao S., Heat transfer characteristics of twin circular jet impingement cooling on the strip surface after rolling, Materials Science and Engineering, 472, 012042, 2019

[12] Liang  R. Q., Zhou J. L., Yang S., Zhang Y. Y., Shi J. H., Xiao S., Experimental study on transition characteristics of thermo-solutocapillary convection under buoyancy, Experimental Thermal and Fluid Science, 106, 38-47, 2019

[13] Yang S., Liang  R. Q., Wang G. F., Gao Y., Ma R., Xu Y. N., Xia Y. F., The experimental investigation on dynamic response of free surface for non-isothermal liquid bridge with the varying shear airflow, Experimental Thermal and Fluid Science, 98, 662-673, 2018

[14] Yang S., Liang R. Q., He J. C., Oscillating characteristic of free surface from stability to instability of thermocapillary convection for high Prandtl number fluids, International Journal of Heat and Fluid Flow, 61(part B), 298-308, 2016

[15] Yang S., Liang  R. Q., Xiao S., He J. C., Zhang S., Influence of ambient airflow on free surface deformation and flow pattern inside liquid bridge with large Prandtl number fluid (Pr > 100) under gravity, Journal of Heat Transfer, 139(12), 122001-1220010, 2017

[16] Ji J. H., Liang  R. Q., He J. C., Numerical simulation on bubble behavior of disintegration and dispersion in stirring-injection magnesium desulfurization process, ISIJ International, 57(3), 453-462，2017

[17] Ji J. H., Liang  R. Q., He J. C, Simulation on mixing behavior of desulfurizer and high-sulfur hot metal based on variable-velocity stirring, ISIJ International, 56(5), 794-802, 2016

[18] Yang S., Liang R. Q., Yan F. S., Gao T. Y., Feng Y. T., Thermocapillary Convection and Surface Fluctuation in a Liquid Bridge under Lateral Vibrations, Microgravity Science and Technology, DOI 10.1007/s12217-014-9407-8, 2015

[19] Geng D. Q., Zheng J. X, Wang K., Wang P., Liang R. Q., Liu H. T, Lei H., He J. C., Simulation on Decarburization and Inclusion Removal Process in RH with ladle bottom blowing, Metallurgical and Materials Transactions B, DOI: 10.1007/s11663-015-0314-1, 2015

[20] Liang R. Q., Yang S., Yan F. S., Static magnetic fields to liquid bridges:A numerical study, International Journal of Applied Electromagnetics and Mechanics, Vol.45, 3-10, 2014

[21] Liang R. Q., Kawaji M., Surface oscillation and flow structure of a liquid bridge under small vibration, Chinese Physics Letters, Vol.31(4), 044701, 2014

[22] Liang R. Q., Yang S., Li J. Z., Thermocapillary Convection in floating zone with axial magnetic fields, Microgravity Science and Technology, Vol.25, 285-293, 2014

[23] Liang R. Q., Bei D., Yan F. S., Geng D. Q. Thermocapillary Convection of low Prandtl number fluids under uniform magnetic fields, Applies Mechanics and Materials, Vol.580-583, 2970-2973, 2014

[24] Liang R. Q., Zhang Z. H., Gao T. Y., Yan F. S. Influence of vertical vibration on surface velocity of a liquid bridge, Applies Mechanics and Materials, Vol.580-583, 2890-2893, 2014

[25] Liang R. Q., Yang S., Yan F. S., He J. C., Kinetics of oxidation reaction for magnetite pellets, Journal of Iron and Steel Research, International, Vol.20(9), 16-20, 2013

[26] Liang R. Q., Duan W. J., Duan G. D., Ba J., Thermocapillary convection in a floating half zone, Applied Mechanics and Materials, Vol.248, 218-223, 2013

[27] Liang R. Q., Yang S., Ji J. H., He J. C., Flow of high Prandtl number fluid under varying axial magnetic field, Applied Mechanics and Materials, Vols.256-259, 2412-2415, 2013

[28] Liang R. Q., Yang S., Ji J. H., He J. C., Effect of axial magnetic field strengths on radial velocity field in a liquid bridge under microgravity, Applied Mechanics and Materials, Vols.256-259, 1670-1673, 2013

[29] Liang R. Q., Yang S., Ji J. H., Yan F. S., He J. C., Temperature distribution of high Prandtl numbeer liquid bridge under zero gravity, Advanced Materials Research, Vol.712-715, 1638-1641, 2013

[30] Liang R. Q., Yang S., Yan F. S., Ji J. H., He J. C., Numerical study on high Prandtl number liquid bridge, Advanced Materials Research, Vol.712-715, 1630-1633, 2013

[31] Liang R. Q., Yang S., Ji J. H., He J. C., Flow characteristics for high Prandtl number fluid under zero gravity, Applied Mechanics and Materials, Vols.353-356, 3611-3614, 2013

[32] Liang R. Q., Ji J. H.,  Yan F. S., He J. C., Numerical study on flow characteristics in a stirring vessel, Applied Mechanics and Materials, Vols.130-134, 3050-3053, 2012

[33] Liang R. Q., Yan F. S.,  Ji J. H., He J. C., Numerical simulation of particle mixing feature for a gas-liquid-solid three phase flow in an impeller-driven stirred vessel, Applied Mechanics and Materials, Vols.130-134, 869-872, 2012

[34] Liang R. Q., Ji J. H., Yan F. S., Kawaji M., An experiment on the surface stability of a liquid bridge, Advanced Materials Research, Vol.502, 249-252, 2012

[35] Yan F. S., Zhang W. J., Liang R. Q., Numerical study on turbulence modification in particle-laden pipe flows, Applied Mechanics and Materials, Vols.130-134, 3603-3606, 2012

[36] Ji J. H., Liang R. Q., Feng Y. T., He J. C., Study on the characteristics of fluid flow in stirring vessel of new type stirring of KR desulphurization, Journal of Iron and Steel Research, International, Vol.19(S1), 171-174, 2012

[37] Yan F. S., Zhang W. J., Liang R. Q., Validation of a proposed model for computing turbulence variation in air-particle flows, Communications in Computer and Information Science, Vols.289, 430-437, 2012

[38] Yan F. S., Zhang W. J., Liang R. Q., A mathematical model for predicting turbulence variation in air-particle two phase flows, Communications in Computer and Information Science, Vols.289, 422-429, 2012

[39] Liang R. Q., Duan G. D., Investigation of thermocapillary convection of high prandtl number fluid under microgravity, (NASA) Materials Research in Microgravity TMS2012, 177-184, Orlando, Florida, 2012.03.11-15

[40] Liang R. Q., Liao Z. Q., Jiang W., Duan G. D., Shi J. Y., Liu P., Numerical simulation of water droplets falling near a wall: Existence of wall repulsion,  Microgravity Science and Technology, Vol.23(1), 59-65, 2011

[41] Liang R. Q., Liang D., Yan F. S., Liao Z. Q., Duan G. D., Bubble motion near a wall under microgravity: Existence of attractive and repulsive forces,  Microgravity Science and Technology, Vol.23(1), 79-88, 2011

[42] Liang R. Q., Duan G. D., Jiang W., Yan F. S., Ji J. H., Kawaji M., Flow structure and surface deformation of high Prandtl number fluid under reduced gravity and microgravity, Microgravity Science and Technology, Vol.23(1), 113-121, 2011

[43] Liang R. Q., Liao Z. Q., Liang S., Solving dam break problem considering wall adhesion,  Microgravity Science and Technology, Vol.23(1), 49-57, 2011

[44] Liang R. Q., Liang S., Ji J. H., Esfahany M. N., Ichikawa N., Kawaji M., Effect of G-Jitter on multiphase fluid systems, Chinese Journal of Space Science, Vol.31(3), 355-360, 2011 (in Chinese)

[45] Liang R. Q., Ji J. H., He J. C., Study on desulphurization in molten iron pretreatment process based on a new stirring method, Journal of Iron and Steel Research, International, Vol.18(S2), 107-112, 2011

[46] Yan F. S., Liang R. Q., He J. C., Computational prediction of turbulence modification in gas-solid two-phase flows, Communications in Computer and Information Science, Vols.202(2), 134-141, 2011

[47] Liang R. Q., Kawaji M., Surface oscillation of a liquid bridge induced by single and multiple vibrations,  Microgravity Science and Technology, Vol.21, 31-37, 2009

[48] Liang R. Q., Chen Z., Dynamics for droplets in normal gravity and microgravity, Microgravity Science and Technology, Vol.21, 247-524, 2009

[49] Liang R. Q., Kawaji M., Effect of small and lateral vibrations on the surface oscillation of isothermal liquid bridge, Journal of  The Japan Society of  Microgravity Application, Vol. 25, No.3, 225-230, 2008

[50] Liang R. Q., He J. C., Moving behavior of pellets in a pellet shaft furnace, Journal of Central South University of Technology, Vol.15(S1), 280-283, 2008

[51] Kawaji M., Liang R. Q., Esfahany M. N., Stefani S. S., Yoda S., The effect of small vibrations on Marangoni convection and the free surface of a liquid bridge, Acta Astronautica, Vol.58 (12), 622-632, 2006

招生要求

 1、具有良好的控制理论基础、计算机编程和动手能力，数学基础扎实、熟练应用Fluent等软件者优先考虑。

 2、具备良好的语言书写表达能力和英语听说读写能力，公开发表过文章者优先考虑。

3、性格开朗，具备良好的心理承受能力和团队协作精神，具有继续深造攻读国内、外博士意愿者优先考虑。