露出 户外 江苏大学主页平台解决系统 卢永刚
发布日期:2024-09-28 15:04 点击次数:126一、个东说念主能够
卢永刚,男,博士,副老师,硕士生导师。主要从事流体机械多相流动多场耦合表面酌量,以及新能源修复研发和工程诈欺。主捏或主要参与国度级和省部级科研课题12项,企业托付课题10余项;获省部级科技跳跃奖二等奖3项、三等奖1项;共发表学术论文40余篇,其中以第一或通信作家发表SCI论文15篇;发明专利授权49项,实用新式专利授权17项。
二、主要酌量场所
(1) 流体机械多相瞬变流动表面与流动胁制
(2) 流体机械结构强度优化遐想与多场耦合
(3) 核电泵、水轮机、水泵水轮机、混输泵等多学科遐想优化
三、讲讲课程
(1) 《流体机械强度运筹帷幄》(本科)
(2) 《流体机械内流激发表面及胁制》(酌量生)
(3) 《Applied Process Assessment with Machine Learning》(英文助教)
四、科研终局
1、科研形势
(1) 国度当然科学基金面上形势,海上移动核电站主轮回泵汽液两相全特质瞬态机理,50万,参与(第2)
(2) 江苏省当然科学基金后生形势,深海矿浆泵气液固三相混输流动特质及多相流冲蚀磨损机理酌量,20万,主捏
(3) 中国博士后科学基金面上形势,深海矿浆泵气液固三相非稳态流动特质及四象限失效分析,8万,主捏
(4) 水沙科学国度重心本质室及宁夏水联网衔尾基金,梯级扬水泵站优化调度与智能运维技巧,10万,主捏
(5) 先进反应堆栽植部重心本质室通达课题,汽液两相工况核主泵非稳态流动及涡能源学特征,2万,主捏
(6) 清华大学,高水头水泵水轮机宽负荷遐想及转轮裂纹毁伤展望与彭胀酌量,152万,主捏
(7) 上海阿波罗机械股份有限公司,巴基斯坦恰希玛核电厂五号机组轮回水系统瞬态分析,18万,主捏
(8) 清华大学,水泵水轮机及输水系统过渡经由三维水激振动反映分析,30万,主捏
(9) 哈工大机器东说念主(合肥)海外酌量院,基于XXX工业母机故障监测系统,25万,主捏
(10) 江苏瑞阳环保有限公司,重金属轴流泵的多学科优化遐想,25万,主捏
(11) 国度重心研发子任务,LNG装卸三维流动特质及振动反映分析评估,600万,主研
(12) 山东潍坊抽水蓄能有限公司,山东潍坊抽水蓄能水泵水轮机及输水系统三维水激振动,295万,主研
(13) 中国三峡建工集团有限公司,1000MW水轮发电机组能源学特质多场耦合酌量,672万,主研
(14) 国度电投集团科学技巧酌量院,高温铅液态铅铋泵(A)研制(采购形势),52万,主研
(15) 江苏省重心研发策画,海水移动核电高温重金属核主泵要害技巧研发,120万,主研
(16) 江苏省重心研发策画,铅铋冷却反应堆高温液态金属主轮回泵要害技巧研发,120万,参研
(17) 水沙科学国度重心本质室课题,变速抽蓄机组双调格局流固耦合振动机理酌量,150万,参研
(18) 哈尔滨电气能源装备有限公司,混流式轴封型反应堆主泵水力部件全特质测验酌量,160万,参研
2、学术论文代表作
(1) Lu Y G, Zhu R S, Wang X L, et al. Study on gas-liquid two-phase all-characteristics of CAP1400 nuclear main pump[J]. Nuclear Engineering and Design, 2017, 319: 140-148.
(2) Lu Y G, Zhu R S, Wang X L, et al. Study on the complete rotational characteristic of coolant pump in the gas-liquid two-phase operating condition[J]. Annals of Nuclear Energy, 2019, 123: 180-189.
(3) Lu Y G, Zhu R S, Fu Q, et al. Research on the structure design of the LBE reactor coolant pump in the lead base heap[J]. Nuclear Engineering and Technology, 2019, 51(2): 546-555.
(4) Lu Y G, Zhu R S, Wang X L, et al. Experimental study on transient performance in the coasting transition process of shutdown for reactor coolant pump[J]. Nuclear Engineering and Design, 2019, 346: 192-199.
(5) Lu Y G, Yun Long, Zhu R S, et al. Transient Structural load characteristics of reactor coolant pump rotor system in rotor seizure accident [J]. Annals of Nuclear Energy, 2021, 164: 108631.
(6) Lu Y G, Wang X L, Fu Q*, et al. Comparative analysis of internal flow characteristics of LBE-cooled fast reactor main coolant pump with different structures under reverse rotation accident conditions[J]. Nuclear Engineering and Technology, 2021, 53(7): 2509-2522.
(7) Lu Y G, Wang Z W, Zhu R S, et al. Study on flow characteristics in LBE-cooled main coolant pump under positive rotating condition [J]. Nuclear Engineering and Technology, 2022.
(8) Lu Y G, Zhao W, Alexandre P*, et al. Shutdown idling performance of the nuclear main coolant pump under station blackout accident: An optimization study[J]. Part A: Journal of Power and Energy, 2022.
(9) Wang X L, Lu Y G, Zhu R S*, et al. Study on pressure pulsation characteristics of reactor coolant pump during the idling transition process[J]. Journal of Vibration and Control, 2019, 25(18): 2509-2522.
(10) Wang X L, Lu Y G, Zhu R S*, et al. Study on the transient evolution law of internal flow field and dynamic stress of reactor coolant pump under rotor seizure accident[J]. Annals of Nuclear Energy, 2019, 133: 35-45.
(11) Ma Z*, Lu Y G, Liu G F, et al. Enhanced cyclic redox reactivity of hematite via Sr doping in chemical looping combustion[J]. Journal of the Energy Institute, 2022, 100: 206–212.
(12) Wang X L, Lu Y G, Zhu R S, et al. Study on bidirectional fluid-solid coupling characteristics of reactor coolant pump under steady-state condition[J]. Nuclear Engineering and Technology, 2019, 51(7): 1842-1852.
(13) Wang X L, Lu Y G, Zhu R S*, et al. Experimental study on transient characteristics of reactor coolant pump under rotor seizure accident [J]. Annals of Nuclear Energy, 2020, 136: 1-10.
(14) Zhao Y Y, Lu Y G, Zhu R S*, et al. MDO strategy for meridian plane design to improve energy conversion capability of LFR main coolant pump[J]. Annals of Nuclear Energy, 2020, 148:107763.
(15) Wang X L, Lu Y G*, Zhu R S, et al. Study of non-liner cavitation on flow characteristics inside the centrifugal pump [J]. Journal of the Balkan Tribological Association, 2016,22(3), 2826-2842.
(16) Wang X L, Lu Y G*, Zhu R S, et al. Study of hydraulic performance and pressure pulsation characteristics of the grinder pump in case of clogging [J]. Bulgarian Chemical Communications, 2016, 48:87-95.
(17) Zhu R S, Chen Y M, Lu Y G*, et al. Research on structure selection and design of LBE-cooled fast reactor main coolant pump [J]. Nuclear Engineering and Design, 2020, 110973.
偷拍厕所女同学(18) Wang X L, Xie Y J, Lu Y G, et al. Mathematical modelling forecast on the idling transient characteristic of reactor coolant pump[J]. Processes, 2019, 7(7):452.
(19) Ma Z*, Zhang S, Lu Y G. Activation mechanism of Fe2O3‑Al2O3 oxygen carrier in chemical looping combustion[J]. Energy and Fuels, 2020. doi.org/10.1021/acs.energyfuels.0c02967.
(20) Ma Z*, Liu G F, Lu Y G, et al. Improved redox performance of Fe2O3/Al2O3 oxygen carrier via element doping in chemical looping combustion[J]. Fuel Processing Technology, 2020, 224: 107030.
(21) Ma Z*, Zhang S, Lu Y G. Phase segregation mechanism of NiFe2O4 oxygen carrier in chemical looping process[J]. International Journal of Energy Research, 2021. DOI: 10.1002/er.6026.
(22) Ma Z, Liu G F, Lu Y G, et al. Redox performance of Fe2O3/Al2O3 oxygen carrier calcined at different temperature in chemical looping process[J]. Fuel,2021, 122381. doi.org/10.1016/j.fuel.2021.122381.
(23) Ma Z, Yuan C, Lu Y G, et al. Effect of supports on the redox performance of pyrite cinder in chemical looping combustion[J]. Chinese Journal of Chemical Engineering, 2020.
3、授权发明专利
(1) 卢永刚, 高波, 张宁, 等. 一种深海采矿垂向擢升泵管系统, ZL202111264471.X.
(2) 卢永刚, 高波, 马忠, 等. 一种风冷型筒式联轴器, ZL202010982885.5.
(3) 卢永刚, 冯琦, 高波, 等. 一种氢燃料电板氢气供给系统, ZL202111264017.4.
(4) 卢永刚, 王洋, 朱荣生, 等. 一种鱼友好轴空轴流泵, ZL201610586021.5.
(5) 卢永刚, 王洋, 朱荣生, 等.一种核主泵反螺旋线导叶及遐想方法, ZL201610009409 .9.
(6) 卢永刚, 王秀礼, 朱荣生, 等. 重金属轴流泵的多学科优化遐想方法, ZL201611049061.2.
(7) 卢永刚, 高波, 张宁, 等. 一种新式对转泵结构十分责任模式, ZL202110078434.3.
(8) 王秀礼, 卢永刚, 朱荣生, 等. 一种可智能减振的泵站安装方法, ZL201710084158.5.
(9) 王秀礼, 卢永刚, 陈文采, 等. 一种泵站防涡旋智能导流安装, ZL201710038039.6.
(10) 王秀礼, 卢永刚, 朱荣生, 等.一种高温泵测验系统以及测验方法, ZL201810275310.2.
(11) 王秀礼, 卢永刚, 朱荣生, 等. 一种带整流叶片的离心泵叶轮, ZL201710082658.5.
(12) 朱荣生, 卢永刚, 王秀礼, 等. 基于遗传算法的高温高压离心式叶轮多学科优化方法, ZL201611050738.4.
(13) 朱荣生, 卢永刚, 王秀礼, 等. 基于多学科优化的高温高压离心泵叶轮概括遐想方法, ZL201611049233.6.
(14) 朱荣生, 卢永刚. 一种气液流量调度阀, ZL201410675608.4.
(15) 朱荣生, 卢永刚. 一种磁流体介质润滑立式磁悬浮推力轴承, ZL201611112586.6.
(16) 朱荣生, 卢永刚. 一种用于潜水泵水下管路的自动耦合机构, ZL201611114159.1.
(17) 朱荣生, 卢永刚. 一种带双聚散机构的轴流式水泵水轮机, ZL201611149428.8.
(18) 朱荣生, 卢永刚. 一种泵用静水式水润滑轴承结构, ZL201611136041.9.
(19) 朱荣生, 卢永刚. 一种新式密封机构的水力遐想方法, ZL20140677310.7.
(20) 朱荣生, 卢永刚. 一种无窒碍泵的水力遐想方法, ZL201510346507.7.