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学习工作简历：

2022年7月-至今，北京科技大学，土木与资源工程学院，副教授

2019年-2020年，伦敦大学学院（UCL），巴特莱特建筑学院(世界排名第一)，访问学者

2015年8月-2022年7月，北京科技大学，土木与资源工程学院，讲师

2010年9月-2015年7月，北京大学，能源与资源工程专业，博士

2006年9月-2010年7月，北京科技大学，建筑环境与设备工程专业，学士

研究领域：

[1] 低碳、智能建筑技术

[2] 绿色生态建筑材料研制及表征

[3] 建筑热工环境模拟与仿真

[4] 资源开发与高效循环利用

教育教学：

[1] 传热学，本科生专业必修课，48学时

[2] 被动式建筑技术，本科生选修课，32学时

[3] 可持续建筑理论和技术，研究生选修课，32学时

荣誉获奖：

[1] 北京科技大学优秀硕士学位论文指导教师，2023

[2] 北京科技大学第13届青年教师教学基本功比赛校级三等奖，2023

[3] 北京市科协“千人进千企”专项行动产业特派员，2023

[4] 北京科技大学优秀本科生全程导师，2021

[5] 北京科技大学优秀工会积极分子，2017

近年主持的教学项目：

[1] 北京科技大学校级规划教材（讲义），JC2023JY003，2023.6-2025.6，主持。

[2] 北京科技大学课程思政特色示范课程建设项目，KC2022SZ15，2022.5-2023.5，主持。

[3] 北京科技大学研究生课程思政示范课程项目，2023SZA001，2023.3-2024.3，主持。

近年主持和参与的科研项目：

[1] 国家自然科学基金面上项目，受限条件下城市公路隧道通风与净化气流偶和机理和污染协同控制，2023.1-2026.12，主要参与者。

[2] 国家自然科学基金青年项目，无热桥整体式墙体材料的研制及其节能性预测，2018.1-2020.12，主持。

[3] 企业科技项目，油藏相变机制计算与测试技术服务，主持，2021。

[4] 企业科技项目，九江中冶环保资源开发有限公司全年钢渣和改性钢渣的理化指标检测，主要参与，2020。

[5] 国家重点研发计划重点专项，可再生能源和蓄能技术耦合应用关键技术研究，主要参与，2017.7-2021.7。

[6] 中央高校基本科研业务，建筑围护结构节能材料制备及其性能模拟，主持， 2019.1-2019.12。

[7] 中国博士后科学基金（科技类），新型一体式建筑节能墙体材料的研发及其热性能研究，主持，2017.1-2018.12。

[8] 中央高校基本科研业务，建筑节能中新型墙体材料及热性能的表征与模拟，主持，2016.1-2017.12。

授权发明专利：

[1] 一种利用陶瓷渣和单晶硅磨抛废料制备一体墙体板材的新方法，发明专利

[2] 一种用含钛高炉渣制备多孔材料的方法及含钛多孔材料，发明专利

[3] 一种用稀土尾矿制备多孔材料的方法，发明专利

近年代表性论文：

近年发表论文36篇SCI期刊论文，其中第一作者论文17篇和通讯作者论文8篇；包括32篇TOP期刊论文，单篇最高被引次数120多次。列举部分代表期刊论文：

[1] Ru Ji, Xiang Li. Numerical analysis on the energy performance of the PCMs-integrated thermochromic coating building envelopes[J]. Building and Environment, 2023,233:110113. (SCI) IF=7.093

[2] Ru Ji, Xiang Li, Cheng Lv. Synthesis and evaluation of phase change material suitable for energy-saving and carbon reduction of building envelopes[J]. Energy and Buildings, 2023,278:112603. (SCI) IF=7.201

[3] Ru Ji, Xiang Li, Cheng Lv, et al. Energy performance optimization of phase change materials considering the building micro‐environment[J]. International Journal of Energy Research, 2022：1-12. (SCI) IF=4.672

[4] Ru Ji, Guo S, Wei S. Evaluation of anchor bolt effects on the thermal performance of building insulation materials[J]. Journal of Building Engineering, 2020, 29: 101200. (SCI) IF=7.144

[5] Yio M H N , Xiao Y , Ji R , et al. Production of foamed glass-ceramics using furnace bottom ash and glass[J]. Ceramics International, 2020, 47(6). (SCI) IF=5.532

[6] Ru Ji, Zheng Y, Chen Z, et al. Development and energy evaluation of novel integrated envelopes without thermal bridges[J]. Energy and Buildings, 2019, 203: 109409. (SCI) IF=7.201

[7] Ru Ji, et al. Development and energy evaluation of phase change material composite for building energy‐saving[J]. International Journal of Energy Research, 2019, 43(14): 8674-8683. (SCI) IF=4.672

[8] Ru Ji, Zheng Y, et al. Climate applicability study of building envelopes containing phase change materials[J]. International Journal of Energy Research, 2019, 43(13): 7397-7408. (SCI) IF=4.672

[9] Ru Ji, Zheng Y, et al. Utilization of mineral wool waste and waste glass for synthesis of foam glass at low temperature[J]. Construction and Building Materials, 2019, 215: 623-632. (SCI) IF=7.693

[10] Ru Ji, Zou Z, Chen M, et al. Numerical assessing energy performance for building envelopes with phase change material[J]. International Journal of Energy Research, 2018. (SCI) IF=4.672

[11] Ru Ji, Wu S, Yan C, et al. Preparation and Characterization of the One-piece Wall Ceramic Board by Using Solid Wastes[J]. Ceramics International, 2017.12(43):8564-8571.(SCI) IF=5.532

[12] Ru Ji, Zhang Z, Yan C, et al. Preparation of novel ceramic tiles with high Al 2 O 3, content derived from coal fly ash[J]. Construction & Building Materials, 2016, 114:888-895.(SCI) IF=7.693

[13] Ru Ji, Zhang Z, He Y, et al. Simulating the effects of anchors on the thermal performance of building insulation systems[J]. Energy & Buildings, 2016.140:501-507.(SCI) IF=7.201

[14] Ru Ji, et al. Preparation and modeling of energy-saving building materials by using industrial solid waste. Energy and buildings, 2015. 15(97):6-12. (SCI) IF=7.201

[15] Ru Ji, Zuotai Zhang, Yang He, Lili Liu and Xidong Wang. Synthesis, characterization and modeling of new building insulation material using ceramic polishing waste residue. Construction and building materials,2015, 85,119-126. (SCI) IF=7.693

[16] Ru Ji, et al. Development of the random simulation model for estimating the effective thermal conductivity of insulation materials. Building and Environment, 2014. 80: 221-227. (SCI) IF=7.093

[17] Chen Z, Wang H, Ji R, et al. Reuse of mineral wool waste and recycled glass in ceramic foams[J]. Ceramics International, 2019, 45(12): 15057-15064. (SCI) IF=5.532

[18] Liu L, Lu G, Qiu G, Ru J, et al. Characterization of novel shape‐stabilized phase change material mortar: Portland cement containing Na2SO410H2O and fly ash for energy‐efficient building[J]. International Journal of Energy Research, 2019. (SCI) IF=4.672

[19] Wang S, Wang H, Chen Z, Ru J, et al. Fabrication and characterization of porous cordierite ceramics prepared from fly ash and natural minerals[J]. Ceramics International, 2019. (SCI) IF=5.532

[20] Hao Wang, Xidong Wang, Ru Ji. Integrated utilization of fly ash and waste glass for synthesis of foam/dense bi-layered insulation ceramic tile[J]. Energy & Buildings, 2018. (SCI) IF=7.201

[21] Hao Wang, Ziwei Chen, Xidong Wang, Ru Ji. Synthesis of a foam ceramic based on ceramic tile polishing waste using SiC as foaming agent[J]. Ceramics International, 2018. (SCI) IF=5.532

[22] Hao Wang, Ziwei Chen, Lili Liu, Xidong Wang, Ru Ji. Integrated utilization of high alumina fly ash for synthesis foam glass ceramic [J]. Ceramics International, 2018. (SCI) IF=5.532

[23] Hao Wang, Yongqi Sun, Ru Ji, Lili Liu, Xidong Wang. Synthesis of a ceramic tile base based on high-alumina fly ash [J]. Construction & Building Materials, 2017, 155:930-938. (SCI) IF=7.693

[24] Zhu M, Wang H, Liu L L, Ru Ji. Preparation and characterization of permeable bricks from gangue and tailings[J]. Construction & Building Materials, 2017, 148:484-491. (SCI) IF=7.693

[25] Zhu M, Ru Ji,et al. Preparation of glass ceramic foams for thermal insulation applications from coal fly ash and waste glass[J].Construction & Building Materials, 2016, 112:398-405. (SCI) IF=7.693