Ø 本科生课程:
《传热学》
《热工基础》
《强化传热技术及应用》(双语课)
Ø 研究生课程:
《强化传热原理与技术》
Ø 本科生课程:
《传热学》
《热工基础》
《强化传热技术及应用》(双语课)
Ø 研究生课程:
《强化传热原理与技术》
Ø 2018年-至今,ASME K-18 committee member
Ø 国家自然科学基金项目评审专家
Ø IWHT 2013、ISEST2018、PRES20会议秘书
Ø Session Co-Chair, 10th International Conference on Applied Energy, August 22-25, 2018, Hong Kong, China
Ø Session Co-Chair, 12th International Green Energy Conference, July 31-August 3, 2017, Xi’an, Shaanxi, China.
Ø Session Chair, 4th International Workshop on Heat Transfer, IWHT2017, April 2-5, 2017, Las Vegas, NV, USA
2017IWHT会议分会主席(USA,Las Vegas)
2016EMN会议(USA,Orlando)
2014ASME IMECE会议(Canada, Montreal)
近五年代表性论文:
[1] Liao Xinzhong, Liu Yuxuan, Ren Jiahang, Guan Liuping, Sang Xuehao, Wang Bowen, Zhang Hang, Wang Qiuwang, Ma Ting*. Investigation of a double-PCM-based thermoelectric energy-harvesting device using temperature fluctuations in an ambient environment. Energy, 2020, 202:117724.
[2] Xu Zirui, Li Xinyi, Zhu Ziliang, Wang Qiuwang, Chen Yitung, Ma Ting*. Experimental study on the heat transfer performance of a gallium heat sink. Energy Conversion and Management, 2020, 213:112853.
[3] Ma Ting, Zhang Pan, Shi Haoning, Chen Yitung, Wang Qiuwang*. Prediction of flow maldistribution in printed circuit heat exchanger. International Journal of Heat and Mass Transfer, 2020, 152:119560.
[4] Chu Wenxiao, Li Xionghui, Chen Yitung, Wang Qiuwang, Ma Ting*. Experimental study on small scale printed circuit heat exchanger with zigzag channels. Heat Transfer Engineering, DOI: 10.1080/01457632.2020.1735779, 2020.
[5] Xu Zirui, Li Xinyi, Niu Cong, Wang Qiuwang, Ma Ting*. Enhancement of gallium phase-change heat transfer by copper foam and ultrasonic vibration. Journal of Enhanced Heat Transfer, 2020, 27(1):71-84.
[6] Wang Luxin#, Lu Xing#, Yu Xingfei, Wang Qiuwang, Zhao Dongliang, Ren Wei, Ma Ting*. Effect of operating temperature on interface diffusion and power generation of bismuth telluride thermoelectric modules. Heat Transfer Research, 2020, 51: 253-262.
[7] Lu Xing, Yu Xingfei, Wang Qiuwang, Chen Yitung, Ma Ting*. Numerical study on nonuniform segmented enhancement method for thermoelectric power generator. Numerical Heat Transfer Part A-Applications, 2019, 76(8): 605-627.
[8] Borjigin Saranmanduh, Zhang Shuxiong, Zeng Min, Wang Qiuwang, Ma Ting*. Coupling epsilon-NTU method for thermal design of heat exchanger in cabinet cooling system. Applied Thermal Engineering, 159: UNSP 113972, 2019
[9] Deng Tianrui, Li Xionghui, Wang Qiuwang, Ma Ting*. Dynamic modelling and transient characteristics of supercritical CO2 recompression Brayton cycle. Energy, 2019, 180: 292-302.
[10] Ma Ting, Qu Zuoming, Yu Xingfei, Lu Xing, Chen Yitung, Wang Qiuwang*. Numerical study and optimization of thermoelectric-hydraulic performance of a novel thermoelectric generator integrated recuperator. Energy, 2019, 174: 1176-1187.
[11] Ma Ting, Qu Zuoming, Yu Xingfei, Lu Xing, Wang Qiuwang*. A review on thermoelectric-hydraulic performance and heat transfer enhancement technologies of thermoelectric power generator system. Thermal Science, 22(5): 1885-1903, 2018.
[12] Yu Xingfei, Lu Xing, Wang Qiuwang, Chen Yitung, Ma Ting*. Parametric study of thermoelectric power generators under large temperature difference conditions. Applied Thermal Engineering, 144: 647-657, 2018.
[13] Lu Xing, Yu Xingfei, Qu Zuoming, Wang Qiuwang, Ma Ting*. Experimental investigation on thermoelectric generator with non-uniform hot-side heat exchanger for waste heat recovery. Energy Conversion and Management, 150: 403-414, 2017.
[14] Ma Ting, Lu Xing, Pandit Jaideep, Ekkad Srinath V., Huxtable Scott T., Deshpande Samruddhi, Wang Qiu-Wang*. Numerical study on thermoelectric-hydraulic performance of a thermoelectric power generator with a plate-fin heat exchanger with longitudinal vortex generators. Applied Energy, 185: 1343-1354, 2017.
[15] Ma Ting, Chu Wen-xiao, Xu Xiang-yang, Chen Yi-tung, Wang Qiu-wang*. An experimental study on heat transfer between supercritical carbon dioxide and water near the pseudo-critical temperature in a double pipe heat exchanger. International Journal of Heat and Mass Transfer, 93: 379-387, 2016.
[16] Pasquier U., Chu W.X., Zeng M., Chen Y.T., Wang Q.W., Ma T.*. CFD simulation and optimization of fluid flow distribution inside printed circuit heat exchanger headers. Numerical Heat Transfer Part A-Applications, 69(7): 710-726, 2016.
[17] Ma Ting, Li Lei, Xu Xiang-Yang, Chen Yi-Tung, Wang Qiu-Wang*. Study on local thermal-hydraulic performance and optimization of zigzag-type printed circuit heat exchanger at high temperature. Energy Conversion and Management, 104: 55-66, 2015.
[18] Ma Ting, Xin Fei, Li Lei, Xu Xiang-yang, Chen Yi-tung, Wang Qiu-wang*. Effect of fin-endwall fillet on thermal hydraulic performance of airfoil printed circuit heat exchanger. Applied Thermal Engineering, 89: 1087-1095, 2015.
[19] Ma Ting*, Pandit Jaideep, Ekkad Srinath V., Huxtable Scott T., Wang Qiuwang. Simulation of thermoelectric-hydraulic performance of a thermoelectric power generator with longitudinal vortex generators. Energy, 84: 695-703, 2015.
[20] Ma Ting, Yan Min, Zeng Min, Yuan Jin-liang, Chen Qiu-yang, Sunden Bengt, Wang Qiu-wang*. Parameter study of transient carbon deposition effect on the performance of a planar solid oxide fuel cell. Applied Energy, 152: 217-228, 2015.
[21] Ma Ting, Zhang Jie, Borjigin Saranmanduh, Chen Yi-Tung, Wang Qiu-Wang, Zeng Min*. Numerical study on small-scale longitudinal heat conduction in cross-wavy primary surface heat exchanger. Applied Thermal Engineering, 76: 272-282, 2015.
[22] Xu X.Y., Wang Q.W., Li L., Ekkad S.V., Ma T.*. Thermal-hydraulic performance of different discontinuous fins used in a printed circuit heat exchanger for supercritical CO2. Numerical Heat Transfer Part A-Applications, 68(10): 1067-1086, 2015.
[23] Xu X.Y., Wang Q.W., Li L., Chen Y.T., Ma T.*. Study on thermal resistance distribution and local heat transfer enhancement method for SCO2-water heat exchange process near pseudo-critical temperature. International Journal of Heat and Mass Transfer, 82: 179-188, 2015.
近五年代表性专利:
[1] 马挺,关柳萍,任佳航,刘宇轩,廖新忠,桑学昊,王博文,王秋旺. 一种温度控制式复合相变材料温差发电系统. 中国发明专利, 专利号: ZL 201910489573.8(授权日期:2020-7-14)
[2] 马挺,萨仁满都呼,王秋旺,曾敏,常宏亮,张术雄. 一种气气换热系统. 中国发明专利, 专利号: ZL 201910489572.3(授权日期:2020-7-14)
[3] 马挺,俞兴飞,李娜,王秋旺. 一种模块化喷雾冷却器. 中国发明专利, 专利号: ZL 201910040978.3 (授权日期:2020-7-28)
[4] 王秋旺,李雄辉,马挺,曾敏,褚雯霄. 一种螺旋推流通道板式换热器. 中国发明专利, 专利号: ZL 201711209065.7(授权日期:2019-8-23)
[5] 王秋旺,萨仁满都呼,马挺,曾敏. 一种换热器系统热力设计方法. 中国发明专利, 专利号: ZL 201710047745.7(授权日期:2019-8-23)
[6] 王秋旺,石昊宁,马挺. 一种多通道板式换热器进出口设计方法. 中国发明专利, 专利号: ZL 201710839087.5 (授权日期:2019-04-12)
[7] 王秋旺,辛菲,马挺,李雄辉,邓天瑞. 喷淋蚀刻系统. 中国发明专利, 专利号: ZL 201711153828.0 (授权日期:2019-04-02)
[8] 马挺, 屈佐明, 芦星, 王秋旺. 一种板翅式热发电换热器. 中国发明专利, 专利号: ZL 201610986596.6 (授权日期:2019-3-1)
[9] 王秋旺,张攀,马挺. 一种气气高温换热器. 中国发明专利, 申请号: ZL 201710615447.3 (授权日期:2018-12-14)
[10] 王秋旺, 褚雯霄, 马挺, 曾敏. 一种非均匀分布肋片的高温高压板式换热器. 中国发明专利, 专利号: ZL 201510941222.8. (授权日期:2017-10-20)