劉廣青

人物經歷

2013.07-至今北京化工大學國際教育學院院長，北京化工大學生物質能源與環境工程研究中心執行主任，教授，博導

2008.11-2013.07 北京化工大學化學工程學院，副教授，北鍵捆紙京化工大學人事處副處長

2006.07-2008.11 北京化工大學化學工程學院，講師，碩士生導師，北京化工大學人才引進辦公蘭應嚷室主任助理

2005.03-2006.03 美國加州大學戴維斯分校聯合培養博士2001.09-2006.06 中國農業大學博士研究生

學術兼職

1. 工信部工業節能與綠色評價中心主任

2. 中國清潔爐灶聯盟常務副秘書長

3. 國際區域清潔爐灶測試與知識中心主任

研究方向

1. 生物質和有機廢棄物厭氧清潔能源轉化技術研究

2. 生物質與固體廢棄物熱解清潔能源轉化技術研究

3. 生物質及潔淨煤清潔爐灶設計開發及污染排放控制技術研究

4. 廢水及污泥處理處置技術研究

科研項目

1. 國家大氣重點專項，“居民高效清潔採暖爐具研發及其套用示範”。

2. “863”國家高技術研究發展計畫重點課題，“木質纖維原料高效預處理技術與工藝設備研究及示範）”。

3. 國家科技支撐計畫，“北方城市生活垃圾乾法厭氧消化及生物質燃氣利用技術及示範-大型居民區生活垃圾生物質燃氣製備與提純天然氣技術及示範”。

4. “863”國家高技術研究發展計畫重點課題，“生物質高效熱解轎危催化定向製備燃氣關鍵技術研究及工程示範”。

5. 國家科技支撐計畫，“北方城市生活垃圾乾法厭氧消化及生物質燃氣利用技術及示範茅乘膠求-餐廚廢棄物乾法發酵製備生物質燃氣及併網發電技術及套用”。

6. 國家自然科學基金青年基金，“基於高效沼氣發酵的高木質纖維素類廢棄物生化預處理結構解析和耦合強化機制研究”。

7. 工信部縱向課題，“化工行業節能與綠色評價中心建設”。

8. 科技部縱向課題，“雄牛兵敬中美清潔爐寒套旋灶戰略發展過程管理”。

9. 企業合作課題，“微波加熱生物質催化氣化關鍵技術開發研究”。

10. 企業合作課題，“生物質高效熱解催化定向製備清潔燃氣關鍵技術研究。

11. 聯合國基金會國際課題，“國際區域清潔爐灶測試與知識中心建設項目”。

12. 北京市優秀人才培養資助項目，“北京市餐廚垃圾沼氣能源化集成技術研究”。

13. 世界銀行國際項目，“中國清潔爐灶第二期平台建設項目”。

14. 聯合國基金會國際項目，察陵蜜“Support for the China Alliance for Clean Stoves”。

15. 世界銀行國際項目，“中國清潔爐灶發展策略研究分析”。

16. 聯合國基金會國際項目，“中美清潔爐灶測試標準研究”。

學術成就

Enhanced methane production of vinegar residue by response surface methodology (RSM) [J]. AMB Express, 2017, 7: 89(1-8). (SCI收錄)

2. Study on biomethane production and biodegradability of different leafy vegetables in anaerobic digestion [J]. AMB Express, 2017, 7: 27(1-9). (SCI收錄)

3. Effect of organic loading rate on anaerobic digestion of food waste under mesophilic and thermophilic conditions[J]. Energy & Fuels, 2017, 31 (3), 2976-2984. (SCI收錄)

4. Effect of lipase hydrolysis on biomethane production from swine slaughterhouse waste in China [J]. Energy & Fuels, 2016, 30(9): 7326-7330. (SCI收錄)

5. Inhalation exposure and risk of polycyclic aromatic hydrocarbons (PAHs) among the rural population adopting wood gasifier stoves compared to different fuel-stove users [J]. Atmospheric Environment, 2016, 147: 485-491. (SCI收錄)

6. Exposure and size distribution of nitrated and oxygenated polycyclic aromatic hydrocarbons among the population using different household fuels [J]. Environmental Pollution, 2016, 216: 935-942. (SCI收錄)

7. Bio-energy conversion performance, biodegradability, and kinetic analysis of different fruit residues during discontinuous anaerobic digestion [J]. Waste Management, 2016, 52: 295-301. (SCI收錄)

8. Influence of steam explosion pretreatment on the anaerobic digestion of vinegar residue [J]. Waste Management & Research, 2016, 34(7): 630-637. (SCI收錄)

9. Pollutant Emissions from Improved Coal- and Wood-Fuelled Cookstoves in Rural Households [J]. Environmental Science & Technology, 2015, 49: 6590-6598. (SCI收錄)

10. Flexible polyaniline / carbon nanotube nanocomposite film-based electronic gas sensors[J]. Sensors and actuators B-Chemical, 2017, 244: 47-53. (SCI收錄)

11. Microwave pyrolysis of textile dyeing sludge in a continuously operated auger reactor[J]. Fuel Processing Technology, 2017, 166: 174-185. (SCI收錄)

12. Microwave pyrolysis of textile dyeing sludge in a continuously operated auger reactor: Condensates and non-condensable gases[J]. Environmental Pollution, 2017, 228: 331-343. (SCI收錄)

13. Microwave pyrolysis of textile dyeing sludge in a continuously operated auger reactor: Char characterization and analysis[J]. Journal of Hazardous Materials, 2017, 334: 112-120. (SCI收錄)

14. Comparison of air pollutant emissions and household air quality in rural homes using improved wood and coal stoves[J]. Atmospheric Environment, 2017, 166: 215-223. (SCI收錄)

15. The impact of household cooking and heating with solid fuels on ambient PM2.5 in peri-urban Beijing [J]. Atmospheric Environment, 2017, 165: 62-72. (SCI收錄)

16. Effects of ammonia on anaerobic digestion of food waste: process performance and microbial community [J]. Energy & Fuels, 2016, 30(7): 5749-5757. (SCI收錄)

17. Effect of sodium salt on anaerobic digestion of kitchen Waste [J]. Water Science & Technology, 2016, 73(8): 1865-1871. (SCI收錄)

18. Phosphorous-nitrogen-codoped carbon materials derived from metal-organic frameworks as efficient electrocatalysts for oxygen reduction reactions [J]. European Journal of Inorganic Chemistry, 2016, 2100-2105. (SCI收錄)

19. Biochar from microwave pyrolysis of biomass: A review [J]. Biomass & Bioenergy, 2016, 94: 228-244. (SCI收錄)

20. Low-Cost Upgrading of Biomass Pyrolysis Vapors by Char Recycling in a Downstream Reactor [J]. Journal of Biobased Materials and Bioenergy, 2016, 10(2): 145-150. (SCI收錄)

21. Biochar applications and modern techniques for characterization [J]. Clean Technologies and Environmental Policy, 2016, 18: 1457-1473. (SCI收錄)

22. Catalytic pyrolysis of tar model compound with various bio-char catalysts to recycle char from biomass pyrolysis [J]. BioResources, 2016, 11(2): 3752-3768. (SCI收錄)

23. Improve the anaerobic biodegradability by copretreatment of thermal alkali and steam explosion of lignocellulosic waste [J]. BioMed Research International, 2016, 2006: 1-10. (SCI收錄)

24. Potential of black liquor of potassium hydroxide to pretreat corn stover for biomethane production [J]. BioResources, 2016, 11(2): 4550-4563. (SCI收錄)

25. Influence of Nickel Impregnation on Behavior and Kinetic Characteristics of Oak Pyrolysis [J]. Journal of Biobased Materials and Bioenergy, 2016, 10(2): 137-144. (SCI收錄)

26. Efficiencies and pollutant emissions from forced-draft biomass-pellet semi-gasifier stoves: Comparison of International and Chinese water boiling test protocols [J]. Energy for Sustainable Development, 2016, 32: 22–30. (SCI收錄)

27. Pretreatment of corn stover for methane production with the combination of potassium hydroxide and calcium hydroxide, Energy & Fuels, 2015, 29(9): 5841-5846. (SCI收錄)

28. Anaerobic digestion performance of vinegar residue in continuously stirred tank reactor [J]. Bioresource Technology, 2015, 186: 338-342. (SCI收錄)

29. Pretreatment of wheat straw with potassium hydroxide for increasing enzymatic and microbial degradability [J]. Bioresource Technology, 2015, 185: 150-157. (SCI收錄)

30. Enhancing methane production of corn stover through a novel way: sequent pretreatment of potassium hydroxide and steam explosion [J]. Bioresource Technology, 2015, 181: 345-350. (SCI收錄)

31. Improving the bioenergy production from wheat straw with alkaline pretreatment [J]. Biosystems Engineering, 2015, 140: 59-66. (SCI收錄)

32. A comparative study of enzymatic hydrolysis and thermal degradation of corn stover-understanding biomass pretreatment [J]. RSC Advances, 2015, 5: 36999-37005. (SCI收錄)

33. Thermophilic solid-state anaerobic digestion of alkaline-pretreated corn stover [J]. Energy & Fuels, 2014, 28(6): 3759-3765. (SCI收錄)

34. Anaerobic co-digestion of chicken manure and corn stover in batch and continuously stirred tank reactor (CSTR) [J]. Bioresource Technology, 2014, 156: 342-347. (SCI收錄)

35. Thermogravimetric analysis of lignocellulosic biomass with ionic liquid pretreatment [J]. Bioresource Technology, 2014, 153: 379-382. (SCI收錄)

36. Understanding changes in cellulose crystalline structure of lignocelluosic biomass during ionic liquid pretreatment by XRD [J]. Bioresource Technology, 2014, 151: 402-405. (SCI收錄)

37. Effects of moisture content in fuel on thermal performance and emission of biomass semi-gasified cookstove [J]. Energy for Sustainable Development, 2014, 21: 60-65. (SCI收錄)

38. Biogas production from co-digestion of corn stover and chicken manure under anaerobic wet, hemi-solid, and solid state conditions [J]. Bioresource Technology, 2013, 149: 406-412. (SCI收錄)

39. Comparison of methane production potential, biodegradability, and kinetics of different organic substrates [J]. Bioresource Technology, 2013, 149: 565-569. (SCI收錄)

40. Influence of particle size and alkaline pretreatment on the anareobic digestion of corn stover [J]. BioResources, 2013, 8(4): 5850-5860. (SCI收錄)

41. Influence of inoculum source and pre-incubation on bio-methane potential of chicken manure and corn stover [J]. Applied Biochemistry and Biotechnology, 2013, 171(1): 117-127. (SCI收錄)

42. Biochemical methane potential (BMP) of vinegar residue and the influence of feed to inoculum ratios on biogas production [J]. BioResources, 2013, 8(2): 2487-2498. (SCI收錄)

43. Evaluating methane production from anaerobic mono- and co-digestion of kitchen waste, corn stover, and chicken manure [J]. Energy & Fuels, 2013, 27(4): 2085-2091. (SCI收錄)

獲獎情況

1. “2017年度中國電力創新獎” 一等獎（完成人之一）。

2. 中國爐具行業傑出貢獻獎，中國農村能源行業協會。

3. “基於高溫木炭床的污泥高效熱解研究”. 2015年第八屆全國大學生節能減排社會實踐與科技競賽三等獎（國家級）. 指導教師.

4. “汽爆預處理提升秸稈厭氧消化產能研究”. 2015年第八屆全國大學生節能減排社會實踐與科技競賽三等獎（國家級）. 指導教師.

5. “Clean Production of Biochar by Biomass Stoves”. 2014 International Student Contest on Environment and New Energy (ISCENE, 環境與新能源國際大學生競賽) ,一等獎（國際競賽）. 指導教師.

6. “基於計算流體力學模擬的新型生物質爐灶的設計與最佳化”. 2014年第五屆全國高校環保科技創意設計大賽銀獎（省部級二等獎）. 指導教師、最佳導師獎.

7. “新型生物質半氣化產炭爐的設計與最佳化”. 2014年第七屆全國大學生節能減排社會實踐與科技競賽二等獎（國家級）. 指導教師.

8. “中國生物質爐灶的節能減排與碳交易潛力研究”. 2009年第二屆全國大學生節能減排社會實踐與科技競賽一等獎（國家級）. 指導教師.

9. “基於碳交易補貼的生物質爐灶和燃料可持續推廣模式研究”. 2011年第二屆全國高校環保科技創意設計大賽銀獎. 指導教師.

論著專利

論著：

《Biomass Conversion Technology》，主編，科學出版社， 2015，北京．

參編《中國建築節能年度發展報告》，2012，北京．

《生物質能源轉化技術》，主編，化學工業出版社，2009，北京．

參編《固體廢物工程實驗》，化學工業出版社，2008，北京．

參編《有機固體廢棄物管理與資源化技術》,國防工業出版社，2006，北京．

專利：

1. 一種鹼聯合預處理、黑液循環利用的纖維素類生物質厭氧消化工藝. ZL201310027025.6.

2. 一種循環利用催化劑熱解氣化農林廢棄物的工藝. ZL201310101274.5.

3. 一種農作物秸稈與畜禽糞便聯合固態發酵生產沼氣的方法. ZL201310025678.0.

4. 一種生物質爐灶蒸汽減排裝置, ZL201410230539.6.

5. 一種果蔬垃圾厭氧消化生產沼氣的方法. ZL201210180850.5.

6. 一種兩相多級厭氧發酵有機固體廢棄物生產沼氣的方法. ZL200810104975.3.

7. 兩相厭氧循環水洗處理有機垃圾裝置. ZL200620023158.1.

8. 好氧加溫/厭氧發酵處理有機廢棄物裝置. ZL200620167412.5.

9. 一種同步實現有機廢棄物處理及合成氣提質的系統裝置, ZL201620223633

10. 一種用於氣體輸送及物料攪拌的一體化裝置及包括該裝置的生物反應器, ZL201620237901.7.

講授課程

《新能源國際交叉與前沿》

合作交流

與美國加州大學戴維斯分校、加拿大英屬哥倫比亞大學、美國喬治亞大學、紐約州立大學ESF分校、瑞典皇家理工學院、荷蘭代爾夫特大學、丹麥技術大學、希臘帕特雷大學等30餘所國外高校有密切合作關係。

劉廣青

基本介紹

人物經歷

學術兼職

研究方向

科研項目

學術成就

獲獎情況

論著專利

講授課程

合作交流

獲獎情況

論著專利

講授課程

合作交流

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