楊開[武漢大學土木建築工程學院教授]

楊開[武漢大學土木建築工程學院教授]

楊開,男,1959年生。武漢大學土木建築工程學院教授,博士研究生導師。

個人經歷

1977.01-1978.02 長江航運管理局通信總站,工人

1978.02-1982.01 武漢建築材料工業學院,給水排水工程專業本科生,工學學士學位

1998.09-2003.06 武漢大學,水文學及水資源專業(在職),博士學位

1982.01-1983.09 湖北省工業設備安裝公司,水工工段長

1983.09-1986.06 武漢工業大學,市政工程專業碩士研究生,工學碩士學位

1986.06-1989.12 武漢城市建設學院,環境工程系,助教/講師

1989.12-2000.08 武漢水利電力大學,建築工程學院,講師/副教授/教授

2000.08-- 武漢大學,土木建築工程學院,教授

主講課程

水質工程學I(本科),水質控制工程(碩士),水處理高級教程(博士)

成就介紹

現就職於武漢大學,任市政工程學科教授,博士生指導教師,湖北省市政給排水學會副主任委員,武漢市海綿城市建設專家委員會副主任。

2006年以來,主編普通高等教育“十一五”國家級規劃教材《城鎮水資源利用與保護工程》1部,“十二五”規劃教材《給排水科學與工程專業畢業設計基礎及實例》1部。獲得國家發明專利(接觸氧化過濾一體化生物反應器ZL200610018772.3,一種集成式接觸氧化/除磷脫氮-過濾分離生物反應器201510013637.9)2項。參與完成國家級科研項目3項(“十一五”國家科技支撐計畫項目、863計畫、國家重大水專項等子題或專題負責人),主持完成“十二五”科技支撐計畫2項(休閒旅遊類城郊型美麗鄉村建設綜合技術集成示範2015BAL01B02,宜居村鎮設施配置技術研究與示範2014BAL04B04)。負責完成多項湖北省農村安全飲水工程及污水處理工程。與武漢排水集團合作開展的“基於技術經濟性的污水提標工藝優選與最佳化”科研課題,已獲得中試規模的階段性成果,有望成為一種全新的城市污水廠提標改造技術路線與工藝,並得到廣泛套用。作為水領域專家,長期參與國家三峽庫區和丹江口庫區水環境治理項目投資決策諮詢,以及省內外地方污水處理工程項目建設決策諮詢工程,為國家和地方建設作出了積極的貢獻。近五年以第一或通訊作者身份發表高水平論文30餘篇。

研究經歷

1. 湖北省遠安縣河口鄉污水工程設計,2016,項目負責人。

2. 湖北省遠安縣花林寺鎮污水工程設計,2016,項目負責人。

3. 仙桃市防洪排澇規劃,2015,項目負責人。

4. 孝感市排水管網規劃,2014,項目負責人。

5. 休閒旅遊類城郊型美麗鄉村建設綜合技術集成示範,2015-2017,十二五科技支撐計畫課題,課題負責人,項目號:2015BAL01B02。

6. 宜居村鎮設施配置技術研究與示範,2014-2017,十二五科技計畫課題,課題負責人,項目號:2014BAL04B04。

7. 武漢市非常規水資源利用規劃,2013,項目負責人。

8. 武漢市黃陂區蔡店鄉姚家山抗日第一村基礎設施建設與改造,2015年,項目負責人。

9. 武漢市黃陂區蔡店鄉姚家山抗日第一村排水管網設計,2014年,項目負責人。

10. 中部小城鎮飲用水除氟除砷技術研究及設備開發,2006-2009, 國家十一五科技支撐計畫, 課題參與人;

11. 雨污聯合調控及強化處理技術研究與工程示範,2008,863計畫,課題主要參與人;

12. 武漢市木蘭山風景管理處輸配水工程設計,2011,項目負責人;

13. 武漢市黃陂區長軒嶺社區給水管網設計,2010,項目負責人;

14. 武漢市黃陂區農村學校飲水安全工程,2010,項目負責人;

15. 武漢市黃陂區王家河街農村安全飲水工程,2008-2010,項目負責人;

16. 武漢市黃陂區長軒嶺街農村安全飲水工程,2008-2010,項目負責人;

17. 武漢市黃陂區蔡店鄉農村安全飲水工程,2008-2010,項目負責人;

18. 武漢市黃陂區長集鎮農村安全飲水工程,2008-2010,項目負責人;

19. 黃陂前川城區排水管網工程規劃,2005-2006, 項目負責人。

發表論文

[1] Ji B, Wang H, Yang K. Nitrate and COD removal in an upflow biofilter under an aerobic atmosphere[J]. Bioresource Technology, 2014, 158: 156-160.

[2] Yang K, Ji B, Wang H, et al. Bio-augmentation as a tool for improving the modified sequencing batch biofilm reactor[J]. Journal of Bioscience and Bioengineering, 2014, 117(6): 763-768.

[3] Zhou J, Wang H, Yang K, et al. Optimization of operation conditions for preventing sludge bulking and enhancing the stability of aerobic granular sludge in sequencing batch reactors[J]. Water Science & Technology, 2014, 70(9): 1519.

[4] Ji B, Wei L, Chen D, et al. Domestic wastewater treatment in a novel sequencing batch biofilm filter[J]. Applied Microbiology and Biotechnology, 2015, 99(13): 5731-5738.

[5] Ji B, Yang K, Wang H, et al. Aerobic denitrification by Pseudomonas stutzeri C3 incapable of heterotrophic nitrification[J]. Bioprocess and Biosystems Engineering, 2015, 38(2): 407-409.

[6] Zhang H, Liu L, Chang Q, et al. Biosorption of Cr(VI) ions from aqueous solutions by a newly isolatedBosea sp. strain Zer-1 from soil samples of a refuse processing plant[J]. Canadian Journal of Microbiology, 2015, 61(6): 399-408.

[7] Zhang H, Wang H, Yang K, et al. Autotrophic denitrification with anaerobic Fe2+ oxidation by a novel Pseudomonassp. W1[J]. Water Science & Technology, 2015, 71(7): 1081.

[8] Zhang H, Wang H, Yang K, et al. Nitrate removal by a novel autotrophic denitrifier (Microbacterium sp.) using Fe(II) as electron donor[J]. Annals of Microbiology, 2015, 65(2): 1069-1078.

[9] Zhou J, Wang H, Yang K, et al. Nitrate removal by nitrate-dependent Fe(II) oxidation in an upflow denitrifying biofilm reactor[J]. Water Science & Technology, 2015, 72(3): 377.

[10] Zhou J, Chen D, Jiang Y, et al. Removal of color caused by dissolved organic matter from groundwater by electroflotation-filtration continuous flow reactor and optimization by response surface methodology[J]. Desalination and Water Treatment, 2014, 57(2): 754-764.

[11] Zhou J, Wang H, Yang K, et al. Autotrophic denitrification by nitrate-dependent Fe(II) oxidation in a continuous up-flow biofilter[J]. Bioprocess and Biosystems Engineering, 2016, 39(2): 277-284.

[12] Chen D, Yang K, Wang H, et al. Cr(vi) removal by combined redox reactions and adsorption using pectin-stabilized nanoscale zero-valent iron for simulated chromium contaminated water[J]. RSC Adv., 2015, 5(80): 65068-65073.

[13] Chen D, Gao B, Wang H, et al. Effective removal of high concentration of phosphate by starch-stabilized nanoscale zerovalent iron (SNZVI)[J]. Journal of the Taiwan Institute of Chemical Engineers, 2016, 61: 181-187.

[14] Chen D, Dai T, Wang H, et al. Nitrate removal by a combined bioelectrochemical and sulfur autotrophic denitrification (CBSAD) system at low temperatures[J]. Desalination and Water Treatment, 2015, 57(41): 19411-19417.

[15] Jiang Y, Shang Y, Yang K, et al. Phenol degradation by halophilic fungal isolate JS4 and evaluation of its tolerance of heavy metals[J]. Applied Microbiology and Biotechnology, 2016, 100(4): 1883-1890.

[16] Jiang Y, Shang Y, Zhou J, et al. Characterization and biodegradation potential of an aniline-degrading strain ofPseudomonas JA1 at low temperature[J]. Desalination and Water Treatment, 2016, 57(52): 25011-25017.

[17] Jiang Y, Wang H, Shang Y, et al. Simultaneous removal of aniline, nitrogen and phosphorus in aniline-containing wastewater treatment by using sequencing batch reactor[J]. Bioresource Technology, 2016, 207: 422-429.

[18] Jiang Y, Shang Y, Wang H, et al. Rapid formation and pollutant removal ability of aerobic granules in a sequencing batch airlift reactor at low temperature[J]. Environmental Technology, 2016, 37(23): 3078-3085.

[19] Zhang J, Yang T, Wang H, et al. Optimization of process variables by driedBacillus cereus for biosorption of nickel(II) using response surface method[J]. Desalination and Water Treatment, 2015, 57(34): 16096-16103.

[20] Zhang J, Yang K, Wang H, et al. Impact of microwave treatment on dewaterability of sludge during Fenton oxidation[J]. Desalination and Water Treatment, 2015, 57(31): 14424-14432.

[21] Yang K, Zhang J, Yang T, et al. Investigation of equilibrium and kinetics of Cr(VI) adsorption by dried Bacillus cereus using response surface methodology[J]. Water Science and Technology, 2016, 73(3): 617-627.

[22] Chen D, Xiao X, Yang K. Removal of phosphate and hexavalent chromium from aqueous solutions by engineered waste eggshell[J]. RSC Adv., 2016, 6(42): 35332-35339.

[23] Peiwen Yu, Yingwen Xue*, Fei Gao, Zhigang Liu, Xiaoru Cheng, Kai Yang. Phosphorus removal from aqueous solution by pre- or post-modified biochars derived from agricultural residues [J]. Water Air Soil Pollut, 2016, 227:370.

[24] Zhigang Liu, Yingwen Xue*, Fei Gao , Xiaoru Cheng , Kai Yang. Removal of ammonium from aqueous solutions using alkali-modified biochars [J]. Chemical Speciation & Bioavailability. 2016, Vol.28, No.1-4, 26-32.

[25] 魯青青,薛英文*,楊開,李江雲,鄒勇.小流量大高差單級加壓供水管道工程設計[J].給水排水. 2015.41(9):88-92.

[26] Fei Gao, Yingwen Xue*,Pinya Deng, Xiaoru Cheng, Kai yang. Removal of aqueous ammonium by biochars derived from agricultural residuals at different pyrolysis temperatures [J]. Chemical Speciation & Bioavailability, 2015. Vol.27, NO.02, 92 – 97.

[27] 薛英文,楊開,梅健.混凝沉澱法除氟影響因素試驗研究[J].武漢大學學報(工學版).2010,44(4):477-480.

[28] 薛英文,楊開,靳文浩.我國農村含氟飲用水現狀與處理技術建議[J].中國農村水利水電.2010,7:52-55.

[29] Kai Yang, Yingwen Xue, Jiaje He, Xiaojun Yang, Case study: reducing manganese (Mn++) level in surface water with natural manganese-coated sand in Sinopec Shanghai Ltd. Journal of water supply: Research and technology.2008,57(3):185-194.

[30] 薛英文,楊開,李白紅,李進,董文楚.中水微灌系統生物堵塞特性探討[J].中國農村水利水電.2007,7: 36-39.

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