农业工程学报
農業工程學報
농업공정학보
2013年
6期
209-213
,共5页
张兰河%孙立娇%仇天雷%韩梅琳%王旭明
張蘭河%孫立嬌%仇天雷%韓梅琳%王旭明
장란하%손립교%구천뢰%한매림%왕욱명
硝化%温度%模型%固体碳源%响应曲面法%硝酸盐
硝化%溫度%模型%固體碳源%響應麯麵法%硝痠鹽
초화%온도%모형%고체탄원%향응곡면법%초산염
nitrification%temperature%models%solid carbon source%response surface methodology%nitrate
为了预测固相反硝化反应器出水的硝酸盐浓度,优化工艺参数,以聚羟基丁酸戊酸共聚酯[Poly (3-Hydroxybutyrate-co-3-Hydroxyvalerate),PHBV]作为反应器的碳源和生物膜载体,对受硝酸盐污染的水进行生物反硝化脱氮.采用Box-Behnken试验设计,利用响应曲面法研究了反应器出水硝态氮浓度与进水硝态氮浓度、水力停留时间(hydraulic retention time,HRT)和温度之间的关系,建立了以出水硝态氮浓度为响应值的二次多项式回归模型.该数学模型可以定量描述进水硝态氮浓度、HRT和温度对出水硝态氮浓度的影响,模型预测值与试验值能吻合较好.方差分析结果表明,进水硝态氮浓度、温度和HRT及其交互作用对响应值均具有显著性影响(P<0.05).
為瞭預測固相反硝化反應器齣水的硝痠鹽濃度,優化工藝參數,以聚羥基丁痠戊痠共聚酯[Poly (3-Hydroxybutyrate-co-3-Hydroxyvalerate),PHBV]作為反應器的碳源和生物膜載體,對受硝痠鹽汙染的水進行生物反硝化脫氮.採用Box-Behnken試驗設計,利用響應麯麵法研究瞭反應器齣水硝態氮濃度與進水硝態氮濃度、水力停留時間(hydraulic retention time,HRT)和溫度之間的關繫,建立瞭以齣水硝態氮濃度為響應值的二次多項式迴歸模型.該數學模型可以定量描述進水硝態氮濃度、HRT和溫度對齣水硝態氮濃度的影響,模型預測值與試驗值能吻閤較好.方差分析結果錶明,進水硝態氮濃度、溫度和HRT及其交互作用對響應值均具有顯著性影響(P<0.05).
위료예측고상반초화반응기출수적초산염농도,우화공예삼수,이취간기정산무산공취지[Poly (3-Hydroxybutyrate-co-3-Hydroxyvalerate),PHBV]작위반응기적탄원화생물막재체,대수초산염오염적수진행생물반초화탈담.채용Box-Behnken시험설계,이용향응곡면법연구료반응기출수초태담농도여진수초태담농도、수력정류시간(hydraulic retention time,HRT)화온도지간적관계,건립료이출수초태담농도위향응치적이차다항식회귀모형.해수학모형가이정량묘술진수초태담농도、HRT화온도대출수초태담농도적영향,모형예측치여시험치능문합교호.방차분석결과표명,진수초태담농도、온도화HRT급기교호작용대향응치균구유현저성영향(P<0.05).
Solid-phase denitrification (SPD) process is characterized by insoluble biodegradable polymers used as carbon sources. It is likely to avoid the risk of overdosing of liquid carbon sources in the conventional with the resultant deterioration of the effluent water quality. SPD process has been successfully applied on the treatment of groundwater and wastewater with a low ratio of carbon to nitrogen. This work was carried out in order to predict the nitrate concentration in the treated water and optimize the parameters using SPD process. A laboratory scale reactor was used, which was packed with the poly (3-Hydroxybutyrate-co-3-Hydroxyvalerate) (PHBV) granules as both carbon source and biofilm carrier for nitrate removal from the contaminated water. Based on Box-Behnken experimental design, the relationship among the effluent and influent nitrate-nitrogen concentrations, temperature and hydraulic retention time (HRT) was quantitatively investigated using response surface methodology. The calculated values of the equation were agreed well with the experimentally tested data, and their relative errors ranged from 1.5% to 19%. This equation can quantitatively describe the relationship among the effluent and influent nitrate-nitrogen concentrations, temperature and HRT. Influent nitrate-nitrogen concentration, HRT, temperature and their interaction had significant impacts on the response value by analysis of variance (P<0.05).