臺灣博碩士論文加值系統

近二十年來，由於密集農業的快速發展，化學肥料過量施用，造成氮化合物積存於自然環
境中。其中有一部份以硝酸氮(NO3-N)形態溶入地面水及地下水中，並進而影響飲用水品質
，造成飲水衛生上的警訊。本研究建立起一小型表面流人工溼地系統(microcosm)與一試驗
規模(pilot-scale)人工溼地系統，以探討(1)種植不同植物之溼地組與對照組的NO3-N處理
效能以及季節變化對NO3-N處理效能的影響，並藉由監測溼地底泥之各種特性，以探討小型
溼地的NO3-N去除與底泥特性的關係；(2)表面流動式溼地(FWS)和表面下流動式溼地(SSF)
的NO3-N處理效能與其出流水質特性，以及操作不同水力負荷對NO3-N處理效能的影響與動
力學之表現。
小型表面流人工溼地系統(每個溼地為長0.6 m、寬0.4 m、高0.45 m)以連續入流方式，水
力負荷控制為0.035 m d-1，入流NO3-N與PO4-P目標濃度分別為為20 mg N L-1與5 mg P L-
1之合成水。各溼地組分別種植水芙蓉、蘆葦、空心菜、水蠟燭、狼尾草，對照組分別為加
上誘l以阻絕陽光之加遜儱茞梬P不加遜儱茞捸C除了水質的監測，為了了解溼地底泥的
特性與水質的關係，本研究並監測溼地底泥之脫硝潛能、有機物含量、碳含量、pH、與氧
化還原電位，以及底泥的氮含量與植物對於氮的攝取量。經由近兩年之實驗結果顯示，小
型表面流人工溼地系統NO3-N之入流濃度為21.05±6.49 mg N L-1，種植植物(分別為水芙
蓉、蘆葦、空心菜、水蠟燭、狼尾草)溼地組的NO3-N去除效能(72-98%)比無種植植物之對
照組優越(1-33%)，溼地組NO3-N去除效能受季節變化的影響也不如對照組明顯。而各組底
泥之NO3-N去除速率與脫硝潛能的大小呈正相關，而脫硝潛能與底泥底泥之STOC含量具明顯
之線性正比例關係，脫硝潛能與底泥之ORP與pH值呈現負相關。以上結果顯示，能提供較還
原態條件及較多的有機物作為脫硝碳源的溼地，可表現較高的NO3-N去除能力，而溼地中的
植物對提供此脫硝環境是有助益的。另外，由氮質量平衡結果估算種植植物之溼地的底泥
氮累積速率為0~0.163 g TN m-2 d-1，約佔溼地總氮去除的0~26.6%，而植物對於總氮的攝
取速率為0.004~0.126 g TN m-2 d-1，佔該組溼地總氮去除量的0.8~26.8%。此結果顯示脫
硝作用對於整個溼地的NO3-N去除相當重要。
試驗規模人工溼地系統分別入流含NO3-N之地下水(目標濃度為20 mg N L-1)於FWS與SSF溼
地(每座均為長5m、寬1m、高0.8m)，並調整不同水力負荷(範圍0.02-0.27 m d-1)，以及觀
察溼地中植物的生長與底泥氮含量。經由一年之實驗結果顯示，當試驗規模人工溼地系統
開始操作之後，SSF溼地的啟動適應期比FWS溼地短，並且在出流水有機物濃度及TSS濃度等
表現均較FWS溼地低。當水力負荷不斷提升之後，FWS與SSF溼地的NO3-N去除速率也隨之升
高，並於水力負荷控制為0.12 m d-1時達到最高(FWS與SSF分別為1.288與1.372 g N m-2
d-1)，隨後水力負荷調整為0.25 m d-1時，FWS與SSF溼地的NO3-N去除速率反而下降。以零
與一階柱塞流動力學模式描述NO3-N在人工溼地中的去除行為，結果發現一階柱塞流動力學
模式與實驗結果的契合度較高，FWS 溼地一階面積去除速率常數(k1)介於0.018-0.093 m
d-1，SSF溼地介於0.027-0.135 m d-1。另外，於監測期間FWS溼地底泥的總氮含量並無明
顯累積的趨勢(P=0.7211)，經由氮質量平衡估算發現，雖然植物的氮攝取對於溼地氮的去
除具有部分貢獻，然而脫硝作用仍佔了溼地氮去除相當大的比例，顯示脫硝作用為溼地去
除氮的主要機制。

Nitrate contamination of groundwater normally results from intensive use of
fertilizers in agriculture. Such contamination can lead to health problems via
drinking water contamination and is an environment concern in many areas. This
study set up seven microcosm wetlands with free water surface flow (FWS) and
tow pilot-scale wetlands (an FWS and a subsurface flow (SSF) type) to
investigate nitrate removal from groundwater in constructed wetland. The aims
of the study included: (1) determine nitrate removal of the microcosm
wetlands, effect of seasonal variation, and the relationship between nitrate
removal and sediment characteristic; (2) make a comparison of nitrate removal
between FWS and SSF wetlands, and investigate their kinetic behaviors under
various hydraulic loading rates.
In the seven microcosm wetlands (each measured 0.6 m×0.4 m×0.45 m), five
were planted with various native machrophytes (Pistia stratiotes, Phragmites
australis, Ipomoea aquatica, Typha orientalis, and Pennisetum purpureum),
whereas the others were unplanted (one with black plastic cover and another
without cover). A simulated nitrate-contaminated groundwater containing around
20 mg N/l of nitrate and 3 mg P/l of phosphate were continuously fed into the
microcosm wetlands at a hydraulic retention time (HRT) of around 4 d. Besides
water sampling and analysis, the characteristics of wetland sediments
including denitrification activity, organic matter content, carbon content,
pH, and oxidation-reduction potential (ORP) were measured. Throughout two
years continuous operation, the influent-effluent data showed that planted
wetlands reduced influent nitrate (21.05±6.49 mg N L-1) averagely by 72~98%.
These nitrate removals were all significantly higher than those in two
unplanted wetlands, in which the covered wetland was 1% and uncovered one was
33%. Seasonal effect on nitrate removal was more obvious in planted wetlands
than unplanted wetlands. Additionally, the denitrification activities of
sediment in planted wetlands (6.3~13.1 ug N/g/h) were also significantly
higher than those in unplanted wetland (1.8~11.2 ug/g/h). Nitrate removal rate
of microcosm increased proportionally with the increase of sediment
denitrification activity; also, the denitrification activity increased with
the increase of organic matter or carbon content of sediments. Furthermore,
sediment denitrification activity correlated conversely to the sediment ORP
and pH measured in situ. These results suggest that microcosms providing more
reduced condition and greater organic carbon available for denitrification can
perform higher nitrate removal ability. The presence of wetland macrophyte was
advantageous to create denitrification conditions and support nitrate removal.
The results of nitrogen balance in planted wetlands showed that nitrogen
accumulation in sediment and nitrogen uptake by harvested plant accounted for
0~0.163 and 0.004~0.126 g TN m-2 d-1, respectively, which represented 0~26.6%
and 0.8~26.8% of overall nitrogen removal. This implies that denitrification
is the most essential part of nitrogen removal in wetlands.
In pilot-scale wetlands study, FWS and SSF wetlands (each measured 5m××1m×0.
8m) received a simulating nitrate contaminated groundwater at a target
concentration of 20 mg NO3-N L-1 under various hydraulic loading rates ranged
from 0.02 to 0.27 m d-1. SSF wetland seemed to need shorter period to achieve
stable performance than FWS wetland; also, the levels of total organic carbon (
TOC) and total suspended solid (TSS) in SSF wetland effluent were significantly
higher than FWS wetland effluent. Nitrate removal rates of both wetlands
increased with increasing hydraulic loading rate until a plateau was reached;
the maximum removal rates, occurred at hydraulic loading rate of 0.12 m d-1,
were 1.288 and 1.372 g N m-2 d-1 for FWS and SSF wetland, respectively.　
Afterward, removal rate decreased when hydraulic loading rate increased to 0.
25 m d-1. First-order nitrate removal kinetic was found to be more sufficient
for fitting concentration decrease profile than zero-order kinetic. Removal
rate constant values were higher for the SSF wetland (0.027-0.135 m d-1) than
the FWS wetland (0.018-0.093 m d-1), probably because SSF wetland provided
more surface area for attached growth of denitrifying bacteria than the FWS
wetland. Nitrogen accumulation in FWS sediment was insignificant (P=0.7211).
Nitrogen uptake by plant growth accounted for up to 12.5 and 9.2 % of total
nitrogen removal in FWS and SSF wetland, respectively. Denitrification was
still the major contribution for nitrate removal in the pilot-scale wetlands
study.

中文摘要.................................................I
英文摘要.................................................III
目錄.....................................................VI
表目錄...................................................IX
圖目錄...................................................X
第一章前言
1.1水體的NO3-N污染.......................................1
1.2研究目的..............................................2
1.3研究架構..............................................3
第二章文獻回顧
2.1去除水中NO3-N技術的國內外發展.........................5
　 2.1.1國外技術發展.....................................5
　 2.1.2國內技術發展.....................................6
　 2.1.3本研究所採行的技術...............................7
2.2溼地的定義及分類......................................7
2.3人工溼地的發展沿革與類型..............................9
2.4人工溼地應用於水體NO3-N污染整治之發展.................14
2.5溼地中的氮循環........................................19
　 2.5.1含氮化合物的種類.................................19
　 2.5.2循環途徑.........................................21
2.6溼地中NO3-N的去除機制.................................26
2.7人工溼地去除NO3-N的模式推導...........................29
　 2.7.1柱塞流反應槽的物質傳輸模式.......................29
　 2.7.2零階柱塞流動力學模式.............................30
　 2.7.3一階柱塞流動力學模式.............................32
　 2.7.4溫度變化對去除速率常數的影響.....................34
2.8人工溼地中影響NO3-N去除的因子.........................34
　 2.8.1植物與碳源.......................................34
　 2.8.2NO3-N濃度........................................40
　 2.8.3溫度.............................................42
　 2.8.4溶氧濃度.........................................43
　 2.8.5底泥pH值.........................................44
　 2.8.6水力操作條件.....................................44
　 2.8.7溼地的類型.......................................47
2.9溼地脫硝速率的測量....................................48
第三章實驗設備與研究方法
3.1人工溼地系統的配置與操作..............................52
　 3.1.1小型表面流人工溼地系統...........................52
　 3.1.2試驗規模人工溼地系統.............................52
3.2水樣採集與水質監測分析................................57
　 3.2.1小型表面流人工溼地系統...........................57
　 3.2.2試驗規模人工溼地系統.............................57
　 3.2.3監測與分析方法...................................59
3.3植物的採收與分析......................................59
3.4處理效能的評估........................................62
3.5溼地底泥的採集與分析..................................63
　 3.5.1溼地底泥採樣.....................................63
　 3.5.2溼地底泥pH、ORP的監測............................64
　 3.5.3溼地底泥脫硝的潛能測量...........................64
　 3.5.4溼地底泥溶解性有機碳(STOC)分析...................66
　 3.5.5溼地底泥總碳(TC)與總氮(TN)分析...................67
　 3.5.6溼地底泥有機物分析...............................67
第四章結果與討論
4.1小型表面流人工溼地系統................................69
　 4.1.1處理效能.........................................69
　 4.1.2溫度變化NO3-N處理效能之影響......................78
　 4.1.3底泥性質與NO3-N去除的關係........................84
　 4.1.4底泥中氮的累積...................................98
　 4.1.5植物的採收及氮的攝取.............................98
4.2試驗規模人工溼地系統..................................104
　 4.2.1 FWS與SSF溼地啟動期之表現........................104
　 4.2.2 FWS與SSF溼地NO3-N處理效能與出流水質特性.........108
　 4.2.3不同水力負荷對溼地處理NO3-N的影響................112
　 4.2.4 溼地中NO3-N的去除動力學探討.....................121
　 4.2.5底泥中氮的累積...................................135
　 4.2.6植物對氮的攝取...................................135
　 4.2.7溼地中氮質量平衡估算.............................142
第五章結論...............................................150
第六章參考文獻...........................................152

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