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Soil column study on five Hong Kong soils on purifying livestock slurry.January 1990 (has links)
by Ng Sai Leung. / Thesis (M.Phil.)--Chinese University of Hong Kong, 1990. / Bibliography: leaves [172]-[182] / ABSTRACT --- p.iii / ACKNOWLEDGEMENTS --- p.V / TABLE OF CONTENT --- p.vii / LIST OF FIGURES --- p.xii / LIST OF TABLES --- p.xiv / LIST OF PLATES --- p.xvii / LIST OF APPENDICES --- p.xviii / CHAPTER --- p.Page / Chapter I --- INTRODUCTION --- p.1 / Chapter 1.1 --- Background --- p.1 / Chapter 1.2 --- Objectives --- p.3 / Chapter 1.3 --- Significance --- p.3 / Chapter 1.4 --- Literature review --- p.5 / Chapter 1.5 --- Scope and approach of the study --- p.8 / Chapter II --- METHODOLOGY --- p.11 / Chapter 2.1 --- Conceptualization --- p.11 / Chapter 2.2 --- Soil characteristics / Chapter 2.2.1 --- Site selection --- p.12 / Chapter 2.2.2 --- Descriptions of soils for investigation --- p.15 / Chapter 2.3 --- Preliminary percolation test and soil preparation --- p.24 / Chapter 2.4 --- Column design --- p.25 / Chapter 2.5 --- Routine operation --- p.28 / Chapter 2.6 --- Sampling procedure --- p.29 / Chapter 2.7 --- Time schedule of the experiment --- p.30 / Chapter III --- ANALYTICAL METHODS --- p.31 / Chapter 3.1 --- Soil characteristics --- p.31 / Chapter 3.2 --- Soil leachate --- p.37 / Chapter 3.3 --- Continuous monitoring of the column system --- p.42 / Chapter 3.4 --- Manipulation and analysis of data --- p.43 / Chapter 3.5 --- Remarks --- p.44 / Chapter IV --- INITIAL STATE OF THE SYSTEM --- p.45 / Chapter 4.1 --- Slurry characteristics --- p.45 / Chapter 4.2 --- Soil matrix --- p.47 / Chapter 4.3 --- Blank soil leachate --- p.50 / Chapter 4.5 --- Summary --- p.51 / Chapter V --- HYDRAULIC PERFORMANCE OF THE COLUMNS --- p.53 / Chapter 5.1 --- Hydraulic considerations of disposal design --- p.53 / Chapter 5.1.1 --- Soil clogging phenomenon --- p.54 / Chapter 5.1.2 --- Significance of soil clogging --- p.55 / Chapter 5.2 --- Morphology of clogging layer --- p.55 / Chapter 5.3 --- Infiltration regimes of the columns --- p.59 / Chapter 5.3.1 --- Kostiakov infiltration model --- p.59 / Chapter 5.3.2 --- Factors affecting infiltration regimes --- p.63 / Chapter 5.4 --- Practical recommendations --- p.65 / Chapter 5.4.1 --- Recommended dosage rate --- p.65 / Chapter 5.4.2 --- Time of failure --- p.66 / Chapter 5.4.3 --- Recovery of the system --- p.67 / Chapter 5.5 --- Summary --- p.68 / Chapter VI --- PURIFICATION EFFICIENCY OF THE SYSTEM --- p.70 / Chapter 6.1 --- PH --- p.70 / Chapter 6.2 --- Specific conductivity --- p.71 / Chapter 6.2.1 --- Ion movement pattern --- p.74 / Chapter 6.2.2 --- Ion movement mechanism --- p.77 / Chapter 6.3 --- E. coli --- p.78 / Chapter 6.3.1 --- E. coli removal pattern --- p.81 / Chapter 6.3.2 --- E. coli overview --- p.82 / Chapter 6.4 --- Carbon --- p.83 / Chapter 6.4.1 --- Carbon attenuation pattern --- p.84 / Chapter 6.4.2 --- Carbon transformation mechanisms --- p.93 / Chapter 6.5 --- Nitrogen --- p.95 / Chapter 6.5.1 --- Nitrogen attenuation --- p.96 / Chapter 6.5.2 --- Nitrogen transformation mechanisms --- p.103 / Chapter 6.6 --- Phosphorus --- p.106 / Chapter 6.7 --- Summary --- p.112 / Chapter VII --- CHEMICAL QUALITY OF SOIL LEACHATE --- p.113 / Chapter 7.1 --- Cluster analysis of leachate samples --- p.114 / Chapter 7.1.1 --- Clustering of soil leachate --- p.115 / Chapter 7.1.2 --- Implications --- p.118 / Chapter 7.2 --- Discriminant analysis of leachate samples --- p.119 / Chapter 7.2.1 --- Discriminant functions --- p.119 / Chapter 7.2.2 --- Scanning the misclassified samples --- p.123 / Chapter 7.3 --- Spatial and temporal changes of soil leachate --- p.124 / Chapter 7.5 --- Summary --- p.127 / Chapter VIII --- CONTROLLING FACTORS OF THE LEACHATE QUALITY --- p.128 / Chapter 8.1 --- Interrelationship of leachate chemical quality --- p.130 / Chapter 8.2 --- Analytical framework --- p.133 / Chapter 8.3 --- Evaluating the effect of system characteristics --- p.135 / Chapter 8.3.1 --- "Effects on ""degradation""" --- p.137 / Chapter 8.3.2 --- "Effects on ""soil retention""" --- p.138 / Chapter 8.3.3 --- "Effects on ""nitrification""" --- p.138 / Chapter 8.3.4 --- Overall effect --- p.139 / Chapter 8.4 --- Pattern of pollutant attenuation --- p.140 / Chapter 8.5 --- Relative performance of five soils and the effect of depth --- p.142 / Chapter 8.5.1 --- Relative purification efficiency of each soil --- p.143 / Chapter 8.5.2 --- The effect of soil depth on purification --- p.144 / Chapter 8.6 --- Evaluating the effect of slurry concentration --- p.146 / Chapter 8.7 --- Evaluating the effect of management practices --- p.148 / Chapter 8.7.1 --- Gravel washing --- p.148 / Chapter 8.7.2 --- Raking --- p.150 / Chapter 8.8 --- Summary --- p.151 / Chapter IX --- CHANGES OF SOIL CHEMICAL PROPERTIES --- p.153 / Chapter 9.1 --- Soil reaction pH --- p.153 / Chapter 9.2 --- Soil electrical conductivity (SEC) --- p.156 / Chapter 9.3 --- Soil total organic carbon (TOC) --- p.158 / Chapter 9.4 --- Soil total nitrogen (TN) --- p.158 / Chapter 9.5 --- Soil total phosphorus (TP) --- p.162 / Chapter 9.6 --- Summary --- p.162 / Chapter X --- CONCLUSION --- p.165 / Chapter 10.1 --- General review of the performance of the columns --- p.165 / Chapter 10.2 --- Purification pathways and contaminant attenuation --- p.166 / Chapter 10.3 --- Factors affecting the purification --- p.167 / Chapter 10.4 --- Impacts of slurry application on the soil properties --- p.168 / Chapter 10.5 --- Practicability of soakaway and recommendations --- p.168 / Chapter 10.6 --- Suggestion and discussion --- p.169 / Chapter 10.6.1 --- Experimental design --- p.169 / Chapter 10.6.2 --- Operational improvement --- p.170 / Chapter 10.6.3 --- Statistical considerations --- p.171 / BIBLIOGRAPHY / APPENDICES
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A feasibility study of a CDM compliant small-scale biomass gasification electricity generation project at a Western Cape wine cellarSchumann, Dolf 12 1900 (has links)
Thesis (MBA)--Stellenbosch University, 2008. / ENGLISH ABSTRACT: The goal of this study was to investigate the feasibility of a small-scale biomass gasification system
within the context of a cooperative wine cellar operation in the Western Cape of South Africa.
Central to this goal was the questions whether the time for the implementation of such small-scale
renewable energy technologies in South Africa has arrived, in light of the status quo which has
changed drastically from the days of abundant and cheap coal-based electricity, and whether the
new opportunities afforded by the CDM can help foster financial feasibility.
There are various macro-drivers contributing to the current-day emphasis on renewable energy and
cogeneration projects. The first and most pressing driver is the global climate change imperative,
while the others include the increased aspiration of countries towards energy security, the
realization of the importance of sustainable development and the subsequent renewable energy
policies that falls within the ambit of sustainable development.
Small-scale biomass gasification technology still poses some challenges, particularly when it comes
to the gasification of agricultural residues, as with grape residues in the case of this project. The
most important technical feasibility problem to overcome is the low ash agglomeration temperature
of grape residues reported in the literature. Although the local equipment manufacturer foresees no
problem in this regard with their system design - since they have conducted tests on sunflower seed
residues, which have similar ash properties, without experiencing any agglomeration problems - the
seriousness of this aspect will be confirmed during pilot trials.
In order to be eligible for emissions reduction trading under the CDM, the project must adequately
demonstrate that the emissions reductions are additional to the business-as-usual scenario, in both
the environmental and financial sense. The project will satisfy the environmental additionality
requirement, since in its absence the wine cellar will continue its full reliance on coal-based
electricity from the grid. Financial additionality, in its strictest sense, requires for the project to be
infeasible if it does not pursue CDM participation, which the financial feasibility modeling results
indicated to be true in this case.
A feasibility model was developed to - subject to the input parameter values assumed and basic
assumptions made - be able to assess the financial viability of the project. The main assumptions
were that the private feed-in into the national electricity grid was available to all IPPs, in spite of the
fact that in its Medium Term Power Purchase Program me (MTPPP) of May 2008 Eskom had only
requested expressions of interest from IPPs that had a generating capacity of 5MW and higher to
install private base load capacity. This assumption is commensurate with the country's renewable
energy targets and the official government aim of achieving a 30% contribution from IPPs to the
national electricity mix.
The second assumption was that the 65 to lOOclkWh offered by Eskom in its MTPPP will be
applicable to sub-SMWe IPPs as well (Creamer, 2008), and that this lower bound electricity price of
65clkWh can be applied over the whole project lifetime. Inherent to this assumption is the further
supposition that the progressive decline of electricity prices to an eventual level of 35clkWh by
2018 foreseen by Eskom will not materialize, due both to the sustained pressure an expanding South
African economy will put on the considerable but time-consuming supply-side initiatives launched
by Eskom, and the likelihood for price premiums to be introduced for clean electricity in order to
meet the country's renewable energy targets.
From the assumed input parameter values the initial capital and COM expenditures, operating
revenues and costs over the project lifetime were determined, and then used to calculate the net cash
flows, where after the NPV was computed to serve as the deciding criterion on financial feasibility.
A discount rate of 18% was assumed, corresponding with the subjectively judged risks that the
project posed as a small-scale renewable energy system within the wine cellar operations.
In the case where the project excluded all CDM aspects, the NPV was negative at - ZAR342 573,
but this improved to ZAR325 193 if the project participated in the CDM. Thus it was concluded that
the project will only be financially feasible if it includes CDM participation, and that this positive
contribution can be leveraged by pursuing a programmatic CDM approach. This entails the
development of this project as part of a larger program in which similar projects are implemented as
they arise, up to the official UN limit of 15MWe in total to still qualify as a small-scale program.
The nature of the assumptions that form the backbone of this study indicate that the positive
financial feasibility result in the case where the project includes COM participation will become
practically relevant only over the short- to medium-term as these assumptions become reality in
South Africa. Therefore, although the time for such small-scale renewable energy projects has
clearly not arrived as yet, it would seem that it is indeed around the corner. / AFRIKAANSE OPSOMMING: Die mikpunt van die navorsing was om die lewensvatbaarheid van 'n klein-skaal biomassa
vergassing sisteem binne die konteks van 'n kooperatiewe wynkelder in die Wes-Kaap van Suid-Afrika
te ondersoek. 'n Sentrale aspek was die vrae of die tyd aangebreek het om klein-skaal
volhouhare energie projekte in Suid-Afrika tot uitvoering te bring, gesien in die lig van 'n status
quo wat drasties weg beweeg het van die tydperk toe elektrisiteit volop en goedkoop was, en of die
geleentheid wat die CDM bied sulke projekte finansieel lewensvatbaar kan maak.
Daar is verskeie eksterne makro-drywers wat bydrae tot die huidige fokus op sulke volhoubare
energie projekte. Hieronder tel globale klimaatsverandering as die dringendste drywer, terwyl die
res onder andere die hernuwe strewe van lande tot verbeterde energie-sekuriteit, die besef van die
belangrikheid van volhoubare ontwikkeling en die daaropvolgende volhoubare energie beleid
stappe insluit.
Daar bestaan nog etlike tegniese uitdagings tot die toepassing van klein-skaal biomassa vergassing
tegnologie, spesifiek met betrekking tot die vergassing van afval landbou byprodukte, soos wat die
geval is met druiwe afval in hierdie projek. Die belangrikste tegniese uitvoerbaarheids-aspek wat
aandag verg is die lae smeltpunt van druifafval-as wat in die literatuur rapporteer word. Alhoewel
die plaaslike toerustings-vervaardiger nie enige probleme in hierdie verhand voorsien nie, aangesien
toetse met sonneblom afval - met as-eienskappe rofweg identies aan die van druiwe-afval - geen
smelting van die as getoon het nie, sal dit tog nogsteeds aan verdere toetse onderwerp word.
Vir die projek om te kwalifiseer as geskik vir verhandeling in kweekhuisgas vermindering deur
middel van die COM, moet dit voldoende bewys kan word dat alle uitlaatgas vermindering
addisioneel is tot wat die geval sou wees in die gewone gang van besigheid. Hierdie addisionaliteit
is relevant in beide 'n omgewings- en finansiele sin. Hierdie projek sal orngewings-addisionaliteit
bevredig deurdat die wynkelder in sy afwesigheid volkome afhanklik van die steenkool-gebaseerde
elektrisiteit vanaf die nasionale netwerk sou bly, terwyl finansiele addisionaliteit bewys is deur die
finansiele lewensvatbaarheids-model wat getoon het dat die projek slegs ekonomies uitvoerbaar sal
wees indien dit CDM deelname insluit.
Die lewensvatbaarheids-model is ontwikkel om die ekonomiese uitvoerbaarheid van die projek te
evalueer, onderworpe aan die aangenome inset parameter waardes en basiese aannames in die
studie. Die hoof-aanname was naamlik dat privaat terugvoer in die nasionale elektrisiteits-netwerk
vir alle grootte IPPs moontlik is, ten spyte van die feit dat Eskom se MTPPP van Mei 2008 slegs
kapasiteite van 5MW en groter aanvaar bet. Hierdie aanname is gebaseer op Suid-Afrika se
volhoubare energie teikens en die regering se offisiele mikpunt om 30% van alle krag-voorsiening
vanaf IPPs te bekom.
Die tweede hoof-aanname was dat die 65 tot 100clkWh wat Eskom in sy MTPPP aangebied het,
ook van toepassing sal wees op sub-SMW IPPs (Creamer, 2008), en dat die laer prys-limiet van
65c/kWb oor die hele projek-leeftyd toegepas kon word. Inherent tot hierdie aanname is die verdere
veronderstelling dat die progressiewe daling in elektrisiteits-pryse tot 'n eventuele vlak van
35clkWh voorsien deur Eskom nie sal realiseer nie, beide as gevolg van die volgehoue druk wat die
groeiende Suid-Afrikaanse ekonomie op die aansieniike, maar tydrowende, opwekkings-kapasiteit
uitbreidings van Eskom behoort te plaas, en ook die hoe waarskynlikheid dat prys premiums vir
skoon elektrisiteit ingestel word sodat Suid-Afrika sy volboubare energie telkens kan bereik.
Die aanvanklike kapitaal en CDM uitgawes, en bedryfsuitgawes en - inkomstes oor die projekleeftyd
is vanaf die aangenome inset parameter waardes afgelei, waarop die NPV van die projek
uitgewerk is om te dien as die beslissende maatstaf van ekonomiese haalbaarheid. 'n Diskontokoers
van 18% is gebruik, ooreenstemmend met die subjektief beraamde risikos wat die projek
inhou as 'n klein-skaal volhoubare energie sisteem.
Die resultate van die finansiele lewensvatbaarheids-model het getoon dat in die geval waar die
projek geen CDM aspekte bevat nie, die NPV hoogs negatief sou wees met 'n waarde van
-ZAR342 573, terwyl dit verbeter na ZAR325 193 as die projek CDM deelname insluit. Die
gevolgtrekking is dus gemaak dat die spesifieke projek slegs ekonomies haalbaar sal wees indien dit
wel CDM deelname insluit, en dat hierdie positiewe finansiele bydrae van die CDM geoptimaliseer
kan word deur 'n programmatiese CDM benadering te volg. Dit behels die ontwikkeling van die
projek as deel van 'n groter program waarin soortgelyke projekte mettertyd geimplementeer word
soos hulle ontstaan, tot by die offisiele VN limiet van 15MWe om sodoende nog te kwalifiseer as 'n
algehele klein-skaalse program.
Die aard van die hoof-aannames in hierdie studie is indikatief dat die positiewe finansiele
lewensvatbaarheid in die geval waar die projek CDM deelname insluit, eers oor die kort- tot
medium-termyn prakties relevant sal word soos die aannames bevredig word. Dus, alhoewel die era
van klein-skaalse volhoubare energie projekte nog nie aangebreek het in Suid-Afrika nie, lyk dit tog
asof dit om die draai is.
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Tertiary biovalorisation of Grape pomaceAngadam, Justine Oma January 2018 (has links)
Thesis (Masters of Environmental Health)--Cape Peninsula University of Technology, 2018. / In the Western Cape, South Africa and other regions globally, grape pomace (GP) is one of the abundant agro-waste from the winery industry. This study reports on the hyper-extraction of fermentable sugars from GP treated with white rot fungi (WRF) Phanerochaete chrysosporium BKMF 1767 to facilitate improved biovalorisation for total reducing sugars (TRS) extraction in conjunction with Nepenthes mirabilis digestive fluids. TRS were quantified using the 3,5-dinitrosalicylic acid (DNS) reagent method. The free readily dissolvable sugars from the GP recorded for the bio-treated (BT) samples was 206.39 ± 0.06 mg/L and for the untreated (UT) samples was 271.05 ± 0.02 mg/L. Overall, the TRS yield for the Bio-treated (BT) and untreated (UT) samples was recorded as 205.68 ± 0.09 and 380.93 ± 0.14 mg/L, respectively, using hot water pretreatment (HWP) with 2266.00 ± 0.73 (BT) and 2850.68 ± 0.31 mg/L (UT), respectively, for dilute acid pretreatment (DAP); with 2068.49 ± 6.02 (BT) and 2969.61 ± 8.054 mg/L (UT) respectively, using the cellulase pretreatment (CP) method. Using the HWP as a reference, the relative increases imparted by the biotreatment was higher (51%) for DAP and low (33%) for CP. The combination of conventional used pre-treatment methods (hot water pretreatment, dilute acid pre-treatment, and cellulase pre-treatment) in a single pot system was also done while monitoring the total residual phenolics (TRPCs) in the samples. Furthermore, powder X-ray diffraction (pXRD) were used to measure the crystallinity index (CrI) and functional groups of pre- and post-pretreated GP to ascertain the efficiency of the pre-treatment methods, with quantification of lignin, holocellulose, and ash. Overall, the TRS yield for N. mirabilis pre-treated agro-waste was 951 mg/L ± 4.666 mg/L, with biomass having a lower CrI of 33%, and 62% residual lignin content. Furthermore, reduced TRPCs were observed in hydrolysate, suggesting limited inhibitory by-product formation during N. mirabilis pre-treatment
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Crop residue gasificationDybing, Kyle Dean. January 1984 (has links)
Call number: LD2668 .T4 1984 D93 / Master of Science
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Carburetion system for biomass gas fueling of spark ignition enginesGoodman, Mark A. January 1984 (has links)
Call number: LD2668 .T4 1984 G666 / Master of Science
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Beef and swine digester gasses: evauluation [sic] as fuels for spark ignition enginesMarr, Jerry Dwight. January 1984 (has links)
Call number: LD2668 .T4 1984 M37 / Master of Science
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The production of granular activated carbon from agricultural waste productsVan Dyk, Lizelle Doreen 12 1900 (has links)
Thesis (MEng)--University of Stellenbosch, 2000. / ENGLISH ABSTRACT: Peach and apricot shells are agricultural waste products. These waste products
accumulate around canneries and food-processing plants in South Africa. No effort is
being made to utilise these waste products. This study is the first part of the product
development from these products i.e. peach shell activated carbon and apricot shell
activated carbon. By producing activated carbon from peach and apricot shells the
solid waste problem is addressed, but most of all a profit can be made.
But why activated carbon? Activated carbons are unique and versatile adsorbent with
a vast amount of adsorption applications. It can be produced via a simple oxidation
reaction with steam and the nature of peach and apricot shells are such that it is
expected that activated carbons with good adsorption properties can be produced from
it. The single largest consumer of activated carbon in South Africa is the gold mining
industry that uses imported coconut shell activated carbon for gold adsorption in the
gold recovery process. Activated carbon is also used as water purification adsorbents.
During this study activated carbons were produced in a fluidized bed reactor at
various activation conditions: 700 - 900°C, 0.0425 - 0.0629 g steamlg char.min and
30 - 60 min. This was done in order to find the optimum activation conditions within
the activation parameter range. The optimal activated carbons were defined as peach
and apricot shell activated carbons that showed good microporous as well as
mesoporous character. The optimal activated carbons produced are: peach shell
activated at 875°C, 0.0533 g stearnlg char. min, 60 min and apricot shell activated
carbon at 850°C, 0.0533 g steamlg char.min, 60min.
The possible use of these optimal activated carbons and two other activated carbons
produced (Peach shell activated carbon 900°C, 0.0425 g steamlg char. min, 60 min
and apricot shell activated carbon 900°C, 0.0425 g steamlg char.min, 60min) were
tested in gold recovery and water purification. The gold adsorption properties of
peach and apricot shell activated carbons were found to be better than two
commercial coconut shell activated carbons (Chemquest 650 and GRC 22). No
definite conclusions could, however, be drawn about the replacement of coconut shell activated carbon with peach or apricot shell activated carbon, because abrasion test
work and thermal regeneration of the experimental carbons still have to be performed.
The experimental activated carbons displayed good phenol adsorption characteristic,
although further test work is required. / AFRIKAANSE OPSOMMING: Perske- en appelkoospitte is landbouafvalprodukte. Hierdie afvalprodukte versamel
rondom inmaakfabrieke en voedselververkingsaanlegte. Tans word daar geen poging
in Suid-Afrika aangewend om hierdie afvalprodukte te benut nie. Hierdie studie is die
eerste deel van die ontwikkeling van die produkte: Perskepitdop-geaktiveerde
koolstof en appelkoospitdop-geaktiveerde koolstof. Deur geaktiveerde koolstof van
die perske- en appelkoospitdoppe te maak, word nie net 'n antwoord op die
vastestofafvalsprobleem gevind nie, maar daar kan ook geld gemaak word.
Hoekom geaktiveerde koolstof? Aktiveerde koolstowwe is veelsydige en unieke
adsorbente met 'n groot verskeidenheid adsorpsie toepassings. Dit kan vervaardig
word via 'n eenvoudige oksidasie reaksie met stoom en die aard van die perske- en
appelkoospitdoppe is sodanig, dat verwag kan word om geaktiveerde koolstowwe met
goeie adsorpsie eienskappe daarvan te kry. Die grootste enkelverbruiker van
geaktiveerde koolstof in Suid-Afrika is die goudmynbedryf, wat kokosneutdop
geaktiveerde koolstof invoer om goud te herwin. Geaktiveerde koolstof word ook
gebruik vir watersuiwering.
Tydens hierdie studie IS geaktiveerde koolstowwe by verskillende
aktiveeringskondisies in 'n gevloeïdiseerde bed vervaardig: 700 - 900oe, 0.0425 -
0.0629g stoornlg gepiroliseerde pitdoppe.min en 30 - 60 mm. Die
aktiveringskondisies is gevarieer om sodoende die optimale aktiveringskondisies
binne die aktiveringsparameterreeks te kry. 'n Geaktiveerde koolstof is as optimaal
geklassifiseer as dit 'n goeie mikro- sowel as mesostruktuur getoon het. Die optimaal
geaktiveerde koolstowwe is: geaktiveerde koolstof vervaardig van perskepitdoppe by
875°e, 0.0533 g stoornlg gepiroliseerde pitdoppe.min, 60 mm en geaktiveerde
koolstof vervaardig van appelkoospitdoppe by 850oe, 0.0533 g stoornlg
gepiroliseerde pitdoppe.min, 60min.
Die gebruik van die twee optimale geaktiveerde koolstowwe sowel as twee ander
geaktiveerde koolstowwe (perskepitdop-geaktiveerde koolstof, 900oe, 0.0425 g
stoornlg gepiroliseerde pitdoppe.min, 60 min en appelkoospitdop-geaktiveerde koolstof, 850°C, 0.0533 g stoom/g gepiroliseerde pitdoppe.min, 60min) is VIr
goudadsorpsie en watersuiwering ondersoek. Die goudadsorpsie eienskappe van die
perske-en appelkoospitdop-geaktiveerde koolstowwe was beter as die van twee
kommersiële kokosneutdop-geaktiveerde koolstowwe (Chemquest 650 and GRC 22).
Daar kan egter geen definitiewe gevolgtrekkings gemaak word oor die vervanging
van kokosneutdop geaktiveerde koolstowwe met dié van perske of appelkoospitdoppe
nie, aangesien daar nog toetsresultate oor die slytweerstand en reaktiverings
eienskappe van die eksperimentele geaktiveerde koolstowwe uitstaande is.
Die eksperimentele geaktiveerde koolstowwe toon goeie adsorpie ten opsigte van
fenol, maar verdere toetswerk is egter nodig.
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UTILIZATION OF COTTONSEED HULLS FOR HORSES.Lyle, William Henry. January 1983 (has links)
No description available.
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DEGRADATION OF WHOLE COTTONSEED IN THE RUMEN OF FISTULATED AND INTACT STEERS.Maman, Ali. January 1984 (has links)
No description available.
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Dark fermentative biohydrogen production using South African agricultural, municipal and industrial solid biowaste materialsSekoai, Patrick Thabang January 2017 (has links)
A dissertation submitted to the Faculty of Engineering and the Built Environment, University
of the Witwatersrand, Johannesburg, in fulfillment of the requirements for the degree of
Doctor of Philosophy in Engineering, October 2017 / The dwindling fossil reserves coupled with environmental pollution necessitate the search for
clean and sustainable energy resources. Biohydrogen is emerging as a suitable alternative to
fossil fuels and has received considerable attention in recent years due to its economic, social,
and environmental benefits. However, the industrial application of biohydrogen has been
hindered by low yield. Therefore, development of novel techniques to enhance the yield is of
immense importance towards large-scale production of biohydrogen.
Thus, this research effort explored various options to enhance the yield of biohydrogen
during dark fermentation process. Some options explored included (i) the utilization of
feedstocks from the agricultural, industrial and municipal sectors, (ii) parametric optimization
of biohydrogen production, (iii) investigation of biohydrogen production using metal ions and
nitrogen gas sparging, and (iv) assessing the feasibility of biohydrogen scale-up study to pave
the way for pilot-scale development. Solid biowaste feedstocks consisting of apple, bread,
brewery residue, cabbage, corn-cob, mango, mealie-pap, pear, potato, and sugarcane were
investigated for dark fermentative biohydrogen production using anaerobic mixed sludge.
The experimental results showed that substrates which are rich in carbohydrates are suitable for dark fermentative biohydrogen-producing bacteria. Consequently, a maximum
biohydrogen fraction of 43.98, 40.32 and 38.12% with a corresponding cumulative
biohydrogen yield of 278.36, 238.32 and 215.69 mL H2/g total volatile solids (TVS) was
obtained using potato, cabbage, and brewery wastes, respectively. Based on these results,
potato waste was chosen as a suitable substrate for subsequent biohydrogen production
studies.
Parametric optimization was carried out on biohydrogen production via dark fermentation
using potato waste as the substrate. Effects of operating variables such as pH, temperature, fermentation time, and substrate concentration were investigated via response surface
methodology (RSM) approach using a two-level-four factor (24) central composite design
(CCD). The obtained predictive model (statistical model) was used to explain the main and
interaction effects of the considered variables on biohydrogen production. In addition, the
model was employed in the optimization of the operating conditions. Consequently, a secondorder
polynomial regression with a coefficient of determination (R2) of 0.99 was obtained and
used in the explanation and optimization of operating variables. The optimum operating
conditions for biohydrogen production were 39.56 g/L, 5.56, 37.87 oC and 82.58 h for potato
waste concentration, pH, temperature and fermentation time, respectively, with a
corresponding biohydrogen yield of 68.54 mL H2/g TVS. These results were then validated
experimentally and a high biohydrogen yield of 79.43 mL H2/g TVS indicating a 15.9%
increase was obtained. Furthermore, the optimized fermentation conditions were applied in
the scale-up study of biohydrogen production that employed anaerobic mixed bacteria
(sludge) which was immobilized in calcium alginate beads. A biohydrogen fraction of
56.38% with a concomitant yield of 298.11 mL H2/g TVS was achieved from the scale-up
study.
The research also investigated the influence of metal ions (Fe2+, Ca2+, Mg2+ and Ni2+) on
biohydrogen production from suspended and immobilized cells of anaerobic mixed sludge
using the established optimal operating conditions. A maximum biohydrogen fraction of
45.21% and a corresponding yield of 292.8 mL H2/g TVS was achieved in fermentation using
Fe2+ (1000 mg/L) and immobilized cells. The yield was 1.3 times higher than that of
suspended cultures. The effect of nitrogen gas sparging on biohydrogen conversion efficiency
(via suspended and immobilized cells) was studied as well. Cell immobilization and nitrogen
gas sparging were effective for biohydrogen production enhancement. A maximum
biohydrogen fraction of 56.98% corresponding to a biohydrogen yield of 294.83 mL H2/g
TVS was obtained in a batch process using nitrogen gas sparging with immobilized cultures.
The yield was 1.8 and 2.5 times higher than that of nitrogen gas sparged and non-sparged
suspended cell system, respectively.
Understanding the functional role of microorganisms that actively participate in dark
fermentation process could provide in-depth information for the metabolic enhancement of
biohydrogen-producing pathways. Therefore, the microbial composition in the fermentation
medium of the optimal substrate (potato waste) was examined using PCR-based 16S rRNA
approach. Microbial inventory analysis confirmed the presence of Clostridium species which
are the dominant biohydrogen-producing bacteria.
The results obtained from this research demonstrated the potential of producing biohydrogen
using South African solid biowaste effluents. These feedstocks are advantageous in
biohydrogen production because they are highly accessible, rich in nutritional content, and
cause huge environmental concerns. Furthermore, optimization techniques using these
feedstocks will play a pivotal role towards large-scale production of biohydrogen by
increasing throughput and reducing the substrate costs which accounts for approximately
60% of the overall costs. The findings from this research also provide a solid basis for further
scale-up and techno-economic studies. Such studies are necessary to evaluate the
competitiveness of this technology with the traditional processes of hydrogen production. In
summary, the findings from this research effort have been communicated to researchers in the
area of biohydrogen process development in the form of peer-reviewed international
scientific publications and conference proceedings, and could provide a platform for
developing an economic biohydrogen scaled-up process. / CK2018
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