Academic literature on the topic 'Biogas from livestock waste'

The basis of the biogas production in agriculture is the processing of waste agricultural products (particularly excrements of farm animals but also phytomass). Different but rather similar is the biogas production from biologically degradable municipal waste (BDMW) and biologically degradable industrial waste (BDIW) coming mainly from food industry. The processing of these wastes in agricultural biogas stations could significantly improve their economy. It is necessary to note that all these biogas stations differ from the wastewater cleaning plants where municipal sludge water from public sewers is processed. The municipal sludge water processing to biogas by anaerobic fermentation is a classical technology introduced all over the world. At present, about 100 wastewater cleaning plants operate in the Czech Republic using regular sludge processing into biogas. Electricity produced is utilised mainly for the needs of own operation of waste water treatment plant (WWTP), partly it is sold into public power net. The heat energy is used for heating in the process and its surplus is utilised for operational and administrative facilities. Usually, the heat and electricity quantities produced do not cover the wastewater cleaning plant operation. Agricultural biogas stations and biogas stations for BDMW processing provide considerably higher gas yields because they work with higher dry matter contents in substratum, i.e. 8–12% (compared with waste water treatment plants – 2–6%), and are able to produce high gas surpluses for following applications. Frequently discussed issue are the processing of slaughter waste and grass (or public green areas at biogas stations).

The production of biogas from livestock waste manure in particular is one of the alternative utilization of organic wastes that can be implemented in Indonesia since there is a huge potential of bio-energy in Indonesia. This study utilizes cow manure as the raw material for making biogas and it is coupled with a cow rumen fluid and water. The objective of this study is to determine the effect of manure, rumen, and water composition in biogas production. The research was conducted in anaerobic for 60 days. The composition of manure, water, and the rumen were vary following the variable and ratio; variable A (manure and water); variable B (manure and rumen). The results indicate that the variable A (manure and water) with a 1:3 ratio, and the variable B (manure and rumen) with a 1:2 ratio produced the highest volume of biogas compared to other ratios. The highest biogas production occurred on average at day 23.

An inventory of agro-food industry organic waste streams with a high potential for biogas transformation was studied in a logistically viable area (Cider Region, Asturias, Spain). Three industries were selected as the most viable ones: livestock, dairy and beverage. The potential for methane production from six wastes (beverage waste, BW; milled apple waste, MA; milk waste, MK; yogurt waste, YG; fats and oils from dairy wastewater treatment, F&O and cattle manure, CM) at five different substrate:inoculum ratios (0.25, 0.50, 0.75, 1.00 and 1.50) was evaluated in laboratory batch assays. Obtained methane yields ranged from 202–549 mL STP CH4·g VS waste−1, and the methane content in biogas ranged from 58–76%. The ultimate practical biochemical methane potentials were slightly affected by the substrate:inoculum ratio. The estimation of the regional fluxes of waste and methane potentials suggests anaerobic digestion as a sustainable solution for the valorization of the organic wastes generated in this Region.

Ukraine has untapped potential for the production of own energy from renewable sources - processing of livestock waste (animal manure and bird droppings) with the formation of biogas, which can then be used to produce electricity, heat or fuel - analogues of natural gas (methane) (in particular, for own needs of farms). Currently in Ukraine, the generation of large amounts of waste on industrial farms is an environmental problem that needs to be addressed. Recycling livestock waste to generate biogas will partially solve environmental problems, as well as benefit from decentralized renewable energy production or fuel production. The role of renewable energy sources in energy production is constantly growing and now the issue of increasing the share of renewable sources in the energy balance of each country is relevant. In the supply of primary energy, the share of renewable energy accounts for 13% worldwide. Of these, biomass accounts for 10%, or 258 million tons per year, ie in the world biomass provides the largest share of energy supply from renewable sources. Domestic agricultural enterprises are significant consumers of fuel and energy resources, so they face the objective need to use alternative energy sources, including biofuels and the introduction of innovative energy-saving technologies. Biogas production is an efficient and attractive investment technology, due to the presence of significant raw material potential, favorable climatic and other. However, the level of introduction of this type of energy in the agro-industrial complex is insufficient, which is due to a number of issues, including insufficient level of practical recommendations for choosing power generators, their number, modes of operation taking into account daily energy consumption schedule, load and optimal efficiency. installations while providing autonomous power supply of the enterprise. This paper determines the level of energy supply of livestock farms through the use of biogas plants as a source of energy used for livestock waste.

For some time now, the development of systems for electricity production based on the exploitation of renewable energy sources has begun to progress. Biogas is one of these energy sources. Thanks to the new regulations in the field of self-production of energy, the recognition of the environmental value of electricity from renewable sources and a proven technology is now possible to produce, through the process of anaerobic digestion, biogas for cogeneration of heat and electricity at favorable conditions. This study highlights the economic advantages resulting from the implementation of biogas cogeneration plant fueled with biogas from buffalos waste and other waste material resulting from the same production chain, in an area of Campania (Italy) with an intense livestock activity.

Pakistan is facing a severe energy crisis due to its heavy dependency on the import of costly fossil fuels, which ultimately leads to expansive electricity generation, a low power supply, and interruptive load shedding. In this regard, the utilization of available renewable energy resources within the country for production of electricity can lessen this energy crisis. Livestock waste/manure is considered the most renewable and abundant material for biogas generation. Pakistan is primarily an agricultural country, and livestock is widely kept by the farming community, in order to meet their needs. According to the 2016–2018 data on the livestock population, poultry held the largest share at 45.8%, followed by buffaloes (20.6%), cattle (12.7%), goats (10.8%), sheep (8.4%), asses (1.3%), camels (0.25%), horses (0.1%), and mules (0.05%). Different animals produce different amounts of manure, based upon their size, weight, age, feed, and type. The most manure is produced by cattle (10–20 kg/day), while poultry produce the least (0.08–0.1 kg/day). Large quantities of livestock manure are produced from each province of Pakistan; Punjab province was the highest contributor (51%) of livestock manure in 2018. The potential livestock manure production in Pakistan was 417.3 million tons (Mt) in 2018, from which 26,871.35 million m3 of biogas could be generated—with a production potential of 492.6 petajoules (PJ) of heat energy and 5521.5 MW of electricity. Due to its favorable conditions for biodigester technologies, and through the appropriate development of anaerobic digestion, the currently prevailing energy crises in Pakistan could be eliminated.

The livestock sector is a fundamental part of the modern global economy and provides food, clothing, furnishings, and various other products. So as to ensure its resilience to changes in consumer expectations, cost of production, and environmental sustainability, the sector must shift to a circular economy model. Current strategies to recover value from wastes and low-value co-products from livestock industries yield limited value; hence, new technologies are required to upgrade wastes and co-products, and generate high-value products that can feed into the livestock value chain. Anaerobic digestion can convert high organic-content waste to biogas for energy and a stable nutrient-rich digestate that can be used as fertiliser. Microbial technologies can transform wastes to produce nutritionally advanced feeds. New materials from waste can also be produced for livestock industry-specific applications. While aiming to add commercial value, the successful implementation of these technologies will also address the environmental and productivity issues that are increasingly valued by producers and consumers.

In this research, we studied the use of cattle biological waste to obtain biogas through a biodigester in the city of Chone, considered the livestock capital of Ecuador. Biogas is a mixed gas produced by the fermentation (anaerobic digestion) of organic materials in the absence of oxygen. It is mostly composed of methane and carbon dioxide. The biogas production process takes place in a container called a digester, in which the anaerobic fermentation process occurs. Obtaining biogas is one of the most used alternative sources for the production of renewable energy, so it can be evidenced by its importance as a tool against the fight of the environmental problem that exists today. The use of biogas of bovine origin has a high calorific value so it can be used for the production of heat, electricity or biofuel. This initiative seeks to manage and sustainably reduce organic waste, reduce the amount of greenhouse gas emitted into the atmosphere and reduce dependence on fossil fuels.

Ngadirojo District was one of the centers of beef cattle business development in Wonogiri Regency. But the business done by farmers has not yet produced an optimal income. The purpose of this service activity was to empower farmers by increasing farmers' knowledge through the application of organic fertilizer-based fertilizer production technologies for beef cattle manure and biogas waste so as to increase the income of farmers. The method of this community service activity was through FGD (Focus Group Discussion), counseling, training and demonstration plots on technology for organic fertilizer and biogas production. The result of this activity was an increase in knowledge of farmers after attending counseling and training on organic fertilizer and biogas production technology. Farmers in Gemawang and Gedong Ngadirojo villages have benefited from the construction of biogas installations and the processing of livestock waste into organic fertilizer. The conclusion of this activity was the effort of empowerment through counseling activities and training on processing livestock waste into organic fertilizer and biogas showing success and running effectively as seen from the increasing knowledge of respondents after participating in counseling and training activities.

Inadequate disposal of livestock manure has caused environmental pollution around the village, both water, soil and air (smell). Animal waste in the form of liquid is deliberately flowed into the river while solid waste is left piled up around the cage. The occurrence of odor and pollution is sometimes triggered social conflict, with complaints from local communities. With a population of 35 head of cattle for a farmer group, assuming the average per cow yields 15 kg of solid waste, the waste produced can reach approximately 525 kg per day. The lack of knowledge and the low educational background of the cattle ranchers in the Arabica Village makes the awareness of the environment to be lacking, as well as the technology of processing animal waste and the benefits. Biogas Reaktors of animal waste, although they have heard but lack of knowledge of how to make biogas installations and the assumption that the budget is spent to build the technology makes them prefer to allocate these funds to other things in order for the survival of livestock business can be sustainable. By looking at the existing potential, of course, if managed properly, Arabica Village can become an energy independent village and is a new business opportunity, for biogas products and residues from the installation of biogas in the form of organic fertilizer.

The purpose of this feasibility study has been to guide decision makers in the implementation of abiogas project for the region of Sønderborg, Denmark. The project has been part of Feasibility studies envisioned in the Master Plan for Sønderborg to go carbon neutral by 2029. The study tried to evolve abest alternative for the city and gives a ready document to refer all aspects of biogas. The intensive industrial farming in Sønderborg needs to evolve to compare favorably with the situationin other regions of Denmark. The interests of various stakeholders in the waste cycle should be alignedwith that of farming. Interesting developments in the Bioenergy space hold promise for farmers to usetheir capacities for additional or alternative livelihood in energy. The focus to promote biogas as part ofDanish energy strategy and multiply capacity over the next 3 years has attracted numerous biogas proposals all over Denmark. This study had started off with identifying and estimating very obvious substrate sources. At verymoderate assumptions the value of methane in these sources has been estimated at 9 million m3. Thispotential could easily be increased if economically feasible substrates like energy crops and algae areadded. The SWOT analysis of pig farming in the region brings out the perspectives of farming direction in the near future. The 5 scenarios developed help the decision maker understand the various aspects thatneed to be carefully considered when planning the plant. The best case scenario for the city would bethe energy mosaic scenario which would integrate the high tech focus of local industry, a renewable energy source and a showcase project to make the region stand out among the other regions focused inthe climate change debate. The technological system analysis should help decision makers understand the stakeholders and the various dimensions in biogas that although complicated are manageable. The business case approach to identify utilization of energy and its costs gives a clear picture on the need for using the energy in CHP.The present focus by potential investors on government subsidies to calculate profitability needs to be understood in the context of other similar plants accepting present subsidy levels and the societal benefits, which unfortunately cannot be valued in money terms. At the center of all this is the need for proper stakeholder management within a bound timeframe asidentified by the “Create acceptance process”. The various tools and data are all present in this study,that only need to be arranged and presented by the company eventually handling the strict Projectmanagement goals of this project.

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Tesis por compendio
[ES] El acceso a fuentes de energía moderna en las áreas rurales de la región andina es uno de los factores principales para disminuir la pobreza ya que su acceso proporcionaría beneficios ambientales, económicos y sociales. Pese a los esfuerzos de buscar fuentes alternativas para subsanar el déficit energético, aún existen millones de personas que sufren la falta de accesibilidad a fuentes de energía moderna, situación que se debe a los altos niveles de pobreza bajo los cuales se encuentran inmersos. Junto a este inconveniente se suma el enorme incremento de residuos agrícolas en las comunidades andinas. Residuos que provienen de las actividades agrícolas, y que podrían ser perjudiciales para el medio ambiente si no se toman medidas adecuadas. Lamentablemente, en muchos países en desarrollo donde se generan grandes cantidades de estos residuos, se sabe poco sobre sus posibles riesgos y beneficios si no se gestionan adecuadamente. Uno de los enfoques más interesantes para abordar esta problemática, es el desarrollo de la gestión sostenible de los residuos orgánicos agrícolas de la región, transformándolos en recursos para la generación de energía renovable (biogás) y fertilizantes orgánicos (digestato). Esta solución permitiría dar una valorización energética a los residuos de la agricultura de la zona, sobre la cual basan su economía, y a la vez contribuiría a una mayor gestión de los residuos evitando el incremento de la contaminación ambiental. Con la finalidad de contribuir al desarrollo energético y mejorar el paradigma de la gestión de residuos en el área andina de Guaranda (Ecuador), la presente Tesis Doctoral aborda la evaluación del potencial bioquímico de metano (BMP) de los residuos orgánicos agrícolas de la región. Se realiza una cuantificación sistemática de la producción de biogás mediante la transformación bioquímica de residuos orgánicos agrícolas, que comprenden: sustratos principales (residuos de estiércol de vicuña, llama y cuy, y residuos de matadero de ganado vacuno) y cosustratos (residuos de paja de amaranto, quinua y trigo). El objetivo general de esta investigación de doctorado se ha llevado a cabo en cuatro fases: (I) Caracterización de la materia prima mediante el análisis elemental y proximal a través de los cuáles se estimó el rendimiento teórico y la biodegradabilidad de los sustratos y cosustratos, (II) Rendimiento de la codigestión de residuos orgánicos agrícolas con mezclas de lodos de aguas residuales en biodigestores batch, (III) Análisis de los efectos sinérgicos y antagónicos durante la monodigestión y codigestión de las materias primas y (IV) Evaluación de la cinética microbiana de la digestión anaerobia mediante los modelos de Gompertz modificado, transferencia, ecuación logística, modelo del cono y Richards modificado. En la caracterización fisicoquímica se determinó que las relaciones SV/ST de los sustratos y cosustratos oscilaron entre 58 y 77% con una relación C/N entre 12 y 102, lo que indicó que estos residuos son materias primas adecuadas para la producción de metano. En todos los ensayos un aumento de la cantidad de inóculo mejoró la biodegradabilidad de los sustratos y por consiguiente la producción metano; así, en la monodigestión se tuvo incrementos de hasta 90% y en la codigestión incrementos del 71%. Todas las mezclas produjeron efectos sinérgicos, donde los mayores porcentajes de metano se dieron cuando las mezclas de residuos de amaranto, quinua y trigo fueron del 50 y 75% de sólidos volátiles. Independientemente de la SIR1:1 y la SIR 1:2 se mejoró la producción de metano de la codigestión al incrementar el porcentaje de cosustrato especialmente de residuos de amaranto y quinua. Los mejores resultados de todos los ensayos realizados se obtuvieron en los biodigestores compuestos por residuos de matadero y residuos de quinua, donde se obtuvieron producciones de metano entre 581 y 555 ml
[CA] L'accés a fonts d'energia moderna en les àrees rurals de la regió andina és un dels factors principals per a disminuir la pobresa ja que el seu accés proporcionaria beneficis ambientals, econòmics i socials. Malgrat els esforços de buscar fonts alternatives per a esmenar el dèficit energètic, encara existeixen milions de persones que pateixen la falta d'accessibilitat a fonts d'energia moderna, situació que es deu als alts nivells de pobresa sota els quals es troben immersos. Al costat d'aquest inconvenient se suma l'enorme increment de residus agrícoles en les comunitats andines. Residus que provenen de les activitats agrícoles, i que podrien ser perjudicials per al medi ambient si no es prenen mesures adequades. Lamentablement, en molts països en desenvolupament on es generen grans quantitats d'aquests residus, se sap poc sobre els seus possibles riscos i beneficis si no es gestionen adequadament. Un dels enfocaments més interessants per a abordar aquesta problemàtica, és el desenvolupament de la gestió sostenible dels residus orgànics agrícoles de la regió, transformant-los en recursos per a la generació d'energia renovable (biogàs) i fertilitzants orgànics (digestato). Aquesta solució permetria donar una valorització energètica als residus de l'agricultura de la zona, sobre la qual basen la seua economia, i alhora contribuiria a una major gestió dels residus evitant l'increment de la contaminació ambiental. Amb la finalitat de contribuir al desenvolupament energètic i millorar el paradigma de la gestió de residus en l'àrea andina de Guaranda (l'Equador), la present Tesi Doctoral aborda l'avaluació del potencial bioquímic de metà (BMP) dels residus orgànics agrícoles de la regió. Es realitza una quantificació sistemàtica de la producció de biogàs mitjançant la transformació bioquímica de residus orgànics agrícoles que comprenen: substrats principals (residus de fem de vicunya, flama i cuy, i residus d'escorxador de bestiar boví), *cosustratos (residus de palla d'amarant, quinua i blat). L'objectiu general d'aquesta investigació de doctorat s'ha dut a terme en quatre fases: (I) caracterització de la matèria primera mitjançant l'anàlisi elemental i proximal a través dels quals es va estimar el rendiment teòric i la biodegradabilitat dels substrats i cosustratos, (II) Rendiment de la codigestión de residus orgànics agrícoles amb mescles de llots d'aigües residuals en biodigestores batch, (III) Anàlisis dels efectes sinèrgics i antagònics durant la monodigestión i codigestión de les matèries primeres i (IV) Avaluació de la cinètica microbiana de la digestió anaeròbia mitjançant els models de Gompertz modificat, transferència, equació logística, model del con i Richards modificat. En la caracterització fisicoquímica es va determinar que les relacions SV/ST dels substrats i cosustratos van oscil·lar entre 58 i 77% amb una relació C/N entre 12 i 102, la qual cosa va indicar que aquests residus són matèries primeres adequades per a la producció de metà. En tots els assajos un augment de la quantitat d'inòcul va millorar la biodegradabilitat dels substrats i per consegüent la producció metà; així, en la monodigestión es va tindre increments de fins a 90% i en la codigestión increments del 71%. Totes les mescles van produir efectes sinèrgics, on els majors percentatges de metà es van donar quan les mescles de residus d'amarant, quinua i blat van ser del 50 i 75% de sòlids volàtils. Independentment de la SIR1:1 i la SIR 1:2 es va millorar la producció de metà de la codigestión en incrementar el percentatge de cosustrato especialment de residus d'amarant i quinua. Els millors resultats de tots els assajos realitzats es van obtindre en els biodigestores compostos per residus d'escorxador i residus de quinua, on es van obtindre produccions de metà entre 581 i 555 ml/g VS.
[EN] Access to modern energy sources in rural areas of the Andean region is one of the main factors to reduce poverty, since its access would provide environmental, economic and social benefits. Despite efforts to find alternative sources to correct the energy deficit, there are still millions of people who suffer from the lack of accessibility to modern energy sources, a situation that is due to the high levels of poverty under which they are immersed. Along with this inconvenience is added the enormous increase in agricultural residues in the Andean communities. Waste that comes from agricultural activities, and that could be harmful to the environment if adequate measures are not taken. Unfortunately, in many developing countries where large amounts of these wastes are generated, little is known about their potential risks and benefits if not managed properly. One of the most interesting approaches to address this problem is the development of sustainable management of agricultural organic waste in the region, transforming it into resources for the generation of renewable energy (biogas) and organic fertilizers (digestate). This solution would allow to give an energetic recovery to the agricultural residues of the area, on which they base their economy, and at the same time would contribute to a better management of the residues avoiding the increase of environmental pollution. To contribute to energy development and improve the paradigm of waste management in the Andean area of Guaranda (Ecuador), this Doctoral Thesis addresses the evaluation of the biochemical potential of methane (BPM) of agricultural organic waste in the region. A systematic quantification of biogas production is carried out through the biochemical transformation of agricultural organic waste that includes main substrates (vicuña, llama and guinea pig manure residues, and cattle slaughterhouse residues) and co-substrates (amaranth straw residues), quinoa and wheat). The general objective of this doctoral research has been carried out in four phases: (I) characterization of the raw material through elemental and proximal analysis through which the theoretical performance and biodegradability of substrates and co-substrates were estimated, (II) Performance of the co-digestion of agricultural organic waste with mixtures of sewage sludge in batch biodigesters, (III) Analysis of synergistic and antagonistic effects during monodigestion and co-digestion of raw materials and (IV) Evaluation of microbial kinetics of anaerobic digestion using modified Gompertz models, transfer, logistic equation, cone model and modified Richards. In the physicochemical characterization it was determined that the VS/TS ratios of the substrates and co-substrates ranged between 58 and 77% with a C/N ratio between 12 and 102, which indicated that these wastes are suitable raw materials to produce methane. In all the tests an increase in the amount of inoculum improved the biodegradability of the substrates and consequently the methane production; thus, in monodigestion there were increases of up to 90% and in co-digestion increases of 71%. All the mixtures produced synergistic effects, where the highest percentages of methane occurred when the mixtures of amaranth, quinoa and wheat residues were 50 and 75% volatile solids. Regardless of SIR1:1 and SIR 1:2, the production of methane from co-digestion was improved by increasing the percentage of co-substrate, especially amaranth and quinoa residues. The best results of all the tests carried out were obtained in the biodigesters composed of slaughterhouse waste and quinoa waste, where methane productions between 581 and 555 ml/g VS were obtained. Regarding the kinetic modelling of the anaerobic digestion process, it was found that all the models fit the experimental values quite well with the predicted ones. In the monodigestion, in all the logistic models, the calculated asymptotes were adjusted very precisely for the specific yield (Me
This work has been carried out within the framework of the project “Analysis of the implementation of biomass exploitation chains in rural communities in the province of Bolívar (Ecuador)” of the ADSIEO-COOPERATION program of the Universitat Politècnica de València (UPV). The Ecuadorian Energy Exploitation Research Network of Biomass (ECUMASA) and the IBEROMASA Network (719RT0586) of the IberoAmerican Program of Science and Technology for Development (CYTED) have participated in this program
Meneses Quelal, WO. (2021). Optimization of Anaerobic Codigestion Processes of Lignocellulosic Materials of Difficult Degradation with Residues from Andean Livestock [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/171722
TESIS
Compendio

The aim of this experiment was to monitor the microbial communities in two biogas reactors and evaluate the efficiency of denaturing gradient gel electrophoresis (DGGE) as a technique for visualizing shifts in the microbial compositions. The reactors were followed from September 2011 to May 2012. The first reactor is a pilot scale upflow anaerobic sludge blanket (UASB) reactor situated at Foss farm outside of Porsgrunn, running on cow manure. The second reactor is lab scale and situated at Telemark University College, running on pig manure. Samples were taken from the reactors at regular intervals. DNA was extracted from the samples and amplified by polymerase chain reaction (PCR). The primers were 338f and 518r, targeting the 16S rDNA sequence. Changes in the microbial diversity were detected by DGGE in both reactors. Some bands appeared and other disappeared during the period. These changes could not be correlated to changes in operating conditions. This was probably because DGGE reflects cell amounts and not microbe activity levels. DGGE is a highly reproducible and consistently performing fingerprinting technique. It is capable of reflecting long term shifts in the microbial communities and several samples can be compared in one gel. This makes DGGE an effective method for monitoring reactors over time. Several DGGE bands were excised and sequenced, but the results were either negative, or of too poor quality, for further analysis. The probable cause was insufficient separation of bands leading to multiple sequences in the extracted DNA. This may be overcome by using a more specific primer set to reduce the amount of bands.

Textile is a global product used by all people in the world. These textiles after the use are thrown into the trash for incineration or land filling. However an efficient way that can be used to produce more energy, in an environmentally friendly process is anaerobic digestion. Waste textiles which contain cellulosic fibers (e.g. Cotton and viscose) can be converted to biogas. In this study, the performance of a two-stage anaerobic digestion process for biogas production from four different materials, including untreated jeans, treated jeans, cotton, and starch was studied. Starch was used as an easy-to-digest material to compare its digestion with that of cellulosic materials.The two-stage processes were composed of a CSTR (for hydrolysis) and a UASB (for methanogenisis) which were investigated in two different configurations, namely (closed and open systems). In the closed system, the outlet of UASB was completely returned back to the CSTR, while in the open system the UASB outlet was sent to sewage. In a stepwise progress, the OLR was aimed to increase from 2 to 20 g Vs per L per day along with reduction in hydraulic retention time from 10 days to 1 day.The results showed that the closed system was more stable when compared to the open system. The pre-treatment of jeans by NMMO helped to produce methane as that of cotton. The hydraulic retention time was decreased to less than 9 days for treated jeans and less than 5 days for starch. The overall methane yield at OLR of 4 gVS per L per day for starch and treated jeans was 98.5% and 97.4% in the closed system, whereas in the open system the yield was 77.0% and 35.5%, respectively.Another experiment was conducted to compare the performance of two-stage process with that of a single stage process of anaerobic digestion of textiles containing polyester and cotton or viscose. Viscose textiles produced more gas compared to the cotton textile; it may be due to the higher crystalline of cotton which makes it hard to be degraded by the microorganisms. Furthermore, two-stage process could able to produce more methane than the single stage process.The parameters like total solids, volatile solids, pH, gas production, gas composition, concentration of nutrients, and COD were also analyzed for both of the experiments.

This project investigates local industrial biomass streams as feedstocks for the generation of low-cost sustainable energy for The University of Iowa. Methane gas produced during anaerobic digestion would fuel an engine to generate electricity at the University of Iowa Research Park (Oakdale Campus). A current local industry identified for this project is West Liberty Foods (WLF), a turkey processing facility located in West Liberty, Iowa, USA. WLF generates about 6,000 gal/day of blood, 40,000 lb/day of offal (guts), 6,000 lb/day of sludge (process waste water) and 2-4 truckloads/day of feathers as waste streams. To investigate biochemical methane potential, mixed streams and individual streams of WLF were processed anaerobically and incubated at 35 °C. Mixed streams contained blood, offal, and sludge, and individual streams contained offal and sludge. Mixed streams and individual streams generated methane gas. The methane production from mixed streams was achieved on the 11th day of processing, and it was achieved on the 9th day from individual streams. Sludge was the only stream that did not require the addition of acetate for the production of methane gas. Methane production was analyzed using gas chromatography. Methane production was achieved without addition of microbial seed cultures. Cumulative methane and energy produced by the 36th day of processing 6 grams of offal with the addition of acetate are 110 ± 50 mmol/lb and 0.09 ± 0.04 kJ/lb respectively, and without the addition of acetate are 62 ± 2 mmol/lb and 0.054 ± 0.002 kJ/lb respectively. Cumulative methane and energy produced by the 36th day of processing 6 grams of sludge with the addition of acetate are 200 ± 20 mmol/lb and 0.18 ± 0.02 kJ/lb respectively, and without the addition of acetate are 220 ± 60 mmol/lb and 0.19 ± 0.04 kJ/lb respectively. Each average was calculated from three data points with their errors. Reported values are calculated at 95% confidence intervals. The Oakdale Campus is estimating to produce 5.5 MW energy from renewable sources of energy. The methane production capacity from processing turkey waste based on COD analysis was approximately 1% of the renewable energy target. However, the system is still producing methane gas and the process is not complete yet nor has it been optimized. Benchmarking methane productivity through improved quantitative measures should continue to establish the utility of the process.

In order to decrease the pollution of the marine environment from dumping fish waste and by-catch, alternative use for co-digestion with sludge in anaerobic condition was studied. The purpose of this project is to optimize the methane potential from adjustment of the proportion among mixed substrates. Ten groups of different proportions among fish waste, by-catch and sludge were conducted with AMPTS II instrument under mesophilic condition (37 ± 0.5 ºC), by means of the principle of BMP test. The ratio of inoculums and mixed substrate was set as 3:2. The optimal MP obtained after an experiment with 13 days digestion was 0.533 Nm3 CH4/kg VS from the composition of sludge, by-catch and fish waste as 33 %, 45 % and 22 %. It was improved by 6 % and 25.6 %, to compare with the previous studies by Almkvist (2012) and Tomczak-Wandzel (personal communication, February 2012) respectively.

Ever since 1976, livestock farmers in Fiji have been intrigued about biogas digesters as an animal waste management measure, but the concept has never evolved into one that is sustainable. Renewed interest came in 1997 after a better Chinese Modified Dome (CMD) design was established, with this came government funding, however by 2002, some failure was also observed. This study set out to investigate the reasons why biogas digesters have never been established as a sustainable concept, its effectiveness as an animal waste management tool and what changes if any, can be made to try and influence the further development of the concept in Fiji. In order to achieve the objectives, which were simply obtaining the answers to the questions presented above, several different approaches had to be followed. This study was the first on biogas digesters in Fiji and it was unique in the sense that the major component dealt with the social aspects of farmers in relation to their biogas digesters. Basically the study was carried out in two parts - desktop studies and field studies. Desktop studies were done to better understand the situation while the field studies included semi-structured interviews with the farmers as well as the collection of biophysical data. Twelve outcomes are presented in chapter 7 of this paper. Two in particular are the improvement of construction and maintenance, which can only come about through training. The research questions are also answered in chapter 7, with recommendations put forward on possible directions to take in terms of trying to influence the development of the concept in Fiji
Master of Science (Hons)

Thesis (M. Sc.) (Hons) -- University of Western Sydney, 2005.
" A thesis presented to the School of Environment and Agriculture, University of Western Sydney, in fulfilment of the requirements for the degree of Master of Science (Honours)." Includes bibliography : leaves 165 -175, and appendices.

The Brazilian city ofCuritiba produces 2 500 tons of MSW (municipal solid waste) per day that is landfilled.In an effort to find a more sustainable solution for waste management, the objective of this study was to investigate the potential for producing biogas from anaerobic digestion by analyzing the feasibility of small-scale decentralized biogas production as well as centralized production at commercialscale. A field study was carried out to map specific local circumstances and togather data by interviews and literature. Different methods of attaining the organic waste were reviewed and the options for biogas production were evaluated by comparing the highest investment cost admissible for a positive netpresent value of a prospective investment with estimations of investment costs from literature sources. Small-scale decentralized biogas production was found to be the most economically and socially viable option. For centralized production, the results were inconclusive but indicated the potential of profitable business cases. It is estimated that wet digestion in a floating-drum ortubular digester is most suitable for small scale applications while acontinuously dry digestion system is best suited for large scale biogasproduction in Curitiba. The sensitivity analysis showed that the amount oforganic waste available as well as the price of sold products had the biggest economic impact in the scenarios. It was found that any implementation of controlled anaerobic digestion would decrease the total global warming potential of the waste management system. It is recommended that the municipality proceed with and expand a pilot project at Mercado Regional, as well as exploring possibilities for more efficient waste collection, along with gathering more specific data on compositions and quantities for different waste flows. The study was carried out in the scope of a cooperation between KTH, the Swedish EnvironmentalProtection Agency, Municipality of Curitiba and local universities in Paraná,Brazil.
Den brasilianska staden Curitiba producerardagligen 2 500 ton MSW (municipal solid waste) som i dagsläget deponeras. Isyfte att hitta en mer hållbar lösning för avfallshantering ämnade denna studieundersöka potentialen för biogasproduktion via rötning genom att analyseragenomförbarheten av småskalig decentraliserad biogasproduktion samtcentraliserad produktion i kommersiell skala. En fältstudie genomfördes för attkartlägga specifika lokala omständigheter och samla in data genom intervjueroch litteratur. Olika metoder för insamling av organiskt avfall granskades ochalternativen för biogasproduktion utvärderades genom att jämföra de högstatillåtna investeringskostnaderna för ett positivt nettonuvärde av en framtidainvestering med uppskattade investeringskostnader från litteraturkällor.Småskalig decentraliserad biogasproduktion visade sig vara det bästaalternativet från ett ekonomiskt och socialt perspektiv. För centraliseradproduktion var resultaten tvetydiga men indikerade att en lönsam affärsmodellpotentiellt kunde utarbetas. Rötning av substrat med hög fuktighetshalt i en“floating-drum” reaktor eller en tub-formad reaktor bedöms vara bäst lämpat förbiogasproduktion i liten skala emedan ett kontinuerligt system för rötning avtorra substrat bedöms som det bästa alternativet för storskaligbiogasproduktion. Känslighetsanalysen visade att mängden insamlat organisktavfall samt priset på slutprodukterna hade störst påverkan på det ekonomiskautfallet. Studien påvisade även att en implementering av en rötningsanläggningskulle minska växthuspotentialen i avfallshanteringssystemet oavsett skala. Detrekommenderas att kommunen fortsätter med och utvecklar ett pilotprojekt iMercado Regional, samt undersöker möjligheterna för effektivare sophämtning ochsamlar mer specifika data om sammansättning och kvantitet för olika sopflöden. Arbetetutfördes som ett led i samarbetet mellan KTH, svenska Naturvårdsverket,Curitiba kommun och lokala universitet i Paraná, Brasilien.

The manual describes technologies for processing secondary products and agricultural waste using macro-and micro-organisms. The regulations of modern biotechnologies of microbial synthesis, bioconversion of secondary raw materials are briefly presented, methods of its processing and characteristics of the obtained target products of bioconversion are described. Practical classes introduce students to modern methods of improving environmental quality and production waste from commercial products (organic fertilizers, bacterial preparations, feed additives, etc.), as well as obtain the cheapest fuel and energy resources (biogas, alcohols, acids, liquid biofuels, etc.). Meets the requirements of Federal state educational standards of higher education of the last generation. It is intended for students of higher educational institutions of technological specialties.

With the adoption of the Green Deal in the European Union (EU), the role of biodiversity, basic principles of the circular economy, climate change mitigation, forest protection and renewable energy increased. Since 2007, biogas production in Latvia has increased significantly, as it was possible to receive co-funding from the EU Funds for the construction of biogas plants. In 2021, inputs of agricultural origin are used by 40 biogas plants with an average installed capacity of 1 MW. The emergence of biogas plants on livestock farms is facilitated by the development of a circular economy producing waste from the production process – manure and feed waste. Anaerobic fermentation results in digestate – a nutrient-rich plant fertilizer that reduces the application of chemical fertilizers. Rational use of biogas can reduce the need for fossil fuels. Energy production from biogas should be encouraged, as waste is used efficiently, thereby generating energy and reducing the release of greenhouse gases into the atmosphere. In Latvia, livestock production is one of the key industries of the national economy, which produces manure and feed waste. The present research calculated the amounts of cattle, pig and poultry manure and feed waste in Latvia. The research analysed livestock farms by number of cattle, pigs and poultry, the potential amounts of manure and waste produced and theoretical biogas output. Theoretically, 309 farms analysed can produce 93.5 mln. m3 of biogas from agricultural waste and construct 269 new biogas plants. A policy for supporting the construction of new biogas plants would contribute to the country’s independence from fossil energy sources, as well as increase the proportion of renewable energy sources to 50-70 % in final energy consumption by 2030. Farmers on whose farms a biogas plant could be built need to carefully consider the uses of the biogas produced. The uses could be thermal energy generation for heat supply, cogeneration (thermal and electrical energy) or biomethane production.

Anaerobic digestion (AD) has gained popularity as an effective way to treat organic materials, produce clean energy, and reduce greenhouse gas emissions. There is a significant number of large-scale AD facilities operating world-wide, largely treating livestock wastes, and used primarily for electricity production in industrialized countries. At the same time, there are millions of small, household-scale ADs deployed in developing countries, mostly to provide biogas resources for heating and cooking. Decentralized low-volume AD systems could provide a local, renewable energy source (for electricity, heating, or both), reduce or eliminate waste disposal costs, and limit discharges of high strength wastes. The purpose of this study was to evaluate the feasibility of deploying low-volume anaerobic digestion (LVAD) systems at institutions generating significant food waste, using Rochester Institute of Technology (RIT) as a case study. Mass flows and energy balance, net present value (NPV), and discounted payback period (DPP) were used to assess the feasibility of implementing an anaerobic digestion system utilizing the campus organic waste resources. Our study showed that a positive NPV can be achieved if subsidies and incentives were applied to offset the initial capital investment. However, the economics can be improved by driving down equipment cost and accepting food waste from other establishments to generate revenue from tipping fees.

Abstract The urgent need to decrease greenhouse gases (GHG) has prompted countries such as the UK and Norway to commit to net zero emissions by 2050 and 2030, respectively. One of the sectors contributing to GHG emissions is agriculture, by approximately 10% in the EU in 2017. GHG reductions in the production side should involve avoidance at source, reduction of emissions and/or removal of those emissions, with the potential for negative emissions by carbon capture. This paper focuses on the utilisation of agricultural waste that can be converted into biogas, such as livestock and crops residues which represent around 37% of GHG emissions by agriculture in the EU. The biogas can be used to produce electricity and heat in a micro gas turbine (MGT). Then, the exhaust gases can be sent to a carbon capture plant. This offers the potential for integration of waste into energy for in-house use in farms and fosters a circular-bioeconomy, where the captured CO2 could be used in greenhouses to grow vegetables. This could even allow the integration of other renewable technologies, since the MGT offers flexible operation for rapid start-up and shut down or intermittency of other technologies such as solar or wind. Current carbon capture processes are very costly at the smaller scales typical of remote communities. The alternative A3C (advanced cryogenic carbon capture) process is much more economical at smaller scales. The A3C separates CO2 from process gas that flows counter-currently with a cold moving bed, where the CO2 desublimes on the surface of bed material as a thin layer of frost. This allows enhanced heat transfer and avoids heavy build-up of frost that reduces severely the heat transfer. The phase change separation process employed by A3C and the large thermal inertia of the separation medium gives good flexibility of capture for load changes and on-off despatch. This study integrates a combined heat and power MGT, Turbec T100, of 100 kWe output. This include developed models for the MGT using characteristics maps for the compressor and turbine and for the cryogenic carbon capture plant, using two software tools, IPSEpro and Aspen Plus, respectively.

Biomass as a sustainable and renewable energy source is starting to gain momentum, especially as more economical energy extraction methods prevail. Supercritical water biomass gasification (SCWBG) is one of the more promising methods to extract energy from biomass in a gaseous form due to its lower temperature and simpler setup. In this work, two biomass samples (considered livestock feed) and two biomass waste samples are gasified in supercritical water (SCW). To compare the gasification of the real biomass samples (beat skin and straw) to previous works on model biomass compounds, two temperature states (hence different water densities) were used during gasification. An increase in temperature and decrease in water density was found to have similar effects on real biomass compared to that of model compounds. As temperature increases and water density decreases, combustible gas yields tend to increase due to changes in reaction pathways and reaction rates. In this work an analytical comparison is also made between the four different types of biomass in terms of which produce the most combustible gases and of which will generate the most energy. As a result of this analysis beet skins produce the most methane and corn silage yields the most hydrogen. It is the two bio-waste products, however, that generated the largest higher heating values (HHV).

Ashe Juniper is one of three major species of juniper native to Texas. Communities of Ashe Juniper occupy over 8 million acres of Texas rangelands and are responsible for herbage reduction, which adversely impacts the livestock carrying capacity. Ashe Juniper wood contains aromatic liquids called essential oils, which are economically beneficial for the personal care products industry. In order to exploit this benefit Texarome, Inc. of Leaky, Texas uses a large-scale steam distillation process to extract aromatic liquids from Ashe Juniper. This process results in a large quantity of Ashe Juniper woodchip waste for which there is few uses. A moderate temperature process known as fast pyrolysis was used to convert steam-distillated Ashe Juniper into a liquid known as bio-oil. An average liquid yield of 40.8% is reported for steam-distillated Ashe Juniper biomass and an average liquid yield of 47.3% is reported Ashe Juniper biomass that has not undergone the steam distillation process. This work demonstrates that the energy content of steam distillated Ashe Juniper can be extracted and the conversion to bio-oil is another potential use for Ashe Juniper woodchip waste. An economic model of Ashe Juniper biomass developed previously by Jua´rez and Daugaard was used to examine the economic impact of steam-distilled Ashe Juniper by simulating a 4,046-hectare (10,000 acre) Ashe Juniper energy plantation. It was found that bio-oil could be produced for as little as $5.20/GJ on a lower heating value basis if re-investment of profits made from the sale of essential oils extracted during the steam distillation process was assumed. Bio-oil from un-distillated Ashe Juniper could be produced for $13.21/GJ.