Because of the increasing trends in energy consumption and increased environmental awareness, greater focus has been placed on improvement and development of renewable energy sources. An already proven and accepted method is biogas production from anaerobic digestion at municipal wastewater treatment plants.In the waste water treatment process solid material and dissolved pollutants are separated from the water, forming a sludge. The sludge is separated from the process and stabilized during anaerobic digestion or aerobic aeration. Most often, mesophilic anaerobic digestion is used. Because of degradation by microorganisms, biogas with a high content of methane is formed during the digestion.

The biogas plant Kungsängens gård, owned by Uppsala Vatten och Avfall AB, produces biogas and biomanure from organic household waste, food processing waste and slaughterhouse waste. In year 2012, 4.4 million Nm3 of biogas were produced from 25 200 tons of waste. Before digestion all substrate is sanitized by pasteurization at 70°C in order to kill pathogens. Another method, integrated thermophilic sanitation (ITS), is of interest in order to decrease the energy demand. The method implies that the substrate is sanitized during ten hours in the digestion chamber, where the temperature is 52°C.

The biogas plant Kungsängens gård, owned by Uppsala Vatten och Avfall AB, produces biogas and biomanure from organic household waste, food processing waste and slaughterhouse waste. In year 2012, 4.4 million Nm3 of biogas were produced from 25 200 tons of waste. Before digestion all substrate is sanitized by one hour?s pasteurization at 70°C in order to kill pathogens. Another method, integrated thermophilic sanitation (ITS), is of interest in order to decrease the energy demand.

This thesis is   focused on identifying and documenting all   electrical equipment, such as devices, power lines / cables, and connectors in the facility and also on presenting a brief   technical description and information of the systems around the reactors.   Furthermore there will be a brief description of LabVIEW - which is a   graphical programming language- and which devices / elements   are programmed. For further notification, I am not   responsible for the programming of the devices in LabVIEW   which I have only used as a tool in my work. The plant   for production of biogas consists of four reactors   of which the third reactor (Lakbädden)   is connected to another reactor (UASB)   where they cooperate with each other.   The reactors are used for producing   biogas in the form of methane gas.The reactors I and II are   connected to, various electrical devices as, flow meters, temperature   sensors, frequency converter and   more.

Biogas is a gaseous fuel, rich in methane, produced through a biological route in an anaerobic digester. A gas engine generates combined heat and power, which can be used at the farm to reduce energy cost. The process also generates a digestate, with better utilization of nutrient compared to cattle manure. The aim of this study is to analyze the profitability of a farm-scale biogas plant for combined heat and power (CHP) at Wapnö. Wapnö is an agriculture company located in the southern part of Sweden.

Käppala wastewater treatment plant situated on the island of Lidingö northeast of Stockholm is running a project during 2004 and 2005 with the purpose to map out the capacity of anaerobic digestion in the digesters that treat primary and excess sludge. The purpose of this thesis work, which is part of that project, was to characterize the present anaerobic digestion process and to investigate its capacity to treat other organic wastes such as restaurant waste and waste from water works. To decide the potential of both methane and biogas production from different substrates batch laboratory tests were carried out. To imitate the anaerobic digestion process at Käppala continuous tests with small scale reactors were carried out. These reactors were later fed with restaurant waste.The batch laboratory tests showed that primary sludge had a potential biogas and methane production of 0,62 and 0,35 Ndm3/g VS respectively after 40 days of digestion.

Stockholm Gas AB säljer i huvudsak två olika produkter. Den ena är stadsgas och den andra är fordonsgas. Båda produkterna skall på sikt i huvudsak ha biogas som råvara. I dagsläget är det dock så att stadsgasen till största delen består av naturgas blandad med luft.Stockholm Gas AB har genomgått stora förändringar och står inför nya. År 2011 togs ett stort steg i Stockholm Gas klimat- och miljöriktiga utveckling.

Behovet av energisnålare och miljövänligare processer är stort i samhället i dag. Syftet med projektet var att ta fram energisnålare avfuktningsmetoder för biogas, som sedermera ersätter naturgas. Vidare var det önskvärt att undersöka möjligheten att avfukta gasen ytterligare för att undvika kondensering i ledningen under transportering.Energiberäkningar har genomförts, där nuvarande förbrukning ställts mot undersökta alternativ. Vidare beräknades, för alternativen, såväl dimensionering som preliminära investeringskostnader för nödvändig utrustning. Även miljöpåverkan undersöktes för varje metod.Rapporten visar på möjligheten att energieffektivisera processen och dessutom öka avfuktningen.

Scandinavian Biogas is involved in the planning of a combined ethanol and biogas factory in Karlskoga, Sweden. Besides biogas and ethanol large amounts of digester residues will be produced, about 450 000 liquid tonnes residue (~7,3 % Dry Substance( DS)). The objective of this thesis was to investigate possible uses of the residue from the biogas production process ScandgasEthanol developed by Scandinavian Biogas, and to derive a methodological approach how to evaluate and compare handling systems. Three systems where proposed and compared in this thesis; spreading of the untreated residue as fertilizer (system 1), dewatering to a higher DS content to reduce transportation before spreading as fertilizer (system 2) and production of a solid fuel by dewatering and drying the residue (system 3). The general conditions for the proposed systems were investigated in terms of practical viability, economical aspects, environmental impact and energy inputs/outputs.

Vi lever i en värld som konsumerar en allt större mängd energi. Att minska den icke förnyelsebara energianvändningen är en mycket viktig del för ett långsiktigt hållbartsamhälle. Sjöstad är ett av flera reningsverk i Sverige som rötar avloppsslam för att utvinna ett av framtidens bränslen; Biogas. Framställningen av biogas sker genom anaerob nedbrytning, en känslig process som lätt störs av yttre faktorer, som temperatursvängningar och förändringar av substratsammansättning. För att anaerob nedbrytning ska fungera optimalt krävs exakt rätt koncentrationer av näringsämnen i reaktorerna.I detta projekt har en rad olika mikronäringsämnen, som metaller, salter och vitaminer testats för att se om en tillsats av något av dessa kan öka Sjöstads biogasproduktion.

Biogas har anva?nts som fordonsbra?nsle i Sverige sedan bo?rjan av 90-talet som ett fo?rnyelsebart alternativ till naturgas. Fo?rst till bussflottor och sedan slutet av 90-talet a?ven till personbilar. Biogasproduktionen i Sverige har sedan slutet av 90-talet varit omkring 1,5 TWh per a?r.

Det har sedan bilens uppkomst funnits samhällsdebatter kring vilket bränsle som är mest passande. Trots att fossila bränslen dominerar som fordonsbränsle, har debatten om alternativa bränslen pågått under en längre tid. Syftet med denna uppsats är att undersöka en del av denna debatt. Inriktningen är fokuserad på el och biogas som alternativa bränslen i Sverige. Ett antal debattartiklar ur tidsskrifter har valts ut och analyserats med en diskursanalytisk metod.

This thesis is made by Carl Persson and Alejandro Saavedra for Gryaab. Gryaab is Gothenburg?s water processing plant and produces about 60 GWh biogas annually with a flow around 1150 Nm3/h. Gryaab wants to research their possibilities to become independent with electrical energy and the possibilities to enrich, upgrade biogas. The use of methane rich gases like biogas and natural gas is today low in Sweden compared to major parts of the world.

One of Sweden?s sixteen national environmental objectives strives to decrease the impact on the climate. By 2020, green house gas emissions should be 40 % less compared to the levels of 1990 and a minimum of 50 % of the energy consumption should come from renewable energy sources. Because of this there is a great need of increasing the production of renewable energy. This is where biogas comes in as a competitive alternative.

Organic material used for biogas production can also undergo other treatments. The emissions and impact from the different treatments are evaluated in this environmental assessment, with a focus on energy and climate. The materials included in the study are organic household waste, slaughterhouse waste and liquid manure. Other than biogas production, the possible treatments for organic household waste and slaughterhouse waste are incineration and composting, and for liquid manure storing and spreading. The analysis is based on data and information from current and relevant literature, and relates to the conditions in the Swedish energy system.