June 15th, 2014
A novel Upflow Anaerobic Solid State (UASS) reactor was used for biogas production from fibrous feedstock. Digestate from UASS reactor was hydrothermally carbonized into HTC biochar in a pressurized batch reactor. The integration of the two bioenergy concepts was applied in this study to increase overall bioenergy production.
There are four degradation steps in any anaerobic digestion. First polysaccharides are hydrolyzed into monomers. The monomers convert into low carbon fatty acid lactates and alcohols by agenesis.
In a ketogenesis. The product from Agenesis convert into and format. The last step is myogenesis, where Metagenic microorganisms produce methane from Aceto SSIS product.
Traditional anaerobic digestion of solid biomass is a time and energy consuming process. However, a novel upflow and aerobic solid state reactor has every potential to overcome the shortcomings. The significant advantages of this type of reactor is the spontaneous, solid liquid separation.
Also, the liquid circulation can eliminate the expensive steering Hydrothermal carbonization is a thermochemical treatment process where we waste biomass is heated at 200 to 260 degrees Celsius at water saturation pressure 4.5 to six hours. Subcritical water under this condition is very reactive. As a result, Hemi Cellose, along with other extractives, degrade around 180 to 200 degrees Celsius while cellulose reacts around 220 to two 30 degrees Celsius and lignin remains in art HTC Biochar.
The solid product of HTC is very fryable, hydrophobic, and stable. It has a calorific characteristics similar to lignite coal. The aim of the work was to combine these two bioenergy producing processes together.
In this video, we will show the working principle and operation of a novel UASS reactor for biogas production. Later, we will also show the hydrothermal carbonization of digested for biocore production For an aerobic digestion. A 39 liter UASS reactor were used five to 65 millimeter long.
Raw wheat straw chops are fed. The organic dry matter content of the feedstock was 85.9%while the crude fiber fraction was 46.3%The UASS reactors were made of stainless steel with an inspection window made of acrylic glass. A 30 liter anaerobic filter was combined with each 39 liter UASS reactor.
Each anaerobic filter was filled with 325 polyethylene biofilm carrier. The biofilm carrier had a surface area of 305 meters square per meter cube high dolf pump drive 5 2 0 1 was used in both mesophilic and thermophilic condition. For the process liquid, the heating buds were set at the desired reactor temperature level for daily feeding of the UASS reactors.
120 grams of wood straw are weighed. The UASS feeding tube is opened and the stump removed. The wood straw is filled into the diagonal feeding tube and pushed into the reactor's bottom.
The ceiling surface is clinged to be gas tight and the feeding tube is closed. The pumps run continuously conveying 1.2 liters per hour of process leaked through the reactor system. The biogas composition is measured regularly using the industrial biogas analyzer.
Approximately three kilogram of digested are removed once in a week. Samples of process, liquid and digested were analyzed in a weekly basis for their chemical properties. A par 18 liter 4 5 5 5 series is tiered reactor with a par 4 8 4 8 controller was used for the HTC experiments.
Spec view 3 2 8 4 9 software package was used in this study. Straw digested was weighed. The same balance was used to measure 10 kilogram of water.
Both digested and water were fed into the vessel before NU medically closing. The reactor content was manually steered to prevent the blockage of the propeller steer. The reactor was closed and secured by the crosswise.
Tighten the bolt with the force of 50 Newton meter. The reaction conditions were set in this particular experiment. The temperature was set for 230 degrees Celsius with a heating rate two degrees Celsius per minute and hold the temperature for six hours.
After cooling phase, it steered switch off and the gas was collected in a 20 liter gas bag. The slurry was drained through a high pressure, high temperature ball valve. The fluid was collected and filtered.
The produced biochar was teared. The wet biochar is placed into a 105 degrees celsius oven. A vari EL three elemental analyzer was used in this work.
In a sample pan, 30 milligram of tungsten six oxide was weighed. Five to 10 milligram of dry sample was put into the sample pan. Mix it and wrap it.
The sample pan Is placed into a vari EL auto sampler. The analyze is started and the data is stored in a computer. The maximum methane yield was 270.4 liter per kilogram for thermophilic and 216.9 liter per kilogram for mesophilic operation.
The biogas contained between 41 to 61%of methane, and rest is carbon dioxide. Dry digested looks similar to the dry straw, only a bit darker in color. The fibrous structure is destroyed in the HTC biochar.
In the absence of fibrous structure, the HTC biochar become fryable. It barely require any pressure to pulverize it. HTC biochar is very hydrophobic.
It can stay in contact with water for a prolonged time. If one kilogram of raw straw is hydrothermal carbonized, the HTC biochar will have the potential of 11 megajoule. But with the combination process, a total of 12.1 mega bioenergy can be yield.
Anaerobic Digestion has the energy yield of 20 to 25%While with the combination of HTC, the energy yield can reach up to 70%
This study explores the integration of a novel Upflow Anaerobic Solid State (UASS) reactor for biogas production with hydrothermal carbonization (HTC) of digestate into biochar. The research aims to enhance bioenergy production from fibrous feedstock, demonstrating the potential of combining these two bioenergy processes.
This study demonstrates a novel integration of anaerobic digestion and hydrothermal carbonization to enhance bioenergy yield from lignocellulosic biomass, offering a pathway to improve renewable energy output from agricultural residues. The combined approach increases energy recovery by over 60% compared to anaerobic digestion alone, supporting de-risking of biomass conversion technologies in early-stage biofuel development. Such hybrid thermochemical-biological platforms may inform portfolio decisions in sustainable energy R&D by improving predictive confidence in feedstock valorization.
The method positions anaerobic digestion as a upstream biogas generation step and hydrothermal carbonization as a downstream valorization step for digestate, creating a coupled biorefinery workflow applicable to lignocellulosic feedstock screening.