An in-site composting system for community kitchen waste is provided, which includes: a dump unit, configured to receive a kitchen waste; a power energy conversion unit, configured to convert a part of energy generated by a fitness equipment or a rocking handle into electrical energy, and output a remaining part of the generated energy directly as power, a biological conversion unit, configured to receive the kitchen waste fed by the dump unit and perform a composting and fermentation processing on the kitchen waste; an energy storage unit, configured to store the electrical energy generated by the power energy conversion unit and the solar panel; and a material outputting and returning unit, configured to be connected to the biological conversion unit, wherein the material outputting and returning unit is configured to output and return a material decomposed by the biological conversion unit.

System (100) and method for processing biomass. The system comprises a combined heat and power plant (102), an interface (114) for feeding biogas to a traffic fuel production unit, interfaces (114) to a district heating system (106a) and an electrical grid (106b), and a hydrolysis device (108), a digestion device (110), a dryer (116) and a heat recovery unit (112), which are operatively coupled for transferring heat, intermediate products and final products of the process, wherein raw biomass is received into the hydrolysis device (108), biomass processed by the hydrolysis device (108) is fed to the digestion device (110), biogas obtained in the digestion device (110) is fed to the traffic fuel production unit (104), heat is recovered from the hydrolysis device (108), biomass processed by the digestion device (110) is dried by the heat recovered from the hydrolysis device (108), heat is recovered from the dryer (116), heat recovered from the dryer (116) is fed to the hydrolysis device (108) to be used in pre-heating of the received raw biomass, heat recovered from the dryer (116) is fed to the district heating (106a), and production of electricity is fueled by the dried biomass from the dryer (116).

A method of using electricity to produce methane includes maintaining a culture comprising living methanogenic microorganisms at a temperature above 50 C. in a reactor having a first chamber and a second chamber separated by a proton permeable barrier, the first chamber comprising a passage between an inlet and an outlet containing at least a porous electrically conductive cathode, the culture, and water, and the second chamber comprising at least an anode. The method also includes coupling electricity to the anode and the cathode, supplying carbon dioxide to the culture in the first chamber, and collecting methane from the culture at the outlet of the first chamber.

Described herein are methods and systems that can provide independent energy generation as well as systems for the generation of other useful products, such as chemicals. In addition, the systems and methods can provide ways of harnessing the potential of biomass feedstock to generate of multitude of products including green crude, biogas, electricity, heat, fatty acids, biodiesel, ammonia, and chemical products. In many cases, the systems and methods herein utilize anaerobic microorganisms, including aquatic and ruminant organisms, to digest material and create products.

System and process are provided for producing and obtaining valuable products that are derived from microbial fermentation of C1-containing gaseous substrate process. More specifically, the disclosure provides schemes for the integration of a fermentation process with electrolysis process and C1-containing gaseous substrate generating process while achieving reduced carbon dioxide emission. The amount of carbon dioxide subject to the electrolysis process is based on the balance of raw material consumption of the microbial fermentation process.

Systems and processes of providing novel thermal energy sources for hydrothermal liquefaction (HTL) reactors are described herein. According to various implementations, the systems and processes use concentrated solar thermal energy from a focused high-energy beam to provide sufficient energy for driving the HTL biomass-to-biocrude process. In addition, other implementations convert biowaste, such as municipal biosolids and grease and food waste, to biocrude using anaerobic digesters, and a portion of the biogas generated by the digesters is used to produce the thermal and/or electrical energy used in the HTL reactor for the biomass-to-biocrude process. Furthermore, alternative implementations may include a hybrid system that uses biogas and solar radiation to provide sufficient thermal energy for the HTL reactor.

The present invention relates to the field of degradation with hyperthermophilic organisms, and in particular to the use of hyperthermophilic degradation to produce heat from a biomass. In some embodiments, a biomass is fermented in the presence of hyperthermophilic organisms to produce heat. The heat is used to heat a liquid which is used directly in a heat pump or radiant heat or to produce electricity or drive a steam turbine.

A portable renewable energy microgeneration system is disclosed. The system comprises one or more holding tanks that are configured to perform anaerobic digestion on waste in a multi-phase process using bacteria and a controller configured to automatically control the multi-phase process and to re-use the bacteria. The controller re-uses the bacteria by removing at least a portion of the liquid from the waste after anaerobic digestion is performed on the waste and using the at least a portion of the liquid to wet other waste and repeat the multi-phase process.

Various embodiments of the present invention pertain to methods for biological production of hydrogen. More specifically, embodiments of the present invention pertain to a modular energy system and related methods for producing hydrogen using organic waste as a feed stock.

The present invention relates to the field of degradation with hyperthermophilic organisms, and in particular to the use of hyperthermophilic degradation to produce heat from a biomass. In some embodiments, a biomass is fermented in the presence of hyperthermophilic organisms to produce heat. The heat is used to heat a liquid which is used directly in a heat pump or radiant heat or to produce electricity or drive a steam turbine.