A Multi-Stage Wastewater Treatment and Hydroponic Farming Device comprises a compact basin, a moving bed biofilm reactor (MBBR), a modified wetland material, at least one microbial fuel cell (MFC) and a distributor. The MBBR and modified wetland material are disposed within the basin. Openings in the distributor retain hydroponic plants. In one example, wastewater enters through the MBBR which performs primary treatment of wastewater. Treated wastewater is further treated by modified wetland material and the MFC which generates electrical energy that supplies other components. Treated wastewater is pumped through the distributor and processed by hydroponic plants which extract growth inducing nutrients from the treated wastewater. Resultant water treated by the device is selectively recycled through various parts of the device or extracted from the device and used for other purposes. In one example, multiple devices are deployed in an area thereby providing self-sustaining, efficient water treatment and farming functionality.

A microbial fuel cell (100) includes: a positive electrode (10, 10A); a negative electrode (20) that holds microorganisms; and an electrolysis solution (70). The positive electrode includes: an electric conductor layer (1): a porous body layer (2) that is laminated on the electric conductor layer and supports a catalyst (3) therein; and a water-repellent layer (4) that is laminated on a surface (1b) of the electric conductor layer, which is opposite of a surface (1a) thereof in contact with the porous body layer, or a surface (2b) of the porous body layer, which is opposite of a surface (2a) thereof in contact with the electric conductor layer. Then, the porous body layer and the negative electrode are immersed in the electrolysis solution, and at least a part of the water-repellent layer is exposed to a gas phase (90).

The invention relates to a microbial fuel cell arrangement comprising a cell reactor. The cell reactor comprises a membrane, which has an active surface and a support surface, as well as a pore size of ?10 nm and/or a divalent ion rejection of ?50%; an anode and a cathode, which are connected with each other through an external electrical circuit; an influent inlet for liquid medium arranged at the active surface side of the membrane and at least one permeate outlet arranged at the support surface side of the membrane; an influent line connected to the influent inlet; a concentrate outlet, arranged at the active surface side of the membrane and connected to a concentrate line; and pressurisation means for creating pressure difference between the active surface side and support surface side of the membrane. The invention relates also to a method for operating a microbial fuel cell.

A system and apparatus for biomethanation and removing carbon dioxide from the methane comprises (a) a primary anaerobic digester adapted and arranged to generate a biogas mixture comprising methane and carbon dioxide from organic materials; (b) an electrochemical reactor adapted and arranged to capture carbon dioxide from the biogas as bicarbonate and to generate hydrogen by electrolytic water slitting, and (c) a biomethanation reactor adapted and arranged to convert the bicarbonate and hydrogen from the electrochemical reactor to methane. The electrochemical reactor also acidifies a saline process stream from the biomethanation reactor and returns the acidified process stream back into the biomethanation reactor for pH control in the biomethanation process.

The disclosure relates to a staggered electrode bio-electro-Fenton groundwater circulation well system, including a groundwater circulation well, a water pumping and injecting assembly and an in-well bio-electro-Fenton assembly. The water pumping and injecting assembly is configured to realize water pumping and injection between different screening sections of the groundwater circulation well. The bio-electro-Fenton assembly arranged in a first screening section of the groundwater circulation well includes at least one electrode device. A cathode and an anode of the electrode device form a spatially staggered arrangement according to different distribution areas. According to the disclosure, the spatially staggered arrangement of the cathode and the anode, the influence of oxygen on an anaerobic environment of an anode chamber in the electrode device is greatly reduced while ensuring the cathode takes oxygen as an electron acceptor, and the constructed bio-electro-Fenton system can accelerate the decomposition of organic pollutants in the groundwater circulation well.

An electrode includes a first diffusion layer (11) having water repellency and functioning to diffuse oxygen, and a second diffusion layer (13) supporting a catalyst layer (30) thereon and functioning to diffuse oxygen. The electrode further includes an electrically conductive layer (12, 15) including a metal material (20, 21) and an oxygen-permeable material, and interposed between the first diffusion layer and the second diffusion layer. A fuel cell (100) and a water treatment equipment each include: an anode (3); an ion transfer layer (4) having proton permeability; and a cathode (1, 2) being the electrode described above, and separated from the anode with the ion transfer layer interposed therebetween.

An aquarium bacteria management device may include a tank configured to contain a fluid and a light source configured to illuminate the tank. Electrodes may extend into the tank and be spaced apart from one another. The electrodes may introduce a first electric current through the fluid between the electrodes. A photovoltaic panel may be positioned to receive illumination from the light source and to convert the illumination into a second electric current in order to provide the first electric current to the electrodes.

A fuel cell system (100) comprises: a plurality of cell units including a first cell unit (10A) and a second cell unit (10B) positioned below the first cell unit (10A) in the vertical direction; and at least one connection portion including a first connection portion (20A) for connecting the first cell unit (10A) and the second cell unit (10B). In the fuel cell system (100), the cell units each have at least one electrode cell (2) equipped with: a processing bath (3) having a flow path (8) for circulating a liquid to be processed; a liquid supply inlet (11A, 11B) for supplying the liquid to be processed to the flow path (8); and a liquid discharging outlet (13A, 13B) for discharging the liquid to be processed from the flow path (8). The first connection portion (20A) has: a connection path (9) for circulating the liquid to be processed discharged from the liquid discharging outlet (13A, 13B) of the first cell unit (10A) to the liquid supply inlet (11A, 11B) of the second cell unit (10B); and an atmospheric pressure adjustment portion for suppressing atmospheric pressure variations caused by the movement of the liquid to be processed in the connection path (9).

The invention relates to bio-electrochemical systems for treating wastewater, and sour gas produced by anaerobic digestion of organic material. The invention further relates to novel anode/cathode pairing schemes, and electric and hydraulic architectures for use in bio-electrochemical systems.

An electrode assembly includes a hollow member having a hollow portion, an oxygen supply portion that supplies oxygen to the hollow portion, and an oxygen permeable portion that allows permeation of oxygen supplied to the hollow portion. Moreover, the electrode assembly includes: an electrode that is provided on an outside of the hollow member in the oxygen permeable portion and is composed by laminating a water-repellent layer having oxygen permeability and an electrically conductive layer on each other from the oxygen permeable portion side; and a buffer member that is provided in the hollow portion and has pressure resistance. Then, the electrode assembly is provided with air permeability from the oxygen supply portion to the oxygen permeable portion. A microbial fuel cell includes: the electrode assembly; and a negative electrode that supports microorganisms.