Disclosed is an apparatus and method for synchronously treating sewage and sludge through a step-feed partial nitrification coupling anaerobic ammonia oxidation process, belonging to the biological treatment field. Ammonia rich landfill leachate is firstly pumped into an aerobic reactor to realize partial nitrification process; exogenous surplus sludge coupling with partial nitrification reactor effluent are input to an anoxic reactor together for achieving integrated fermentation and denitrification process; finally, effluent from the anoxic reactor is pumped into an integrated autotrophic nitrogen removal reactor by a step-feed mode, the integrated reactor contains two main running units of aeration and anoxic stirring, ammonia is oxidized into nitrite in aeration stage, and the generated nitrite and ammonia contained in secondary influent are further removed through anammox process which operates stably and reliably, realizes efficient nitrogen removal from landfill leachate without external carbon source addition, and realizes the purpose of exogenous excess sludge reduction simultaneously.

Apparatus and associated methods relate to drying a wet coated seed material stream comprising an incoming wet granular biosolids stream mixed with a controlled size dried seed material recycling stream to produce a moist air and pellet stream, separating an uncontrolled size dried pellet stream from the moist air and pellet stream, diverting a recycle portion of the uncontrolled size dried pellet stream to be recycled, diverting the remainder of the uncontrolled size dried pellet stream to an outlet, resizing oversized pellets from the recycle portion of the uncontrolled size dried pellet stream to produce the controlled size dried seed material recycling stream, and mixing the controlled size dried seed material recycling stream with the incoming wet granular biosolids stream to produce the wet coated seed material stream. Oversized pellets may be selected using a screen. The oversized pellets may be resized using a crusher inline with the recycle stream.

Provided is a method for enhancing self-enrichment of anammox bacteria by nitrate-dependent denitrifying bacteria symbiotic metabolism, belonging to the field of biological wastewater disposal. Excess sludge from a municipal wastewater treatment plant is inoculated into an enhanced anammox bacteria self-enrichment system (a closed SBR (Sequencing Batch Reactor)). The method includes the following steps: taking sodium acetate as a carbon source, enriching nitrate-dependent denitrifying bacteria at first, and transforming nitrate into nitrite to provide a sufficient substrate for the growth of anammox bacteria; in turn, the enriched anammox bacteria provide nitrate for the nitrate-dependent denitrifying bacteria to grow.

An apparatus has a plurality of gas transfer membranes. The apparatus floats in water with the membranes submerged in the water. To treat the water, a gas is supplied to the membranes and is transferred to a biofilm supported on the membranes or to the water. Gas is also used to supply mixing or membrane scouring bubbles to the water. The mixing or scouring bubbles can be provided by a cyclic aeration or other gas supply system, which optionally provides gas at a variable pressure to the membranes in parallel or series with an aerator. Condensates can be removed from the membranes, and exhaust gasses from the membranes can be monitored, optionally through one or more dedicated pipes.

A saturated water generation device includes: a container in which an upper surface is open and a bottom surface and side surfaces are closed by a bottom plate and four side plates each having a rectangular shape in plan view; a water guide plate which is bent so as to form a shape in which an ovoid line in a side view is partially cut out, and is installed inside the container with an opening (a portion sandwiched between a pair of ends) facing upward; a nozzle that ejects water from above to an inner surface near the opening; a water supply pipe having a distal end to which the nozzle is connected; a water supply pump whose discharge port is connected to a proximal end of the water supply pipe; and an overflow pipe connected to a first drain port provided in the side plate near the bottom plate.

A process water distillation system (10) comprises an evaporator (18), a condenser (34), a compressor (28) configured to generate a desired pressure in at least a region of the process water distillation system (10) and to convey steam from the evaporator (18) to the condenser (34) during operation of the process water distillation system (10), an inert gas source (40) configured to supply inert gas to the process water distillation system (10), and a control device (48) configured to control the supply of inert gas from the inert gas source (40) to the process water distillation system (10) in such a way that, at least in certain operating phases of the process water distillation system (10), an oxygen concentration in the process water distillation system (10) does not exceed a permissible maximum value.

A process water distillation system comprises an evaporator, a condenser and a compressor configured to generate a desired pressure in at least a region of the system and to convey steam from the evaporator into the condenser during operation of the system. The condenser is in thermal contact with the evaporator so that, at least during certain phases of operation of the system, thermal energy released during condensation of steam conveyed into the condenser is transferred to a fluid in the evaporator. The system further comprises a concentrate collection area configured to receive concentrate produced during operation of the system and an energy source configured to supply energy to the process water distillation system. A control device is configured to control the supply of energy from the energy source to the system (10) in dependence on the progress of the distillation process in the system.

A system for on-line monitoring of a supercritical water oxidation (SCWO) process, the system including an SCWO reactor, a feedstock supply line which supplies a feedstock to the SCWO reactor, an oxidant supply line which supplies an oxidant to the SCWO reactor, at least one sensor which measures at least one parameter of the feedstock and the oxidant, and a controller which determines a Chemical Oxygen Demand (COD) and a Heating Value (HV) of the feedstock based on the at least one parameter, such that the controller adjusts the amount of the oxidant supplied to the SCWO reactor based upon the COD and the HV of the feedstock.