A nanobiocatalytic membrane for a filtration system is provided which includes a filtration membrane and a plurality of nanobiocatalyst nanoparticles associated with the membrane, each of the nanobiocatalyst nanoparticles including a core, a coating at least partially surrounding the core, and a plurality of nanobiocatalysts coupled to the coating. Each of the plurality of nanobiocatalysts includes an antibacterial nanoparticle comprising bismuth, and a quorum quenching agent coupled to the antibacterial nanoparticle. A nanobiocatalyst nanoparticle for use with a water purification system is also provided. A method of forming a nanobiocatalytic membrane for a filtration system and a method of using a nanobiocatalytic membrane in a filtration system are also provided.

An air sterilisation unit comprising a housing providing an air inlet and an air outlet and containing a filter module located between the air inlet and the air outlet, a UV-C treatment chamber located between the air inlet and the air outlet and containing at least one UV-C radiation source, and a ventilation system located between the air inlet, through the filter module and the UV-C treatment chamber and out of the housing through the air outlet, wherein the UV-C treatment chamber comprises an inlet end, an outlet end and a wall there between and the inlet end is closed with a first expanded polytetrafluoroethylene filter, the outlet end is closed with a second expanded polytetrafluoroethylene and the wall is provided with an expanded polytetrafluoroethylene liner, such that the UV-C radiation source is surrounded with expanded polytetrafluoroethylene for reflection of UV-C radiation within the chamber for destruction of pathogens in the air.

An air filter comprising a housing, a plurality of cyclonic-element arrays and a plurality of individual airflow paths is disclosed herein. The housing includes a first side configured to be arranged or otherwise exposed to an upstream side of a first airflow, and a second side configured to be arranged or otherwise exposed to a downstream side of the first airflow. In some embodiments, the plurality of cyclonic-element arrays may be organized in a parallel or approximately parallel arrangement within and/or supported by the housing. Further, the plurality of individual airflow paths may correspond to the plurality individual of cyclone elements in each array life.

An exhaust system (1) of an internal combustion engine, prior to a first heating-up of the exhaust system (1), has a particle filter (2) and an exhaust line (3) upstream of the particle filter (2). The exhaust system (1) has a carrier element (11) with ash-forming components or ash applied thereto. The carrier element (11) may be on a side of the particle filter (2) facing toward the exhaust line (3). Alternatively, the exhaust system (1) may have a catalytic converter (4) upstream of the particle filter (2), the carrier element (11) that with the ash-forming components or the ash may be applied to the catalytic converter (4).

A dust collector for an electric power tool includes a main body case, a dust box, a sliding portion, and a dust collecting route. The main body case includes an exhaust port, the main body case being configured to be installed on an electric power tool. The dust box internally includes a filter. The sliding portion is disposed on the main body case. The sliding portion has a front end on which a nozzle with a suction opening is disposed. The sliding portion is slidable in a front-rear direction. The dust collecting route is from the suction opening to the exhaust port passing through the filter. The main body case includes a guiding portion through which the sliding portion passes, and the guiding portion allows the sliding portion to project rearward when the sliding portion slides.

The present disclosure relates to a filter flushing device and a filter flushing method in which a filter can be flushed and which may include: a main body in which at least one filter can be mounted; a deionized (DI) water supply unit that can selectively supply a plurality of types of DI water having different temperatures to the filter mounted in the main body at desired time intervals, thereby flushing the filter; a drain unit that drains the DI water passing through the filter to the outside of the main body; and a control unit that is electrically connected to the DI water supply unit to apply a control signal to the DI water supply unit so that a temperature and a flow rate of the DI water supplied to the main body through the DI water supply unit can be controlled.

An ionization device may be configured to be portable, and to rest on a surface such as a floor or desk top. The ionization device includes an air-intake port, an ion generator, an ozone catalyst for removing at least some ozone from air, and an air discharge. Air enters the device through the air-intake port, and at least some of the air is ionized to remove particulates. The air is then moved past or through the ozone catalyst to remove at least some of the ozone from the air. A controller may be used to monitor particulates, temperature, humidity, and/or other relevant factors and/or to adjust the ionization level.

An exhaust gas treatment system comprising a first and a second structure being in fluid communication and defining a flow path of the exhaust gases, the second structure being supported by the first structure, the first structure comprising a first catalytic converter downstream a mixing chamber, the first catalytic converter having a fluid connection to an outlet of exhaust gases, the second structure including a filter unit housing removably connected to the first structure and to an inlet module by a filter unit housing fixing, the second structure defining a longitudinal axis, the filter unit housing including a filter unit, and the inlet module including a second catalytic converter and having a fluid connection to an inlet of exhaust gases, the filter unit housing and/or the inlet module being configured to allow its removal from the exhaust gas treatment system.

Systems and methods for increasing removal efficiency of at least one filter medium. In some embodiments, at least one oxidizing agent is introduced into the flue gas stream, so as to react SO2 with the at least one oxidizing agent to form sulfur trioxide (SO3), sulfuric acid (H2SO4), or any combination thereof. Some of the embodiments further include introducing ammonia (NH3) and or dry sorbent into the flue gas stream, so as to react at least some of the sulfur trioxide (SO3), at least some of the sulfuric acid (H2SO4), or any combination thereof, with the ammonia (NH3) and form at least one salt.

An exhaust aftertreatment system for an internal combustion engine includes an outer casing having an exhaust gas inlet and an exhaust gas outlet between which a fluid flow path for exhaust gases is provided, a selective catalytic reduction unit provided in the fluid flow path for reducing nitrogen oxides, a reductant dosing device for adding reductant to the exhaust flow upstream of the selective catalytic reduction unit, and a rotatable mixer device for mixing the reductant with exhaust gases upstream of the selective catalytic reduction unit, an air inlet valve provided upstream of the mixer device for introducing air into the fluid flow path, and an electric motor arranged for rotating the mixer device to create a suction of air into the fluid flow path via the air inlet valve.