A mobile microalgae harvesting apparatus is disclosed. In one embodiment the mobile microalgae harvesting apparatus includes a harvesting boom coupled to a harvesting vessel, where the harvesting boom skims a microalgae mixture of microalgae and water from a surface of a body of water down to a predetermined depth below the surface. In the embodiment, the mobile microalgae harvesting apparatus also includes a separator aboard the harvesting vessel that separates water from the microalgae mixture and a microalgae collector that collects microalgae from the separator, wherein the microalgae collector deposits the collected microalgae on a transfer vessel coupled to the harvesting vessel. A mobile microalgae harvester and a system for harvesting microalgae are also disclosed.

A mobile microalgae harvesting apparatus is disclosed. In one embodiment the mobile microalgae harvesting apparatus includes a harvesting boom coupled to a harvesting vessel, where the harvesting boom skims a microalgae mixture of microalgae and water from a surface of a body of water down to a predetermined depth below the surface. In the embodiment, the mobile microalgae harvesting apparatus also includes a separator aboard the harvesting vessel that separates water from the microalgae mixture and a microalgae collector that collects microalgae from the separator, wherein the microalgae collector deposits the collected microalgae on a transfer vessel coupled to the harvesting vessel. A mobile microalgae harvester and a system for harvesting microalgae are also disclosed.

A filter press (100) is described comprising: a plurality of filtration chambers (155) each of which is delimited by two mutually facing filtering septa (140, 145) interposed between a pair of containment plates (105), a movement apparatus adapted to move each pair of containment plates (105) between a closed configuration and an open configuration, an inlet hydraulic circuit of the liquid to be filtered, an outlet hydraulic circuit of the filtered liquid, and a washing robot (400) adapted to wash the filtering septa (140, 145) that delimit each filtration chamber (155), wherein said washing robot (400) comprises: a trolley (405) adapted to move along a longitudinal direction (A) with respect to the containment plates (105), a bar (445) installed on the trolley (405) and movable relative thereto in a transverse direction with respect to the longitudinal direction (A), and a plurality of nozzles (450) installed on said bar (445) to dispense jets of a washing liquid toward said filtering septa (140, 145), the filter press further comprising: a plurality of identification codes, each of which is fixed to at least one respective filtering septum (140, 145), a device for detecting said identification codes installed on the trolley (405) of the washing robot (400), at least one image acquisition device (600) installed on the bar (445) of the washing robot (400) to acquire images of said filtering septa (140, 145), and an electronic processing unit connected to the identification code detection device and to the image acquisition device (600).

A filter (20) configured to separate the solid components and the liquid components from a slurry. The filter (20) includes a plurality of filter plate assemblies (46) that cooperate to define a plurality of filter chambers (70), each defining a perimeter (96) having an open section (98) when the filter plates (68) are in a closed position relative to one another. Each filter plate assembly (46) includes a closure (104) configured to close the open section (98). Preferably, the closures (104) are movable to an open position to permit a particulate cake to be removed from the filter chambers (70) without separating the filter plates (68).

A filter (20) configured to separate the solid components and the liquid components from a slurry. The filter (20) includes a plurality of filter plate assemblies (46) that cooperate to define a plurality of filter chambers (70), each defining a perimeter (96) having an open section (98) when the filter plates (68) are in a closed position relative to one another. Each filter plate assembly (46) includes a closure (104) configured to close the open section (98). Preferably, the closures (104) are movable to an open position to permit a particulate cake to be removed from the filter chambers (70) without separating the filter plates (68).

A filter (20) configured to separate the solid components and the liquid components from a slurry. The filter (20) includes a plurality of filter plate assemblies (46) that cooperate to define a plurality of filter chambers (70), each defining a perimeter (96) having an open section (98) when the filter plates (68) are in a closed position relative to one another. Each filter plate assembly (46) includes a closure (104) configured to close the open section (98). Preferably, the closures (104) are movable to an open position to permit a particulate cake to be removed from the filter chambers (70) without separating the filter plates (68).

A mobile microalgae harvesting apparatus is disclosed. In one embodiment the mobile microalgae harvesting apparatus includes a harvesting boom coupled to a harvesting vessel, where the harvesting boom skims a microalgae mixture of microalgae and water from a surface of a body of water down to a predetermined depth below the surface. In the embodiment, the mobile microalgae harvesting apparatus also includes a separator aboard the harvesting vessel that separates water from the microalgae mixture and a microalgae collector that collects microalgae from the separator, wherein the microalgae collector deposits the collected microalgae on a transfer vessel coupled to the harvesting vessel. A mobile microalgae harvester and a system for harvesting microalgae are also disclosed.

A mobile microalgae harvesting apparatus is disclosed. In one embodiment the mobile microalgae harvesting apparatus includes a harvesting boom coupled to a harvesting vessel, where the harvesting boom skims a microalgae mixture of microalgae and water from a surface of a body of water down to a predetermined depth below the surface. In the embodiment, the mobile microalgae harvesting apparatus also includes a separator aboard the harvesting vessel that separates water from the microalgae mixture and a microalgae collector that collects microalgae from the separator, wherein the microalgae collector deposits the collected microalgae on a transfer vessel coupled to the harvesting vessel. A mobile microalgae harvester and a system for harvesting microalgae are also disclosed.

An elongated scraper profile is provided, preferably for a dewatering device that serves the purpose of dewatering sludge. The scraper profile features a lip section extending in the direction of the longitudinal extension of the scraper profile, which serves the purpose of scraping sludge components from a screen surface. The scraper profile features a fastening section extending in the direction of the longitudinal extension, which serves the purpose of fixing the scraper profile with the assistance of a retainer assembly. The scraper profile also features an intermediate section connecting the lip section and the fastening section, whereas the intermediate section is flexibly formed in a direction running perpendicular to the longitudinal extension, such that the lip section is moveable in the direction of the fastening section.

An elongated scraper profile is provided, preferably for a dewatering device that serves the purpose of dewatering sludge. The scraper profile features a lip section extending in the direction of the longitudinal extension of the scraper profile, which serves the purpose of scraping sludge components from a screen surface. The scraper profile features a fastening section extending in the direction of the longitudinal extension, which serves the purpose of fixing the scraper profile with the assistance of a retainer assembly. The scraper profile also features an intermediate section connecting the lip section and the fastening section, whereas the intermediate section is flexibly formed in a direction running perpendicular to the longitudinal extension, such that the lip section is moveable in the direction of the fastening section.