The disclosure relates to a cleaning installation for cleaning a component, preferably a motor vehicle body component, in particular laterally along a wet partial region of the component, with a cleaning station, a conveyor device for transporting the component through the cleaning station and a first cleaning apparatus for, preferably large area, cleaning the component. The cleaning installation is characterized in particular in that it comprises a multiaxial robot which comprises a second cleaning apparatus for, preferably sharp-edged, cleaning the component and which is adapted to guide the second cleaning apparatus laterally along a partial region of the component. The disclosure also comprises a corresponding cleaning method.

In an example of the disclosure, a system to service a print blanket includes a rotatably mounted endless cleaning surface (ECS), a doctor blade, a heating element, and a container. The ECS is to carry a polymeric material and positioned to engage the print blanket. The doctor blade is disposed in relationship to the ECS and to a container to scrape a portion of the polymeric material from the ECS into the container. The heating element is to heat the container. The container is positioned to collect the scraped portion of polymeric material, and make heated polymeric material available to be picked up by the ECS as the ECS is rotated adjacent to the container.

The invention relates to a system for cleaning modular belts, characterized in that it comprises a support structure configured to be mounted and dismounted from the structure of a modular-belt conveyor, wherein a plurality of cleaning stations are mounted on the support structure, said cleaning stations consisting of: (a) a first surface cleaning station consisting of at least one roller with cleaning flaps disposed crosswise on the modular belt; (b) a cleaning preparation station consisting of at least one transverse duct disposed in an elevated manner with a plurality of ejection nozzles distributed along the length of the at least one duct and along the width of the modular belt in order to sprinkle water in the form of a spray directly on the modular belt; (c) a pre-cleaning station comprising a system of at least one self-adjustable plastic scraper; (d) a second surface cleaning station consisting of at least one pair of rollers with cleaning flaps, one being placed on the upper part of the modular belt and the other on the lower part thereof; (e) a deep-cleaning and sanitization station consisting of a system of rotary steam-spraying heads connected to a dry steam generator; and (f) a station for drying with warm air, formed by at least two air turbines with an elevated transverse diffuser.

A cleaning system and method can include a cleaning device including a soaking tank configured to accommodate cleaner; and a filtering device configured to filter a first substance being a mixture of the cleaner and mask residue in the soaking tank. The filtering device includes a sucking apparatus including an sucking port for sucking the first substance; a spraying apparatus, including a spraying port oriented a region that the sucking port is capable of sucking in a bottom of the soaking tank, the spraying port being configured to spray liquid or gas to flush the bottom of the soaking tank; and a filtering apparatus connected to the sucking apparatus to receive and filter the first substance sucked by the sucking port.

A cleaning system and method can include a cleaning device including a soaking tank configured to accommodate cleaner; and a filtering device configured to filter a first substance being a mixture of the cleaner and mask residue in the soaking tank. The filtering device includes a sucking apparatus including an sucking port for sucking the first substance; a spraying apparatus, including a spraying port oriented a region that the sucking port is capable of sucking in a bottom of the soaking tank, the spraying port being configured to spray liquid or gas to flush the bottom of the soaking tank; and a filtering apparatus connected to the sucking apparatus to receive and filter the first substance sucked by the sucking port.

A cleaning equipment includes a housing, a rolling brush, a spraying device, a dirt storage container, and a baffle plate. A bottom portion of the housing defines a dirt suction cavity. The housing defines a dirt suction channel including a dirt inlet opening and a dirt outlet opening. The dirt inlet opening communicates with the dirt suction cavity. The dirt outlet opening communicates with the dirt storage container. The rolling brush is mounted in the dirt suction cavity and partially extends out of the dirt suction cavity. The spraying device is positioned in the dirt suction cavity. The spraying device and the dirt inlet opening are arranged at intervals in a rotational direction of the rolling brush. The baffle plate connects to a sidewall of the dirt suction cavity. The baffle plate is positioned between the spraying device and the dirt inlet opening in the rotational direction.

A cleaning assembly for cleaning a surgical instrument includes a first cleaning segment and a second cleaning segment. The first and second cleaning segments present a respective first and second cleaning interface configured to be contacted by a first surgical instrument. The first and second cleaning segments collectively define an instrument receiving channel sized and shaped to receive therein a second surgical instrument to thereby secure the first and second cleaning segments to the second surgical instrument. At least one buffer layer is disposed on an inside surface of one or both the first and second cleaning segments, the buffer layer positioned so as to contact the second surgical instrument when the second surgical instrument is positioned within the instrument receiving channel. At least one tab extends from the cleaning assembly, the tab providing an interface for a user to grasp the cleaning assembly.

In one example, a system to clean imaging oil from a cleaning station in an LEP printer includes an electrode plate, an electrode belt rotatable in a loop past the electrode plate, a channel to carry unfiltered imaging oil from the cleaning station between the electrode plate and the electrode belt, and a voltage source operatively connected to the electrodes to establish an electric field that causes waste in the imaging oil between the electrodes to attach to the belt.

A residue scraper is provided, which includes a machine frame, which is provided with a clamping unit for fastening a material holder; a scraper unit for cleaning residues on a to-be-cleaned surface of the material holder, and a driving unit that drives the scraper unit to reciprocate along a long side direction of the material holder. In the present invention, the scraper unit is driven by the driving unit to scrape off the residues, thereby achieving a high efficiency to remove the residues.

A rinsing device for rinsing a blue film at the bottom of a wafer, including: a base; a water tank; at least one drum disposed in the water tank and partially exposed and vertically protruded from the water tank; at least one drum driver; two vertically-movable scraper sets disposed at the base, flanking the water tank, and each having a scraper, a water collection chamber and a vertically-movable driver, with the scraper disposed above the water collection chamber, the water collection chamber disposed at the vertically-movable driver, and the vertically-movable driver disposed at the base and adapted to drive the water collection chamber and the scraper moving vertically; and a water tray disposed at the base, positioned at the water tank, and positioned below the two scrapers and the two water collection chambers.