The cleaning device (20) for cleaning a cylindrical roller (50), for example an anilox roller of a printing machine, includes a cleaning head (30) with a cleaning chamber (110), in which there is housed a mechanical cleaning member (60), and with which there are associated feeding members (70) for feeding a cleaning liquid into the cleaning chamber (110). The mechanical member (60) and cleaning liquid dispensed by the feeding members work in combination inside said cleaning chamber (110) to clean the lateral surface of the roller (50).

The present application provides a machine cleaning device. The machine cleaning device includes: a guide rail arranged next to a carrying platform of the machine main body, a support slidably mounted on the guide rail, a cleaning component mounted on the support, a driving device connected to the support in a transmission way, and a controller connected to the driving device; and when the cleaning component cleans the top surface of the machine main body, the controller controls the driving device to drive the support to move along the guide rail, so as to drive the cleaning component to clean the top surface of the machine main body in a direction away from the carrying platform. So that unexpected particles are reduced to fall on the carrying platform and contaminate the carrying platform during the cleaning process.

An optical fiber alignment assembly may comprise an alignment fixture including a groove configured to engage first and second optical fiber ferrules, a first clamping mechanism configured to selectively apply a force on the first optical fiber ferrule to constrain motion of the first optical fiber ferrule within the groove, and a second clamping mechanism configured to selectively apply a force on the second optical fiber ferrule to constrain motion of the second optical fiber ferrule within the groove.

A solar panel cleaning system includes a detection traveling vehicle configured to travel on a solar panel and detect dirt on the solar panel, a map generation part configured to generate a dirt map including a dirt position of the dirt on the solar panel, a cleaning path generation part configured to generate a cleaning path for performing cleaning of the solar panel, and a cleaning traveling vehicle configured to travel on the solar panel on the basis of the generated cleaning path and perform cleaning of the solar panel.

A lens inspection module comprises: a lens insertion station, at least one lens inspection station, and a lens removal station as well as a closed-loop transportation rail, a cuvette transportation shuttle with a plurality of inspection cuvettes, and a self-driving cleaning shuttle for cleaning the rail. Cleaning shuttle comprises a driving unit a cleaning head, a suction unit, and a tube connecting cleaning head and suction unit. Cleaning head is spaced apart from suction unit and driving unit in the transportation direction and is pivotally arranged about a pivot axis. Cleaning head may comprise a distance sensor for detecting the distance between cleaning shuttle and transportation shuttle. Driving unit is configured to change the speed of the self-driving cleaning shuttle when the distance between the cleaning shuttle and the transportation shuttle is shorter than a predetermined threshold distance.

A cleaning robot includes a supporting mechanism, cleaning mechanisms and a walking mechanism. The supporting mechanism is used for supporting the cleaning robot; the cleaning mechanisms are symmetrically arranged at the two ends of the supporting mechanism and can clean the surface of a photovoltaic panel; the walking mechanism is arranged in the middle of the supporting mechanism and can fix the cleaning robot to the surface of the photovoltaic panel and drive the cleaning robot to move on the surface of the photovoltaic panel; and the supporting mechanism can adjust the cleaning ranges of the cleaning mechanisms, so that the cleaning mechanisms at least have a first cleaning range and a second cleaning range, and the first cleaning range and the second cleaning range can be concentric circles. The cleaning robot is small and exquisite in structure and light. One person can operate multiple robots at the same time.

A vacuum rail and squeegee system, and a control system for an irregular surface cleaning system, an irregular surface cleaning system, process, and methods of use are presented. The cleaning system presented herein is designed for clearing surfaces of structures. More specifically, but without limitation, the present cleaning system is designed and configured to clean the surfaces, inside and outside, of wind turbines and the corresponding structure. More specifically, and without limitation, the present disclosure relates to a surface cleaner for cleaning surfaces. More specifically, and without limitation, the present disclosure relates to cleaning surfaces of an irregular surface. More specifically, and without limitation, the present disclosure relates to cleaning a surface of an irregular surface where the target surface is at an inconvenient altitude or location.

A handling equipment for a placement shelf of display panel is provided. The handling equipment includes a rack, a rotatable driving wheel and a cleansing device. The cleansing device is configured to cleanse the driving wheel. The driving wheel and the cleansing device both are disposed on the rack. The cleansing device contacts with the driving wheel. The driving wheel is configured to contact a bottom frame of the placement shelf of display panel. The driving wheel is disposed with a cleaning layer on the radial periphery of the driving wheel.

An apparatus for cleaning a controlled and regulated equipment, wherein the apparatus comprises a tool handle including a first handle portion removably connected to a second handle portion and a tool head frame pivotably connected to the second handle portion. The tool head frame further comprises a leading edge opposite a trailing edge and a first side edge opposite a parallel second side edge disposed between the leading edge and the trailing edge respectively wherein the leading edge and the trailing edge are non-parallel to each other—forming a trapezoidal shaped tool head frame. A tray including at least one compartment, a pad assembly and a cleaning solution wherein the pad assembly and the cleaning solution are disposed in the at least one compartment is provided. The pad assembly is movable within the at least one compartment between a first position and a second position so that the tool head frame is hands-free attachable to the pad assembly in the first position or second position and the tool head frame is hands-free detachable from the pad assembly in the second position.

An earth mount utility-scale solar photovoltaic array with modules on the ground. The site can have support regions with an elevation between −20 cm and 40 cm of the ground. Implementations may include elevations between −10 cm and 30 cm of the ground surface; more than one row of modules; connectors joining adjacent modules; modules flexibly joined in one or two dimensions; connectors joining 2-4 modules; connectors electrically bonding some modules to adjacent modules; contact points controlling a direction of a ray normal to a plane of the modules; a dc output, and a DC:AC output voltage ratio is 1.02, 1.9, 1.21.8, or 1.31.7. These or other implementations may configure the module arrangement such that the arrangement can withstanding wind speeds greater than 150 mph without containing stowing or extreme dampening functionality. Implementations of the described techniques may include solar arrays and related methods.