A coating device includes a head, a wiping mechanism, an arm, and a controller. The head includes a nozzle surface for discharging a coating material. The wiping mechanism wipes the nozzle surface. The arm holds the head. The controller controls movement of the head via the arm. The controller relatively moves the head with respect to the wiping mechanism to wipe the nozzle surface.

A cleaning apparatus that cleans a detection surface of a detection element, comprises an attachment to which a detection apparatus including the detection element can be attached, a communication unit configured to communicate with the detection apparatus, a cleaning unit configured to clean the detection surface of the detection element, and a control unit configured to control a driving unit of the detection element included in the detection apparatus through the communication unit. When cleaning by the cleaning unit, the control unit controls the position of the detection element by driving the driving unit through the communication unit.

A lens and/or a view screen of an electronic device having at least one case can be cleaned by wiping the view screen with a cleaning component wherein the cleaning component is configured to selectively couple to the at least one case or some other substrate using a magnetic attractive force. The cleaning devices may have secondary applications such as securing fly fishing lures, activating or deactivating a device having a magnetic switch, or preventing sunglasses from sinking. They may also be manufactured without a cleaning component for use with the secondary applications.

A wipe article includes a substrate, a cationic coating disposed on a surface of the substrate, distributed throughout the substrate, or both. The cationic coating contains a guanidinyl-containing polymer that is crosslinked and bound to the substrate. The substrate includes sponge, nonwoven fabric, or woven fabric. The wipes are useful for removing microorganisms from a microorganism-contaminated surface and also for reducing re-contamination of the cleaned surface or transfer to another surface of the removed microorganisms.

A vehicle cleaning device removes an extraneous object collected on a cleaning subject of a vehicle. The vehicle cleaning device includes: a cleaning liquid supply device mounted on the vehicle; and a wiper device including a wiper driver and a wiper blade. The wiper driver includes a linear movement portion that produces a linear movement based on supply of a cleaning liquid that is pressure-fed from the cleaning liquid supply device, and a movement converter that converts the linear movement into a pivoting movement. The wiper blade is arranged to be contactable with the cleaning subject. The wiper device is configured to cause the wiper blade to perform a reciprocal wiping operation based on the pivoting movement of the movement converter.

The present invention is to provide a method for producing a laminate having excellent adhesion properties. An embodiment of the present invention is a method for producing a laminate, the method including: a step 1 of dry-treating a surface A of a plastic to obtain a dry-treated plastic having a surface B that has been dry-treated; a step 2 of wiping the surface B with a cleaning tool containing a composition for wiping, the composition containing at least one solvent selected from the group consisting of water and polar solvents, and a silane coupling agent, to obtain a cleaned plastic having a surface C that has been wiped with the cleaning tool; and a step 3 of applying at least one selected from the group consisting of adhesives and primers on the surface C to obtain a laminated body.

A method for the removal of mycotoxins from a space associated with a built environment is disclosed. The method may include one or more of the steps of: filtering air within the space using a first filter including a High-Efficiency Particulate Air (HEPA) filter and a second filter including a carbon filter; and, applying a cleaning product including a high alkaline product to one or more surfaces proximate the space.

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.

Provided is a substrate cleaning apparatus including: a substrate support mechanism configured to support a substrate; and a roll-type first cleaning member configured to clean a first surface of the substrate by rotating while being in contact with a bevel and/or an edge of the first surface of the substrate, wherein a rotation axis of the first cleaning member is in parallel with the substrate, and the first cleaning member has a large diameter portion and a small diameter portion.