An optical fiber cleaning assembly includes a cleaning tape, a first spool having the cleaning tape wound thereon, and a second spool onto which the cleaning tape is drawn. The optical fiber cleaning assembly further includes a drive mechanism for moving the cleaning tape from the first spool onto the second spool. A face of an optical fiber may be placed into contact with the cleaning tape, such that a portion of the cleaning tape wipes the face of the optical fiber as the drive mechanism moves the cleaning tape from the first spool onto the second spool.

An ultrasonic cleaning system comprises a cleaning tank containing a cleaning liquid, a moving and holding device configured to move a carrier into the cleaning tank and hold the carrier in the cleaning tank, and an ultrasonic wave generator mounted in the cleaning tank. A plurality of fiber optic ferrules are mounted on the carrier and are immersed in the cleaning liquid when the moving and holding device holds the carrier in the cleaning tank. The ultrasonic wave generator is adapted to emit an ultrasonic wave into the cleaning liquid to clean the fiber optical ferrules immersed in the cleaning liquid.

An optical connector cleaning tool includes: a tool body; and an extension that moves relatively with respect to the tool body. The extension extends out of the tool body and includes a head that presses a cleaning element formed with a tape-like adhesive element onto an optical connector. A relative movement of the extension with respect to the tool body carries the cleaning element to the head, and after carrying the cleaning element to the head, enables the cleaning element to contact the optical connector.

A spray nozzle, systems and methods for cleaning at least one optical fiber end face of an optical fiber connector. The nozzle includes a housing body with a first end portion and a second end portion. A discharge passage carries an atomized mixture of cleaning fluid and positively pressurized air from the first end portion to a discharge opening at the second end portion. A vacuum return passage communicates with the discharge passage proximate the second end portion. The return passage receives the atomized mixture of cleaning fluid and positively pressurized air as well as contaminants removed from the optical fiber end face. A portion of the atomized mixture of cleaning fluid and positively pressurized air is diverted from the discharge passage to control the amount of the atomized mixture being directed at the optical fiber end face.

A cleaning tool that cleans an optical connector includes an adhesive body that contacts an optical signal region of the optical connector where an optical signal enters and is emitted from the optical connector; and a base that holds the adhesive body. The base includes a first protrusion on a holding surface of a holding part that holds the adhesive body. The first protrusion is disposed at a rear side of a section of the adhesive body and is in contact with the optical signal region.

Various implementations of visual inspector attachments for fiber connector cleaners are disclosed. The example fiber optic inspection module includes a camera to capture an image of an end-face, a light source to illuminate the end-face, and a first mirror that reflects light from the light source to the end-face and includes a fixed point that allows the first mirror to pivot. Alternatively, an example fiber optic inspection module includes a camera to capture an image of an end-face, a light source to illuminate the end-face, and a first mirror that reflects light from the light source to the end-face and the first mirror moves in an upward direction.

Various implementations of fiber optic inspection tools with integrated cleaning mechanisms are disclosed. The fiber optic inspection and cleaning tool includes a housing, a cleaning system and an imaging system. The cleaning system includes a pay-off reel, a take-up reel, a spindle and a cleaning tape that travels off the pay-off reel, around the spindle, and onto the take-up reel. The imaging system includes a camera and a light source. The camera, spindle, and cleaning tape are aligned along a visual axis. The pay-off reel, take-up reel, camera and light source are all located within the housing.

The cable cleaning and rolling system combines an automated cleaning and winding system for industrial cables and the like with a water filtration system for recycling the water used to clean the cable. The cable cleaning and rolling system includes a hollow base, a feed drum and a receiving drum. The feed drum is adapted for releasably retaining and feeding the cable to be cleaned, and the receiving drum is adapted for receiving and rolling the cable after it has been cleaned and dried. At least one nozzle, for spraying cleaning water on the cable, at least one brush, for scrubbing the cable, and a blower, for drying the cable, are positioned between the feed drum and the receiving drum. Waste water from the cleaning is received within the hollow base, extracted therefrom, and delivered to a water filtration unit for recycling.

A cleaning device is provided for removing debris from an end surface of a fiber optic connector. The fiber optic connectors may be a Multi Push On (MPO) or Mechanical Transfer (MT). The end surface may have a one or more ferrules with a fiber optic glass cable. The cleaning device includes a housing with a first end open to a gel that adheres to debris. A second end of the housing may be releasably attached to a protrusion or handle to insert and remove the device from an adapter receptacle. The handle may be replaced with a plug frame and protrusion so the device may be inserted into the receptacle of the adapter. The device may be placed over the end surface of the fiber optic connector that is not inserted into an adapter receptacle.

A cleaning nozzle includes an outer housing having a central axis and an inner surface that defines an outer housing interior. An inner housing resides within the outer housing interior along the central axis and has an inner surface that defines an inner flow channel. The inner flow channel supports flow of the cleaning fluid and has a converging taper and a flow disrupter element. The nozzle assembly may include an adapter that receives a front end of the nozzle and that also holds a ferrule that supports an optical fiber having an end face. The nozzle assembly allows the nozzle to direct a jet stream of cleaning fluid to the ferrule end face and the fiber end face. The flow disrupter causes the jet stream to have a time-varying direction that enhances the cleaning of the ferrule end face and the optical fiber end face.