The invention pertains in general to a latching mechanism for maintaining desired friction levels on an optical disc in an optical disc restoration device. In particular the invention pertains to devices, systems and methods for easily maintaining friction levels between pads and an optical disc in an optical disc restoration device for ease of adjusting friction settings during quality control, repair operation or when optimization settings are being set in an optical disc restoration device by a user.

A method for chemically destroying magnetic data carriers. Recorded data are irretrievably eliminated and cannot be re-read. The carriers include aluminium or its alloys and ferromagnetic materials. They undergo a digestion reaction with an aqueous solution of a digesting mixture including: a) hydrochloric acid and (V)nitrate of one or more alkali metals, alkaline earth metals, rare earth metals and ammonium; or b) nitric(V) acid and chloride of one or more alkali metals, alkaline earth metals, rare earth metals and ammonium. The product of the reaction is an aqueous solution having aluminium hydroxide and chlorides and (V)nitrates of metals contained in the ferromagnetic metals and gaseous products of the reaction. Acidic salt solutions are utilized in a sewage treatment plant. Gaseous products including hydrogen and nitrogen oxides, after diluting with nitrogen, are directed to the atmosphere through an absorption system.

The invention relates to devices, systems and methods for restoring optical discs, including CD's, DVD's and Blu-ray discs. The invention provides an easy to use device for user's to repair optical discs without having to clean or remove rotating pads in the device between uses for the life of the pads of about 84 cycles.

A cleaning head and methods for removing contaminants from a data storage media, the cleaning head having a cleaning surface comprising a self-assembled monolayer, with the cleaning surface leading a read/write transducer. The self-assembled monolayer is selected to have a terminal functional group that has a high affinity to the contaminant(s) desired to be attracted and/or removed.

An accessor includes a main body unit configured to convey a recording medium in a first direction, the main body unit being attached to a housing of a library device to be movable in the first direction, a picker configured to convey the recording medium in a second direction intersecting with the first direction, the picker being mounted on the main body unit to be movable in the second direction, and a cleaner mounted on a surface of the picker along the second direction.

An accessor includes a main body unit configured to convey a recording medium in a first direction, the main body unit being attached to a housing of a library device to be movable in the first direction, a picker configured to convey the recording medium in a second direction intersecting with the first direction, the picker being mounted on the main body unit to be movable in the second direction, and a cleaner mounted on a surface of the picker along the second direction.

Provided are a tape drive cleaning device, tape drive library deploying a tape drive cleaning device, and method for using a tape drive cleaning device. The tape drive cleaning device is used to clean a tape drive having a tape drive loader tray in which a tape cartridge is inserted. The tape drive cleaning device includes a body and a material attached to the body. Dimensions of the body with the material are configured to fit into the tape drive loader tray to have the material engage a tray inner surfaces of the tape drive loader tray. The material is configured to collect debris on the tray inner surfaces when engaged with the tray inner surface.

Provided are a tape drive cleaning device, tape drive library deploying a tape drive cleaning device, and method for using a tape drive cleaning device. The tape drive cleaning device is used to clean a tape drive having a tape drive loader tray in which a tape cartridge is inserted. The tape drive cleaning device includes a body and a material attached to the body. Dimensions of the body with the material are configured to fit into the tape drive loader tray to have the material engage a tray inner surfaces of the tape drive loader tray. The material is configured to collect debris on the tray inner surfaces when engaged with the tray inner surface.

According to an embodiment, a control method for a heat-assisted magnetic recording and reproducing device including a heat-assisted magnetic recording head including a main pole, a near-field transducer generating near-field light, a waveguide propagating light to the near-field transducer, and a laser light source supplying light to the waveguide, and a heat-assisted magnetic recording medium that has a lubricant layer on a recording surface opposing the head, includes irradiating the near-field light on the medium with a second laser current value set lower than a first laser current value at a time of write, and operating the head, thereby performing a smoothing process on the surface of the lubricant layer.

In one general embodiment, an apparatus includes a magnetic head, and a controller coupled to the magnetic head, the controller being configured to perform a method that includes measuring humidity in a vicinity of the apparatus in response to detection of an error while performing a data operation on a magnetic recording tape. An error recovery procedure to remove debris on the tape is executed in response to detection of an error and the measured humidity exceeding a predefined upper limit value. An error recovery procedure to remove debris adhering to the magnetic head is executed in response to detection of an error and the measured humidity being below a predefined lower limit value.