A magnet structure for a magnetic data storage medium erasing apparatus includes a first half comprising a first plurality of magnets arranged symmetrically, having polarization direction of adjacent magnets in quadrature and at an oblique angle with respect to a plane of symmetry. A second half comprises a second plurality of magnets arranged symmetrically, having polarization direction of adjacent magnets in quadrature and at an oblique angle with respect to the plane of symmetry. The second half is arranged symmetrically with respect to the first half, wherein the first half and the second half are separated by an air gap disposed about the plane of symmetry.

An apparatus for separating components of a hard disk drive includes a separating blade mounted on a blade mount and a sensor to detect a gap or seam between a hard disk drive lid and housing. The separating blade defines a bevel edge that can be aligned with the gap or seam. The alignment of the separating blade to the gap is in response to a signal generated by the sensor. In certain instances, the sensor is a laser. Opposing drive rollers are configured to contact a hard disk drive for movement of the hard disk drive into the separating blade.

Disclosed herein is an apparatus and/or device to scrape a hard disk drive (HDD) to completely and permanently erase, remove, and/or destroy digital and/or electronic data and/or information stored on and/or written to the HDD without using and/or necessitating the use of external induction. The apparatus includes a first part of a HDD scrapper mounted on an arm of the HDD and a second part of the HDD scrapper mounted on a scrapper head. The apparatus also includes a turner that simultaneously permits a turning operation of magnetic platters of the HDD and the HDD scrapper. The first part, the second part, the arm, the scrapper head, the turner, and the magnetic platters are included in an enclosure of the HDD.

An apparatus comprises a magnet housing dimensioned to receive a heat-assisted magnetic recording (HAMR) medium or a hard disk drive comprising at least one HAMR medium. A degausser is disposed in the magnet housing and is configured to generate at least one field sufficient to erase the HAMR medium, where the HAMR medium has a coercivity of between about 20 and 100 kOe at room temperature.

A magnet structure for a magnetic data storage medium erasing apparatus includes a first half comprising a first plurality of magnets arranged symmetrically, having polarization direction of adjacent magnets in quadrature and at an oblique angle with respect to a plane of symmetry. A second half comprises a second plurality of magnets arranged symmetrically, having polarization direction of adjacent magnets in quadrature and at an oblique angle with respect to the plane of symmetry. The second half is arranged symmetrically with respect to the first half, wherein the first half and the second half are separated by an air gap disposed about the plane of symmetry.

A method of erasing data using a file-based protocol from a data storage apparatus for repurposing, reallocation to a new user or retirement of the data storage apparatus, the data storage apparatus comprising a memory using a file-based protocol, and the method comprises: receiving one or more signals representative of the available free space of at least one selected region of the memory; iteratively writing files to the at least one selected region of the memory using the file based protocol, wherein: at least one of the files is sized based on at least one of the received signals and the iterative writing of the files comprises writing the files in sequence such that for at least part of the sequence each file is smaller in size than the preceding file of the sequence; and wherein the files are written to collectively occupy all of the at least one selected region of the memory; and the method further comprises receiving an indication that said at least one selected region of memory is full following the writing of said files, and in response to the indication writing at least one further file to said at least one region of memory.

A single magnetic pulse degaussing apparatus for use in erasing information contained on magnetic recording or storage media. A degaussing chamber for receipt of magnetic forces above 2.0 Tesla is accessible by upper and lower rotary actuated doors. The internal flux of a coil is measured by the current passing through the coil during the discharge cycle to provide a flux versus time measurements. The measurements are inserted into a performance verification algorithm to assure sufficient time for media destruction has taken place before releasing the media from the degaussing chamber.

A system and method for physically destroying the data storage portion of electronic media electronic storage devices such as hard disk drives, solid state drives and hybrid hard drives that comprises a rotatable milling cutter and a cradle for locating the media electronic storage device in a positioned to engage the milling cutter. An integrated computer is included containing a data base of various parameters of different types of hard drives available. A scanning system determines information about the type of media electronic storage device being introduced in the system to be destroyed and conveys the such information to the computer whereby the data base may be used to provide information to properly locate the cradle and milling cutter to destroy the data storage portion and for printing out a certificate of destruction specifically identifying the hard drive that has had it data destroyed. A slug cutter is provided to retrieve slugs containing the rare earth metal after the data storage portion is destroyed.

A system and method for dismantling components of electronic media electronic storage devices such as hard disk drives, solid state drives and hybrid hard drives. The components are dismantled in a nondestructive manner so as to be capable of reuse. First devices loosen the various components of the storage device, Second devices are provided for removing components from the storage device. A holding chassis receives the storage device, and moves the storage device for engagement with the first and second devices. A mechanism may be provided for destroying the data containing portion of the electric storage device when it is removed from the storage device. A database of information concerning past and current storage devices including their configurations, component locations and screw/fastener locations is provided along with a scanning system for retrieving information about the storage device being introduced into the system. The scanned information and information from the database is used to control and position the first and second devices and holding chassis.

Three systems for the destruction of the data storage portion of electronic media storage devices such as hard disk drives, solid state drives and hybrid hard drives. One system utilizes a mill cutter with which the hard drive has relative motion in the direction of the axis of the mill cutter to destroy the data storage portion. A second system utilizes a laser to physically destroy the data storage portion. The third system utilizes a chemical solvent to chemically destroy the data storage portion.