Patent Description:
Various types of data are stored on the hard drives of computers. Such data may include personal confidential information concerning individuals. This data may include their social security numbers, financial information, health information and private telephone numbers as examples. The hard drives are also used to store corporate information which may include proprietary information such as developing products, customer lists, and business plans. The government may store confidential information including highly classified information on the hard drives.

When it is desired to replace the computer, the data must be removed from the hard drive so that it cannot be misused by unscrupulous individuals. Merely erasing the data by using the computer commands is not sufficient as the data can be recaptured. This is true even if the hard drive is removed for upgrade purposes. However, even if the hard drive is removed, something must be done to destroy the data.

One way of ensuring that the data cannot be used or recovered from an unwanted hard drive is to completely destroy the hard drive. This has been accomplished in the past by completely shredding the entire hard drive. However, as the hard drive is encased in metal, the complete destruction involves the shredding of a relatively large volume of metal that requires a lot of energy. Another way to destroy data carrier is shown in <CIT>.

Additionally, hard dives use rare earth elements in their construction. Rare earth elements include cerium (Ce), dysprosium (Dy), erbium (Er), europium (Eu), gadolinium (Gd), holmium (Ho), lanthanum (La), lutetium (Lu), neodymium (Nd), praseodymium (Pr), promethium (Pm), samarium (Sm), scandium (Sc), terbium (Tb), thulium (Tm), ytterbium (Yb) and yttrium (Y). It is becoming desirable to recycle such elements. The complete destruction of a hard drive does not readily permit the recapture of such elements.

It is thus desirable to have a process and apparatus for reclaiming the elements of the hard drive that contain the rare earth elements and then destroying the data containing portion of the drive.

An example of a hard drive data destroying device that does not destroy the entire hard drive is shown and described in <CIT>, the disclosure of which is is referred to Another example of such a hard drive data destroying device is shown in co-pending <CIT>, the disclosure of which is referred to.

According to the invention there is provided a system for reclaiming select components containing rare earth metals from electronic media storage devices such as hard disk drives, solid state drives and hybrid hard drives and destroying the data containing components thereof comprising first devices to loosen various components of the storage device, said components including the components containing the rare earth metals and the data containing portions. Second devices are provided for removing components from the storage device and a holding chassis is provided for receiving said storage device and moving the storage device for engagement with said first and second devices. A section is provided for destroying the data containing portion of the electric media storage device when it is removed from the storage device.

In general, the system described herein can be used for dismantling and extracting various components of electronic media storage devices such as HDD, SSD, and HHD hard drives. The HDD (Hard Disc Drive) hard drive is essentially a metal platter with a magnetic coating. The coating stores the data. A read/write head on an arm accesses the data while the platters are spinning in a hard drive enclosure. In SSD (Solid State Drive) hard drives, instead of the magnetic coating on top of platters, the data is stored on NAND flash memory (information pods). The SSD drive has no moving parts. The HHD (Hybrid Hard Drive) hard drive is a hybrid incorporating the HDD and the SSD principles.

As outlined by the flowchart shown in <FIG>, the dismantling process of a hard drive <NUM> is initiated when it is placed into the vertical holding chassis <NUM> of the dismantling/destruction machine <NUM> shown in <FIG>. Then, the drive <NUM> is automatically indexed into the machine's milling chamber <NUM>, by way of the hard drive transport rails <NUM>, where a scanning system scans the hard drive. A code reader <NUM> scans the top surface or cover <NUM> (See <FIG>) of the drive <NUM> for its manufacturer's barcode and other appropriate indicators, which are used to identify the make and model of the hard drive. The machine <NUM> will also simultaneously scan the hard drive with a product visioning camera or integrated smart camera to aid in drive orientation and component recognition. A G-code or conversational programming database will also be a part of the dismantling/destruction machine's product recognition operating system. During the initial scanning of the hard drive, the system will also have the capacity to read QR and Data Matrix Codes. The information retrieved may consist of a link to the manufacturers' or supporting companies' website and provide text content like the location make and model of the respective drives' circuit board along with recovery instructions. The operating system of the dismantling/destruction machine <NUM> can print the retrieved information prior to beginning or upon completion of the dismantling process. The operating system also has the capacity to save the retrieved information as a Word document or convert it to a PDF that can be stored for future use or delivered electronically to another computer, smartphone or tablet.

When the manufacturers' barcode on the hard drive <NUM> is successfully captured, the dismantling machine queries its barcode database, which consists of all hard drives, <NUM> inch and <NUM> inch HDDs, SSDs, and HHDs that are currently or were formerly available on the market. The system will also accommodate the integration of newly developed memory drives that are produced in the future. The system's barcode database will also interface with a visioning system comprised of a pictorial database cataloging specific components of the various types of drives, which will consist of: a) the manufacturer's barcode on the face cover <NUM> and top head of the drive; b) circuit boards <NUM> as well as the orientation of the rare earth metals, which consist of c) the voice-coil magnet <NUM> and d) the spindle motor "<NUM>. The orientation of the hard drive cover <NUM>, circuit boards <NUM>", voice-coil magnets <NUM>, and spindle motors <NUM> will also be accompanied with specific x, y, and z numerical coordinates with the visioning system to aid in their designated extraction procedure. Additional logistic information can be integrated into the system's database for the removal of other desired components. Based on the type of drive identified in the holding chassis, the program will convey specific dismantling coordinates to the CNC interface, which consist of several dismantling stages that start from the outside of the hard drive to the inside.

The present device includes an operating system that integrates the following; but it has the capacity to be configured into one integrated system or expanded to more than the four systems currently presented. Further, the algorithm of the present embodiment's operating system has the capacity to be integrated, in part or in total, into other manufacturers' systems that are currently being developed or developed in the future:.

As shown in <FIG>, the present machine <NUM> includes a milling tool <NUM> having two single headed milling units; one positioned over the front and one positioned over the back of the hard drive <NUM> in the milling chamber <NUM> of the machine <NUM> to perform either a HDD, SSD or HHD dismantling process. Along with the type of drives stored in the program's database are the drives' corresponding x, y, and z numerical coordinates, which will be interfaced with a database consisting of specific G-codes or conversational programming used to direct the path of the milling tools in removing the fastening screws, on the drives, using a countersink or boring method.

The dismantling process will be conducted on both sides of the hard drive, at the same time, in the following stages:
Stage <NUM>: Prior to processing hard drives, all external hardware like mounting clips as well as plastic and metal casing need to be removed. The hard drive <NUM> will be placed, on its edge, in the vertical holding chassis <NUM> having an open center and which is mounted to a loading table. There are two distinct holding chassis; one for <NUM> inch drives and the other for <NUM> inch drives. When the hard drive <NUM> is introduced to its appropriate holding chassis through the opening <NUM>, it will automatically index into the milling chamber <NUM>, along the hard drive transport rails <NUM> through the opening <NUM>. Holding clamps <NUM> in the perimeter of the holding chassis <NUM> will secure the hard drive <NUM> in place during the dismantling process. Both the barcode scanner and visioning camera <NUM> will proceed to scan the drive. The present machine will also be able to process hard drives that have their covers removed and the information platters milled out. These particular hard drives will be identified by the manufacturer's barcode placed on the top edge of the hard drive.

Once the hard drive <NUM> has been identified, coordinates received from the system's databases will be transmitted to the system's CNC interface directing the speed, depth and positioning of the milling spindle to bore out specific fastening screws from the cover of the hard drive <NUM>. On specific hard drives, a wedging mechanism will be inserted along the outer edge of the drive's cover to help break the adhesive seal (not shown). At the same time, the milling tool <NUM> over the backside of the hard drive will receive coordinates from the databases to bore out screws, which are holding the drive's circuit board in place.

Once both sides complete the removal of their respective screws, the vertical holding chassis <NUM> will index forward, along the hard drive transport rails <NUM>, into the dismantling chamber <NUM> to allow the cover <NUM>" of the drive and the circuit board <NUM> to be removed using a pick and place mechanism <NUM> including a suction nozzle, and then releasing the components onto the system's conveyor belt <NUM> below the dismantling chamber <NUM>. The conveyor belt <NUM> runs the full length of the dismantling and milling chambers to capture all the dismantled and falling parts. Then the conveyor belt transports the collected components, like circuit boards, down stream for further manual or automated processing to occur. The milling tool <NUM> used to bore out the screws attached to the cover of the hard drive can also be automatically exchanged for an edging tool, which cuts around the perimeter of the hard drive cover (not shown). The described embodiment can be adapted with cooling nozzles that emit air, CO<NUM>, LN<NUM>, or micro lubricants in the form of a mist on the drive or through holes in the milling tools for better performance and extended wear (not shown). The described dismantling system can also be programmed to recover other desired components inside the hard drive.

<FIG> show the dismantling sequence of the various hard drives.

Stage <NUM>: The vertical chassis <NUM> holding the drive <NUM> is indexed back into the milling chamber <NUM>, along the hard drive transport rails <NUM>, where logistic coordinates from the system's databases again direct the milling tool <NUM> over the front of the hard drive, to bore out specific screws that are holding the voice-coil magnets in place, while the milling tool <NUM> over the back of the hard drive will receive coordinates from the system's databases, to bore out the fastening screws that are holding the voice-coil magnet from the back. The procedure for removing the rear fastening screws, of the voice-coil magnet <NUM>, can also be performed during Stage <NUM> when the circuit board is being removed, by boring out targeted holes through the circuit board where the rear fastening screws are located. The milling tool <NUM> will also be directed to bore out a hole in the rear assembly of <NUM> inch HDD and HHD spindle hubs, which will enable the platters to be released during the pick and place process.

When Stage <NUM> of the milling process is complete, the vertical hard drive holding chassis indexes forward, along the hard drive transport rails <NUM>, to the dismantling chamber <NUM> to allow the pick and place mechanism <NUM> to retrieve the voice-coil magnets "<NUM>" from the hard drive with a suction nozzle. A clamping mechanism <NUM>, or magnetic clamp, can also be integrated into the dismantling chamber <NUM>, to provide a more aggressive method for retrieving the voice-coil magnets. Then the coupled voice-coil magnets <NUM> are dropped into a separate holding container <NUM> that prevent the magnets' magnetism from interacting with the other magnets that have been collected.

During the period in which the voice-coil magnets <NUM> are removed, the pick and place mechanism <NUM> also removes the information platters <NUM> from the hard drive casing using the suction nozzle of the pick and place mechanism <NUM>. Referring to <FIG>, in most instances, the platters <NUM> from the <NUM> inch HDDs and HHDs are still mounted to the spindle hub. Then the platters <NUM>, containing stored information, and the spindle hub configuration are placed in a nesting clamp <NUM>, which allows the platters to securely spin while a milling tool <NUM> grinds away the platters <NUM> from their outer edge to the inner spindle hub connection. The nesting clamp <NUM> can also accommodate <NUM> inch platters that are dislodged from the spindle hubs. The metal filings that are created are collected with a vacuum system <NUM>.

As shown in Figs. <NUM>-12b, the milling of the <NUM> inch platters can be performed with one or more milling tool configurations. In all cases, the information stored on the platters is destroyed.

<FIG> shows schematically another method of shredding the platters <NUM>. A single cutting tool <NUM> is mounted in a suitable mechanism that is guided in a track to move the cutting tool <NUM> toward the hub <NUM> of the platter <NUM>. Once the rotating cutting blade of the cutting tool <NUM> pierces the outer portion of the platter and reaches the platter hub <NUM>, moving along the path indicated by the arrows (<NUM>), the cutting tool <NUM> follows a clockwise <NUM>-degree cutting track around the platter hub <NUM>, indicated by arrows (<NUM>), shredding the hard drive platters <NUM> so that the only thing that remains of the hard drive platters <NUM> are small metal shavings. Once the cutting tool <NUM> has completed the <NUM>-degree cutting path around the hub <NUM>, the cutting tool <NUM> returns to the start position along the path indicated by arrows (<NUM>).

<FIG> and <FIG> show schematically yet another method of shredding utilizing two cutting tools <NUM> and <NUM>. As shown, the cutting tools <NUM> and <NUM> are mounted one to either side of the hard drive <NUM>. The cutting tools <NUM> and <NUM> are mounted on suitable mechanisms <NUM> that can be moved in tracks to move each cutting tools <NUM> and <NUM> toward the hub <NUM> of the platters <NUM>. A hard drive platter clam <NUM> clamps the platters <NUM> and prevents them from rotating. Once the rotating cutting blades of the cutting tools <NUM> and <NUM> pierce the outer portions of the platters <NUM> and reach the platter hub <NUM>, the mechanism moves the cutting tools <NUM> and <NUM> around an axis extending through the center of the hub <NUM> as shown. The cutting tool <NUM> is moved clockwise from nine to three o'clock and the other cutting tool <NUM> is moved clockwise from three to nine o'clock around the platter hub <NUM> as indicated by the arrows (<NUM>) leaving only shavings.

Once the cutting tools <NUM> and <NUM> complete the <NUM> degree cutting path around the platter hub <NUM>, the movement of the cutting tools <NUM> and <NUM> is reversed and the cutting tools <NUM> and <NUM> are returned to their original position.

<FIG> and 12b schematically represent another method of shredding platters <NUM>. As shown, there are four milling tools <NUM>, <NUM>, <NUM> and <NUM> mounted around a circle having a diameter slightly greater than the outside diameter of the platters <NUM> and initially positioned above the platters <NUM>. These milling tools <NUM>, <NUM>, <NUM> and <NUM> are shaped like a drill bit in that they have a side cutting edge <NUM> and use their sides <NUM> to grind away the platters <NUM>. The milling tools <NUM>, <NUM>, <NUM> and <NUM> are mounted on suitable mechanisms <NUM> that can be moved in tracks to reciprocate each milling tools <NUM>, <NUM>, <NUM> and <NUM> vertically toward and away from the platters <NUM> and horizontally toward and away from the hub <NUM> of the platters <NUM>.

In operation, a hardware drive platter clamp <NUM> clamps, applies pressure to, the hub of the hard drive <NUM> and each cutting tool is rotated about its axis as indicated by the arrows (<NUM>). The milling tools <NUM>, <NUM>, <NUM> and <NUM> are spun about their individual axes and lowered toward the platter <NUM> in the direction of arrows <NUM> until the lower ends of the milling tools <NUM><NUM>, <NUM> and <NUM> pass the platters <NUM> in the hard drive <NUM>. The milling tools <NUM><NUM>, <NUM> and <NUM> are then rotated around the axis of the hub <NUM> as indicated by the arrows <NUM> and at the same time, each milling tool <NUM><NUM>, <NUM> and <NUM> moves radially inward toward the hub <NUM> as indicated by the arrows <NUM> grinding the platters into small particles.

When the milling tools <NUM><NUM>, <NUM> and <NUM> reach the hub <NUM>, the movement is reversed and the milling tools <NUM><NUM>, <NUM> and <NUM> are rotated about the hub back to their original position. At the same time the milling tools <NUM><NUM>, <NUM> and <NUM> are move radially outward as indicated by the arrows <NUM> into their outermost position. Simultaneously, the milling tools <NUM><NUM>, <NUM> and <NUM> are raised as indicated by the arrows <NUM> into their original position.

Unlike <NUM> inch HDD and HHD platters that are primarily made of ridged aluminum, the handling and destruction of <NUM> inch HDD and HHD information platters require more care because of their fragile composition consisting of glass coated ceramic disks. Their method of destruction as shown in <FIG> comprises the pick and place system <NUM> removing the <NUM> inch platters <NUM> from the partially disassembled hard drive and placing them individually on a platter reception tray <NUM> of a burr grinding device <NUM>. The platters <NUM> are then automatically indexed into the milling chamber <NUM> of the burr grinding device <NUM> through a slotted port <NUM>. Inside the milling chamber <NUM>, there is a rotating flat burr grinder <NUM> on a plunger <NUM> of the type shown in <FIG> above the inserted platter <NUM>, which periodically plunges down to break the platter <NUM> into small pieces. A vacuum system <NUM> is used to help draw the platter fragments through a cone shaped receptor <NUM> into a conical burr grinder <NUM> of the type show in <FIG>. The conical burr <NUM> reduces the platter fragments into a powder consistency <NUM>, which is deposited into a collection receptacle <NUM>.

Another method that can be used to destroy <NUM> inch HDD and HHD platters <NUM> is the use of a modified lapidary flat lap grinding device <NUM> as shown in <FIG> and <FIG>. The pick and place mechanism <NUM> carefully removes the glass coated ceramic platters <NUM> from the partially disassembled hard drive and places them individually on a platter reception tray <NUM>. The platter <NUM> is then automatically indexed into the body of a lap mill grinding device <NUM> through a slotted port <NUM>. The platter <NUM> is then placed around the centering spool <NUM> of a bottom grinding mill <NUM> that has a grinding surface <NUM> facing upwardly. Next, a weighted top mill <NUM>, with a grinding surface <NUM> on its bottom, is placed over the bottom grinding mill <NUM>. By sandwiching the platter <NUM> between the top and bottom grinding mills <NUM> and <NUM>, continuous pressure is applied to both surfaces of the platter; and it prevents the partially ground platter particles from escaping. The top and bottom grinding mills <NUM> and <NUM> rotate counter-clockwise to each other until the information bearing platter <NUM> is reduced to a pulverized residue <NUM>. The remains are collected with a vacuum system <NUM> and deposited into a collection receptacle <NUM>. The spindle motor, which contains rare earth metals, can also be retrieved at this point.

The present embodiment can also utilize a small shredder or hammer mill <NUM> to destroy the <NUM> inch and <NUM> inch platters of the hard drives. The destruction method is carried out when the information platters are dismantled from the hard drive with the pick and place nozzle <NUM> on to the system's conveyor belt <NUM>. Sensors are used to identify the <NUM> inch and <NUM> inch platters. Then the platters are segregated from the other recoverd sub-components; and directed to the shredder. Where the platters are reduced to particulated that are <NUM> or less. A vacuum system with a HEPA filter is used to safely collect the particulates.

Stage <NUM> in the overall process: The <NUM> inch aluminum hard drive casing is indexed back into the milling chamber <NUM> where the milling tool <NUM> is automatically exchanged with a hole cutting tool (not shown) which proceeds to bore out the spindle motor embedded in the base of the hard drive casing. The aluminum slug containing the spindle motor falls into the holding tray <NUM> below shown in <FIG>.

Because of the comprehensive dismantling sequences stored on the system's databases, the present embodiment has the ability to dismantle hard drives that have varying layers of assembly. The system's programming further allows the integration of additional coordinates for the removal of other desired components from the hard drive.

The described dismantling process can also be performed in a linear fashion where the hard drive is placed in the vertical holding chassis; and then advances forward through a series of dismantling chambers and pick and place stations without having to index back and forth between the dismantling chamber and the pick and place station.

The present system can also be configured to perform the dismantling process horizontally where the milling tool is positioned over the hard drive in the milling chamber. Then the system's hard drive holding chassis, that is also positioned horizontally, indexes the hard drive into the dismantling chamber, along the hard drive transportation rails <NUM> where the vacuum nozzle, of the pick and place mechanism, removes the desired components. After the targeted components are retrieved, and placed in their respective resepticals (as previously outlined). The hard drive leaves the system's holding chassis, and is indexed into the horizontal opening of the <NUM> degree hard drive holding chassis <NUM> as shown in <FIG>. The chassis rotates <NUM> degrees along the y axis, performing a Gamma rotation, to position the bottom-side of the hard drive facing up toward the milling tool. The rotation of the holding chassis <NUM> is performed by the chassis turning mechanism <NUM>, which is partially represented in <FIG>. Hex knobs <NUM> on either side of the chassis <NUM> are adapted to be engaged by a turning mechanism <NUM> to rotate the chassis. Automatic locking pins <NUM> on either side of the rotating hard drive chassis secure it into position on the extension-retraction slides on the left and right of the chassis. Then the hard drive exits the <NUM> degree holding chassis <NUM>, and is received back into the open end of the dismantling system's holding chassis; locked into position with the holding clamps <NUM>. The hard drive indexes back into the milling chamber <NUM>, along the hard drive transport rails <NUM>, for the next stage of designated screws to be bored/cored out. The triple sequence continues, among the milling chamber, dismantling chamber, and the <NUM> degree holding chassis until the desired components have been removed. The dismantled hard drive is then ejected from the <NUM> degree holding chassis onto the conveyor belt for further downstream manual or automated processing.

The described embodiment can also be performed in a semi-automated manner. The system's operator will reliy on the automated milling process, in the milling chamber, to bore/core out the fastening screws of the hard drives. Then bypass the automated collection of targeted compoments in the dismantling chamber by attaching the <NUM> degree holding chassis to the end of the milling chamber's hard drive transport rails. This will allow for the dismantled components to fall onto the conveyor belt below, transporting them downsream where the targeted components can be manually collected; and information bearing material can be destroyed using the prescribed destruction methods previously mentioned.

The dismantling machine will also have the option of being configured with an automated hard drive "magazine" loader to further expidite the process.

Although the present embodiment is described in various configurations, automated to semi-automated, for dismantling hard drives, the process can be further consolidated by combining the operatons of both the milling and the dismantling chambers into a single stage.

The dismantling machine's computer interface, linked by an Ethernet cable or wireless connection, will allow the present embodiment to be performed and monitored onsite or remotely requiring minimal or no human interface. The computer interface will also allow for programmatic updates to the system's databases.

The dismantling machine's operating system keeps track of the drives that are introduced to the system. When the destruction process is completed a Certificate of Destruction <NUM> such as shown in <FIG> can be generated which, consists of the manufactures' barcodes from the dismantled drives and the corresponding company asset tags (if present). The captured identification numbers will automatically populate the fields in the Certificate. The Certificate will also consist of the company receiving the service, name of person authorizing the dismantling process, company personnel witnessing the dismantling process, the time and date of the dismantling; and the name of the technician performing the dismantling process.

Additional variables can be added to the Certificate like a running count of sub-components collected; their relative weights; and their value based on current commodity and non-commodity pricing along with other dismantling demographics for productivity reports. However, some of the previously stated variables may not be utilized based on where the company operating the dismantling machine is positioned in the products recovery continuum. The operating system will also allow for the contents of the Certificate to be included with the material retrieved QR and Data Matrix codes to be printed immediately or saved to a Word document or convert it to a PDF that can be stored for future use or delivered electronically to another computer, smartphone or tablet.

A vertical hybrid dismantling fixture <NUM>, shown in <FIG>, can also be adapted to the present embodiment. The fixture consists of a six-headed, pick and place, milling unit integrated with a suctioning system. The combined elements work simultaneously to core/bore out the fastening screws and remove the designated components from the hard drive's chassis in a rapid sequential process. The milling units <NUM> mounted on the frame <NUM>, of the hybrid dismantling fixture <NUM>, can move in unison or independently based on the direction of the system's G-code database. The hybrid dismantling fixture also operates within the sequential manner of the disassembly system's operating system, which includes the barcode system, product visioning system, G-code/conversational programming system, and real earth metals database. After the dismantling system's operating system identifies the type of hard drive in the holding chassis <NUM>, the hybrid dismantling fixtures <NUM> are positioned over the front and back of the hard drive in the milling chamber <NUM> of the machine <NUM> to perform either a <NUM> inch or <NUM> inch HDD, SSD or HHD dismantling process.

Hard drives are typically configured with the same outer dimensions, which allow for the collection of plotted points in a database, directing the milling units <NUM> where to core/bore out the fastening screws as well as holding fixtures. The first stage of the dismantling process consists of the front hybrid dismantling fixture aligning the six-unit hybrid milling fixture over the fastening screws around the perimeter of the hard drive cover. Once the perimeter screws have been cored/bored out, a single milling unit, but others can be directed, sweeps across the surface of the hard drive coring/boring out the fastening screws on the interior. The corresponding suction units <NUM>, mounted on the frame <NUM> of the front fixture <NUM>, are retracted until the milling process is complete. Then the milling units retract. At that time, the suction units <NUM> index toward the surface being milled applying tension pressure before activating the suction. A separation tool (not show) may be activated to help break the adhesive seal around the front cover of the hard drive. While simultaneously on the back of the hard drive, the vertical six-unit hybrid milling fixture is directed to core/bore out the fastening screws from targeted components listed in the hard drive dismantling system's operating system. Not all six milling units may be used, but are available to the G-code/conversational programming system to aid in the milling process. The milling and dismantling process will simultaneously continue on both the front and back of the hard drive, starting from the outside to the inside until the targeted components are removed from the hard drive chassis. The targeted components that are removed will be placed in their respective containers that were previously described or they can be collected on the conveyor belt for downstream manual sorting or automated processing; and the information bearing material can be destroyed using the prescribed destruction methods previously mentioned.

The recovered components from the vertical hard drive dismantling machine can either be directly placed in their respective holding containers, which were previously described or allowed to fall onto the conveyor belt below, transporting them downstream where the targeted components can be manually collected and information bearing material can be destroyed using the prescribed destruction methods previously mentioned.

The Hybrid Dismantling and Suction fixture is best adapted to the horizontal hard drive dismantling system. The hybrid fixture is positioned over the hard drive shortly after the barcode and visioning systems identify the type of drive, either <NUM>. 5inch or <NUM> inch HDD, HHD or SSD, in the holding chassis. The milling units <NUM> are directed by the system's G-code database where to core/bore the fastening screws; and are positioned directly above the fastening screws. When the perimeter are processed a single milling unit <NUM> sweeps across the hard drive eliminating the remaining fastening screws. Then the suctioning units remove the detached components, placing them in their respective collection containers. The six-headed hybrid dismantling fixture, featured in this present embodiment, will be primarily utilized to expedite the removal of hard drive covers; but it is not limited to more or less of the milling and suctioning units to perform the task. The combined milling and suction units, of the hybrid dismantling and suction fixture, make the system highly compatible with the <NUM> degree holding chassis because it consolidates the functions of the milling and dismantling chambers into one unit. The automated collection of targeted components in the dismantling chamber can be bypassed by attaching the <NUM> degree holding chassis to the end of the milling chamber's hard drive transport rails. The recovered components from the hybrid holding fixture can either be directly placed in their respective holding containers or allowed to fall onto the conveyor belt below, transporting them downstream where the targeted components can be manually collected and information bearing material can be destroyed using the prescribed destruction methods previously mentioned.

Claim 1:
A system for reclaiming select components containing rare earth metals of electronic media electronic storage devices such as hard disk drives, solid state drives and hybrid hard drives and destroying the data containing components thereof comprising:
first devices (<NUM>) to loosen various components of the storage device, said components including the components containing the rare earth metals and the data containing portions;
second devices (<NUM>) for removing the components from the storage device;
a holding chassis (<NUM>) for receiving said storage device, and moving the storage device for engagement with said first and second devices; and
a section (<NUM>, <NUM>) for destroying the data containing portion of the electric storage device when it is removed from the storage device.