The present invention relates to a mobile device and method for destroying data carriers .

Devices for destroying data carriers are generally known. Hard disks can thus be destroyed with a shredder. Use can likewise be made of a hydraulic press which crushes the data carrier.

Such known devices are usually fixedly disposed machines . This has the drawback that the data carrier for destruction must be taken to the shredder or press. This is very undesirable in an office environment. It is therefore an object of the present invention to provide a mobile device for destroying a data carrier which destroys the data carrier with sufficient certainty such that after destruction recovery of the information available on the data carrier is not possible, or at least only possible to a very limited extent.

This object is achieved with a device as defined in claim 1. According to the invention the mobile device comprises a feed device and a cutting device, wherein the feed device is disposed for the purpose of feeding the data carrier in a feed direction to the cutting device, and wherein the cutting device is adapted to cut completely through the data carrier. Cutting completely through the data carrier makes recovery of data on the cut-through data carrier considerably more difficult. The device is particularly suitable for cutting through hard disks. These disks consist of a metal housing with a series of concentrically placed, magnetizable disks arranged therein.

In order to further reduce the possibility of successful recovery of data, it is advantageous that the feed device is adapted for stepwise feed of the data carrier during operation. A further advantage can be obtained when the step size of the stepwise feed is adjustable. In the case of the hard disk this means that the disk can be cut into pieces or strips of variable dimensions. The adjustability can preferably be controlled on the outside of the machine so that a user does not have to open the housing in which the cutting device and feed device are placed.

In a preferred embodiment the cutting device comprises a first knife connected to a drive for the purpose of completely cutting through the data carrier perpendicularly of the feed device. During the cutting movement of the knife caused by the drive the knife follows a path. The feed device is now set such that the data carrier is carried into this path such that the path lies perpendicularly of the data carrier. In the case of a hard disk it is advantageous if the cut in the disk is made on the upper and/or lower side thereof, i.e. one of the two larger surfaces.

The drive of the knife preferably comprises a hydraulic press. A hydraulic press has the advantage that much pressure force can be generated within a limited space. It is a further advantage if this press is adapted for connection to the regular mains electricity.

Within the context of the present application the term regular mains electricity is understood to mean the power supply accessible in a normal office environment or dwelling. The object of the present invention is to provide a mobile device for destroying a data carrier. This device can preferably be used in the above-mentioned office environment or dwelling. If such a device could only be used by being connected to for instance a power current connection, the device would have very little flexibility. The term regular mains electricity must therefore be understood to comprise only those connections which are readily accessible, and so for instance not a power current connection.

The use of the regular mains electricity implies that the mobile device can draw off less power than in the case of a power current connection. It is therefore important to use a hydraulic press which can produce sufficient force at this voltage. The hydraulic press is preferably adapted to produce a pressure force of at least 150000 N.

Use is preferably made of a cutting device comprising a second fixedly disposed knife, wherein the first and second knife are disposed such that, during a cutting movement associated with said complete cutting through of the data carrier, the first and second knife pass at least partially alongside each other. An effective cutting movement is achieved by the cutting knives passing a small distance alongside each other.

It has been found that the form of the knife has significant consequences for the power which the press must be able to produce to cut through the data carrier. A particularly advantageous cutting movement can be obtained if the form of the knife is such that the first knife cuts at least partially into the data carrier at an angle. Cutting at an angle is for instance possible by providing the knife with a reverse V-profile. Such a profile is characterized in that a knife with this profile cuts first into the sides of the data carrier. A further advantage of this profile is related to the construction of a hard disk. This is because these are provided in the centre with a shaft around which the concentric magnetizable disks are placed. The material from which this shaft is made is very hard. Making use of a reverse V-profile it is however still possible to suffice with a limited power of the press, whereby the flexibility of the machine is not impaired.

For the manufacture of the first knife a type of steel is preferably used with a hardness of at least 60 HRC. A very advantageous type of steel is known under the name of high-grade tool steel. Of this type, steel with the material number 12379 is highly suitable.

The knife can comprise a plurality of knife parts. It is thus possible for instance for the knife parts to be placed on a knife holder. The knife holder and knife parts can then consist of different material. This provides the advantage that, when the knife parts become worn, only these parts have to be replaced. A reverse V-profile is possible by placing substantially beam-like knife parts at an angle to each other in a knife holder adapted for this purpose. It is thus not essential to apply the V-profile in the hard steel type.

It is important to select the material of the first knife, and preferably also the second knife, such that it is not magnetizable or magnetic. This is related to for instance the strong magnetic fields which may be present in the data carriers such as a hard disk. If the knives were magnetizable, there would be a risk of remnants of the hard disk adhering to the knife during or after cutting. The cutting device would have to be repeatedly cleaned as a result .

In order to further reduce the possibility of data being extracted from the cut parts of the data carrier, it is advantageous for a pressing device to be incorporated downstream of the cutting device. This pressing device then deforms the cut parts.

The present invention also provides a method for destroying a hard disk. This method comprises the steps of stepwise feed of the hard disk in a feed direction to a cutting device which comprises a drivable first knife, and driving the first knife for the purpose of completely cutting through the hard disk substantially perpendicularly of the feed direction. The method is characterized by clamping the hard disk in order to prevent pieces which are too large being pulled out of the hard disk during the cutting. The disks are preferably deformed and clamped in the hard disk or in the remaining part thereof prior to complete cutting through of the hard disk. Preferred embodiments of the present invention will be discussed in more detail hereinbelow with reference to the accompanying figures, wherein:

Figure 1 is a schematic view of the general principle according to the present invention; Figure 2 is a side view according to arrow I in figure 1;

Figure 3 is a schematic top view of an embodiment of the invention; and

Figures 4A and 4B show croas-sections of two preferred embodiments of the present invention.

Figure 1 shows schematically the general principle of the invention, while figure 2 shows a schematic side view according to arrow I in this figure. In figure 1 a hard disk 1 is advanced as according to arrow 3 in the direction of a cutting device 4 by means of a hydraulic cylinder 2 functioning as a feed device. The cutting device comprises a first knife 5 and a second knife 5'. First knife 5 is received in guides 6 and is driven by a hydraulic press 7. First knife 5 is shown in simplified manner in figure 1. In a favourable embodiment use is made of a knife holder to which two knife parts can be connected. These knife parts are connected at an angle to the knife holder, whereby a reverse V-profile is created. The middle horizontal part of the knife as shown in figure 1 can here be largely or wholly absent.

Hydraulic cylinder 2 can move with discrete steps, whereby hard disk 1 can be cut into strips 8. These strips are collected by means of a- receiving bin 9.

The movement of first knife 5 is preferably such that the bottom side of this knife passes alongside the top side of second knife 5 ' . The distance between the two knives is chosen such that there is sufficient tolerance in the direction according to arrow 3 to prevent the knives making contact with each other. In an embodiment this clearance is about 0.5 millimetres.

An optional addition (not shown) to the above embodiment comprises a pressing device for further deforming the cut parts 8. A possible embodiment comprises a plate placed behind the cutting device. After cutting the cut parts 8 fall onto the plate. Arranged on both sides of the plate are pressing members which can move toward each other for the purpose of pressing the parts. The plate can then be pulled away or tilted, whereby the parts fall into the receiving bin 9 placed below the plate. ., Figure 3 shows a top view of the device. In addition to the above discussed hydraulic cylinder 2, this embodiment is provided with a second hydraulic cylinder 10. This cylinder places the hard disk onto a conveyor 11 in the direction of cutting device 4. The hard disk can be placed in the machine by means of a transport device (not shown) , in this case a lift which transports a hard disk for destruction downward from the upper part of the machine to location 12. Hydraulic cylinder 10 will then push the hard disk to conveyor 11. Cylinder 2 then moves the hard disk in stepwise manner to the cutting device.

The device according to the invention has been developed for the physical destruction of for instance 2.5 inch and 3.5 inch hard disks, telephones, USB sticks, DVDs, Blu-Ray DVDs and tapes. As described above, destruction takes place by means of cutting, using for instance two knives, preferably by means of a knife and lower knife.

Using this cutting method disks can be cut in continuously adjustable manner into strips of for instance 1 to 70 millimetres. The hydraulic cylinder used for this purpose has a bore between 100 and 125 millimetres and a stroke of 45 to 65 millimetres, in accordance with the thickness of the disks.

The hydraulic cylinder is actuated by a hydraulic unit. This is provided with a 2.2 kW motor. This motor actuates an oil pump with a capacity of 6.0 litres per minute. A stroke pressure can hereby be developed of 220 bar, this corresponding to about 17300 kilograms. As described, the cylinder drives a vertically moving knife. The hard disk or other media is held fast during cutting by a pressing plate comprising a spring assembly and/or two to three gas cartridges with a pressure force between 1500 and 3000 kilograms. The pressure force of this spring assembly and/or gas cartridges is further absorbed by three round pillars of about 32 millimetres which preyent friction so that the spring assembly and/or the gas cartridges can be pressed downward adequately. On the pressing plate is a resilient tongue which moves up and downward so that the hard disk is still held fast during the final part of the cutting, thus preventing a large piece falling into the waste bin. The cutting knife and the spring assembly and/or gas cartridges operate independently of each other. When the cutting knife moves upward, it co-displaces the spring assembly or the gas cartridges back upward via a guide. When the cutting knife moves downward, the gas cartridges are released and will exert the set pressure force.

The displacement of the data carrier in the direction of the cutting device takes place with a spindle motor which can also develop sufficient counterforce such that the data carrier is not pressed backwards during the cutting. The whole is actuated by a servomotor which remembers all steps made so that it knows the correct position during cutting, should a displacement occur.

The cutting thickness preferably lies between 10 and 25 millimetres, although larger cutting thicknesses are also possible, such as 41 millimetres, this in accordance with the desired degree of destruction. The machine is suitable for 220 V, 16 A as well as for operation at 110 V. This function is possible due to the use of transformers. The 2.2 kW motor can also be connected without problem to 220 V mains electricity by placing a frequency converter which absorbs the peak voltage.

As described, the cutting into strips of 1 to 70 millimetres takes place by means of a pushing the data carrier. After each cut the data carrier will advance a determined distance in accordance with the setting. A PLC- controlled servomotor can also be used here to operate the pushing element .

The form of the cutting knife can also be such that the knife runs obliquely upward on ..either side, wherein two protrusions of round shape are arranged between which the knife runs straight. This type prevents pieces of the data carrier (s) which are too large being pulled out of the cutting device during cutting.

The use of the protrusions of round shape provides particular advantages in the case of a hard disk. Such a disk comprises a plurality of magnetizable disks, referred to as platters, which are placed concentrically around a drive shaft. The round form, or at least non-sharp form compared to the rest of the knife, achieves that the platters are first deformed before being cut through. The deformation provides for a clamping action, whereby the platters are held in place during or after the cutting.

A hard disk generally comprises a strong casing or cover manufactured from metal. It is advantageous if the hard disk is placed in the device such that this casing is directed toward the moving knife. In this case the deforming of the metal can contribute toward the clamping action for the purpose of holding fast the platters . The deformed metal can function here as a clamp for the platters . By cutting through the hard disks in the above stated manner the platters are thus first deformed, whereby they are clamped in the hard disk or the remaining part thereof . This is made possible by engaging the hard disk with a relatively blunt object such as a round protrusion. The platters are cut through only after this deformation. It will be apparent to the skilled person that such a deformation can be realized not only on the knife. Protrusions or similar blunt structures can thus also be placed on the pressing plate or on the transport surface on which the disk rests. The holding of the hard disk during cutting takes place as described above with a relatively great force. Placing the protrusions or structures on these holding means also achieves tha-t the platters are deformed and become clamped in the hard disk or the remaining part thereof.

At least two protrusions or blunt structures are preferably arranged. It is recommended here to place the protrusions such that they engage the hard disk on both sides of the shaft around which the platters are placed.

Because the shaft is manufactured from very strong material , it is necessary to prevent the protrusions engaging thereon. This is possible for instance by placing the protrusions apart, each on a different side relative to the shaft. It is also the case that for an effective deformation the protrusions preferably do not engage on the side edge of the hard disk, since the upright side wall of the casing has a strengthening function in vertical direction.

Figures 4A and 4B show two examples of blunt structures in the form of protrusions. In the front view of figure 4A the first knife 5 comprises two round protrusions 13. Likewise shown are walls 14 of the feed channel through which hard disk 1 is transported stepwise to knife 5 by means of a feed device. Because hard disk 1 is shown in cross-section, the platters 15 situated around a shaft 60 can be seen. The whole unit of platters and shaft is enclosed by a casing 17. Figure 4A shows clearly that protrusions 13 engage hard disk 1 in an area between shaft 16 and upright side wall 18. It is also apparent that the position of hard disk 1 can vary between walls 14. The size of knife 5 and the placing of protrusions 13 thereon does however guarantee engagement between shaft 16 and upright side wall 18.

Knife 5 runs obliquely upward on either side 23. This provides the advantage that the hard disk is also pressed inward from the sides. This measure also strengthens the clamping of the platters in the hard disk or the remaining part thereof .

Figure 4B shows a cross-section of another embodiment in which protrusions are used to deform the platters prior to cutting.

In the device of figure 4B two protruding beam-like parts 19 are arranged on a side of a pressing plate 20 directed toward hard disk 1. Pressing plate 20 is movable as according" to arrow 21 and serves to hold hard disk 1 fixedly during cutting. Platters 15 in hard disk 1 will be deformed by beam-like parts 19 while being held fast.

Instead of the above arrangement, or in combination therewith, beam-like parts can also be fixed to transport surface 22. In that case it can be advantageous to place hard disk 1 in the device with casing 17 directed toward transport surface 22 in order to ensure that casing 17 is likewise deformed, thereby enhancing the clamping action. In figures 4A and 4B protrusions 13 and 19 are drawn as an integral part of respectively knife 5 and pressing plate 20. It is however also possible for these protrusions to be arranged by means of a connection. It is thus also possible for the protrusions to consist of a different material, partly in view of the fact that the function thereof differs from the function of the remaining part of knife 5. The invention is described above using one or more embodiments thereof. It will however be apparent to the skilled person that diverse modifications and additions are possible without departing from the scope of protection defined by the appended claims.