DE19816571A1 - Access protection for security modules - Google Patents

Abstract

The access protection for a security system has a lock mechanism (23) that has a piezoelectric element (3) that is controlled by a manipulation protection system. The piezo device is of a bimorph strip type that when activated deflects and so allows the lock to be released

Description

The invention relates to an arrangement for access protection for Security modules, in particular to prevent reading or the unauthorized manipulation of security-relevant data. The security modules are usually physically isolated units executed. The data can contain safety-relevant parts a machine program, credit values or other security relate to relevant functions.

Such modules are used, for example, in ASICS in franking machines or used in ATMs.

For general protection and protection against manipulation who which these modules usually have with a hardening casting compound surrounded, see EP 0 717 370 A2. The potting compound is usually an epoxy resin or other suitable plastic.

This makes manipulation difficult, but not prevented.  

To manipulate such security modules too , you would first have the module of an X-ray examination undergo and then to the one suitable for access Grind or drill open spots. The still exists Possibility of influencing via the electrical connections.

Another known protective measure is to use the module a film with a meandering conductor of high packing density enclose and electrically couple with it, see Bennet Yee "Using Secure Coprocessors" May 1994 CMU-CS-94-149, School of Computer Science Carnegie Mellon University Pittsburgh, page 7.

The conductor is powered by a long-life battery. When through disconnection at any point the circuit will be interrupted and consequently the security-relevant data in the module manipulated up to the complete deletion of the same.

This solution requires a reliable power source. The stake Such meander foils are due to the minimal allowable bending angle only possible for relatively large units.

The purpose of the invention is to improve the manipulation safety.

The invention has for its object an arrangement for devices to create with security modules of any size, with the one effective access protection with targeted manipulation options and long lifespan achieved without additional batteries becomes.

According to the invention, this object is achieved according to the main claim solved. Further advantageous features of the invention are the Unteran to take sayings.

The electrical coupling of the security module with an inconspicuous arranged piezo element, which in turn in a simple manner a usual closure, for example in the form of a thread screw, mechanically coupled, leads to an unexpected effect protection of the former. An energy source is not required since the energy required by the unauthorized manipulator itself Form of mechanical energy supplied to release the closure  which is then partially converted into electrical energy by the piezo element Manipulation of the security module is converted.

The invention is explained in more detail below using the exemplary embodiment explained.

Show it:

Fig. 1 is a schematic diagram of the arrangement according to the invention,

Fig. 2 is a schematic diagram of the arrangement according to the invention with separate manipulation circuit,

Fig. 3 shows a longitudinal section of the closure, together with actuating member as shown in detail A in FIG. 2,

Fig. 4 shows a cross section of the closure together with the actuating element and the piezoelectric element and capacitor,

Fig. 5 is a schematic diagram of the arrangement according to the invention.

The illustration is for simplification and easier understanding carried out schematically.

Referring to FIG. 1, the arrangement of the invention in Wesent union of a security module 1, a piezoelectric element 3 and an associated actuating member 5 and a housing 2 surrounding all. The piezo element 3 and the security module 1 are electrically connected to one another via a circuit board 6 .

The housing 2 is composed of a housing cap 21 , a housing base 22 and a closure 23 which is mechanically coupled to the piezo element 3 via the actuating element 5 .

When the closure 23 is opened, the actuating element 5 is triggered mechanically, which in turn deforms the piezo element 3 , the piezo voltage of which then serves to influence the safety module 1 electrically.

In FIG. 2, a separate manipulation circuit 4 is connected between the security module 1 and the piezo element 3 . This creates better opportunities for voltage adjustment and a variation of targeted manipulation.

According to FIG. 3, the closure 23 consists essentially of a metallic box 230 with a hollow cylinder 235 made of a non-conductive plastic and a threaded screw 237 . Both the piezo element 3 and its actuating element 5 are arranged in the socket 230 , see also FIG. 4.

The actuator 5 is designed as a metallic coil spring with angled ends 51 , 52 .

The can 230 is placed laterally with its opening on the housing base 22 . The housing cap 21 is pressed by means of the threaded screw 237 against the housing base 22 , which is provided with a threaded hole 221 .

The threaded screw 237 also projects into the hollow cylinder 235 , onto which the spiral spring 5 is pushed on the outside. One end 52 of the spiral spring 5 is anchored in an insulated manner in the socket 230 , while the other, free end 51 is frictionally connected to an adjustable toothed rack 231 made of a non-conductive plastic which is guided with play transversely to the hollow cylinder 235 in a bore 2353 of the cylinder jacket 2351 . The rack 231 is engaged with a pinion 236 which is rotatably arranged in the cylinder bore 2352 . The pinion 236 is provided with a threaded hole 2361 for the threaded screw 237 .

The piezo element 3 is fastened on a carrier 31 with its one covering. The carrier 31 is out as a metallic leaf spring and conductively fastened in the box 230 .

When the threaded screw 237 is turned clockwise, the toothed rack 231 is pressed outwards by the pinion 236 within the play in the bore 2353 and, due to friction, is pushed up to a stop 232 in the can 230 . With further turning, a slip clutch effect occurs.

When the threaded screw 237 is turned to the left, the toothed rack 231 is positively gripped by the pinion 236 and moved away from the stop 232 . If the end of the toothed rack 231 facing the stop 232 falls below the level of the spiral spring 5 , the free end 51 thereof is released and swings counterclockwise around the hollow cylinder 235 until it meets the free end of the piezo element 3 in its path of movement and this, together with the carrier 31, deflects and bends until it can slide past to a metallic stop 233 , which is fastened in an insulating bush 234 in the socket 230 and to which a line to the safety module 1 , see also FIG. 5 , connected.

The stop 233 is a contact C of the switch formed by the coil spring 5 .

The spiral spring 5 is also permanently connected as a fixed contact B to the potential connection of the capacitor 41 , the other connection of which is connected to the ground contact A, via an electrical line led through a further insulating bush 234 . The carrier 31 and thus the one covering of the piezo element 3 and the socket 230 and the 0V input of the security module 1 are at ground potential.

Since the free end 51 of the spiral spring 50 releases the outer coating of the piezo element 3 at its maximum deflection, the maximum piezo voltage is charged in this way to the capacitor 41 .

The free end 51 of the spiral spring 50 lies on the stop 233 outside the movement path of the rack 231 and is therefore not influenced by this with any rotation of the threaded screw. A renewed deflection of the piezo element 3 is therefore no longer possible.

In FIG. 5, the switching sequence is clearly visible. The free end 51 of the spiral spring 5 assumes the position corresponding to the open contact E when it contacts the rack 231 . When released by the toothed rack 231 , the end 51 initially abuts the outer coating of the piezo element 3 , which corresponds to the contact position D in which a connection to the capacitor 41 is established. Finally, the free end 51 abuts the stop 233 after leaving the piezo element 3 , which corresponds to the contact position C in which the capacitor is connected to the write input WE of the security module 1 .

Reference list

1

Security module, non-volatile memory (NVRAM = non volatile random access memory)

2nd

casing

21

Housing cap

22

Case back

221

Threaded hole in the case back

22

23

Closure of the housing

2nd

230

Can

231

Rack

232

Rack stop

231

233

Stop for end

51

the coil spring

5

, Contact C

234

Insulating bush

235

Hollow cylinder

2351

Cylinder jacket

2352

Cylinder bore

2353

Hole for rack

231

236

pinion

2361

Threaded hole for threaded screw

237

237

Threaded screw

3rd

Piezo element

31

Support for piezo element

3rd

, Leaf spring

4th

Manipulation circuit

41

capacitor

5

Actuator for the piezo element

3rd

, Coil spring

51

free end of the coil spring

5

52

fixed end of the coil spring

5

6

circuit board
A Ground contact, ground covering of the piezo element

3rd

, 0V- Security module input

1

B Potential connection of the capacitor

41

C Potential input of the safety module

1

, Write-free delivery (WE = write enable)
D Potential contact, potential covering of the piezo element

3rd

E open contact
NVRAM Non Volatile Random Access Memory
OV zero volts
WE Write Enable

Claims (13)

1. Arrangement for access protection for security modules, characterized in that at least one security module ( 1 ) is surrounded by a housing ( 2 ), the closure ( 23 ) of which is mechanically coupled to at least one piezo element ( 3 ), which in turn is electrically connected to the security module ( 1 ) is connected for the purpose of targeted manipulation. 2. Arrangement according to claim 1, characterized in that the closure ( 23 ) is coupled to an actuating element ( 5 ) for the piezo element ( 3 ) which serves to deform the Piezoelemen tes ( 3 ) when the closure ( 23 ) opens. 3. Arrangement according to claim 2, characterized in that the actuating element ( 5 ) after the opening of the closure ( 23 ) and triggering of the piezo element ( 3 ) is separated from the latter. 4. Arrangement according to claim 1, characterized in that the piezo element ( 3 ) with the security module ( 1 ) is connected directly. 5. Arrangement according to claim 1, characterized in that the piezo element ( 3 ) via a manipulation circuit ( 4 ) with the security module ( 1 ) is connected. 6. Arrangement according to claim 5, characterized in that the manipulation circuit ( 4 ) consists of a capacitor ( 41 ). 7. Arrangement according to claim 1 and 6, characterized in that the security module ( 1 ) is designed as a non-volatile memory, the ground input (0 V) with a connection of the capacitor ( 41 ) and the piezo element ( 3 ) is connected. 8. Arrangement according to claim 2, characterized in that the actuating element ( 5 ) is also designed as an electrical switch. 9. Arrangement according to claim 7 and 8, characterized in that the actuating element ( 5 ) is designed as a sequence switch which, after tripping, the potential coating (D) of the piezo element ( 3 ) with the potential terminal (B) of the capacitor ( 41 ) and then connects it to the write input (WE) of the security module ( 1 ). 10. The arrangement according to claim 2, characterized in that the closure ( 23 ) consists essentially of a metallic box ( 230 ) with a hollow cylinder ( 235 ) made of a non-conductive plastic and a threaded screw ( 237 ) and that in the box ( 230 ) both the piezo element ( 3 ) and its actuating element ( 5 ) are arranged. 11. Arrangement according to 1 and 10, characterized in that
that the housing ( 2 ) from a housing cap ( 21 ), a housing base ( 22 ) and the closure ( 23 ) is composed,
that the box ( 230 ) is placed laterally with its opening on the housing base ( 22 ),
that the threaded screw ( 237 ) projects through the housing cap ( 21 ) and the housing base ( 22 ) into the hollow cylinder ( 235 ),
that the actuating element ( 5 ) is designed as a metallic spiral spring which is pushed onto the outside of the hollow cylinder ( 235 ) and one end ( 52 ) of which is anchored in an insulated manner in the socket ( 230 ), while the other, free end ( 51 ) is on one adjustable rack ( 231 ) made of a non-conductive plastic, which is guided with play transversely to the hollow cylinder ( 235 ) in a bore ( 2353 ) of the cylinder jacket ( 2351 ),
that the rack ( 231 ) is in engagement with a pinion ( 236 ) which is rotatably arranged in the cylinder bore ( 2352 ) and is provided with a threaded hole ( 2361 ) for the threaded screw ( 237 ),
that the connection between pinion ( 236 ) and rack ( 231 ) in the direction of a stop ( 232 ) is designed as a friction or slip clutch and away from it as a tooth clutch. 12. Arrangement according to 10 and 11, characterized in that the piezo element ( 3 ) is fixed with its one covering on a support ( 31 ) in the form of a metallic leaf spring, which in turn is conductively fastened in the can ( 230 ) so that the free end of the piezo element ( 3 ) lies in the path of movement of the free end ( 51 ) of the coil spring. 13. Arrangement according to claim 12 and 9, characterized in that
that in the path of movement of the free end ( 51 ) of the coil spring after the free end of the piezo element ( 3 ) is a metallic stop ( 233 ) which is fixed in an insulating bush ( 234 ) in the socket ( 230 ) and which is used as a switch contact (C ) is electrically connected to the write input (WE) of the security module ( 1 ) and
that the coil spring forms both the switching arm and a switching contact (B) which is electrically connected to the potential connection of the capacitor ( 41 ) by means of a further insulating bush ( 234 ).