JPH01250572A - Magnetic memory system lock - Google Patents

Abstract

PURPOSE:To prevent the make of a copy of a key and to secure the originality as the key to increase the safety by renewing a new magnetic code for a magnetic substance of the key through a magnetic code renewal means in case of locking and changing the code every time in case of locking. CONSTITUTION:A key (b) provided with a magnetic substance (a), a magnetic reader section (c) of the magnetic substance (a) accepting the key (b), a magnetic code renewing section (d) for the magnetic substance (a), and a key cylinder (f) having an electromagnetic lock (e) to prevent the operation of unlocking are provided. A code collation means (g) unlocking the electromagnetic lock (e) by collating a code with a memorized code in advance, a random number generation means (h) to generate a new code at random and a magnetic code renewal means (i) are provided. A new magnetic number is rewritten for the magnetic substance (a) of the key (b) through the magnetic code renewal means (i) in case of locking, and the new code is filed in the code collation means (g) to make a code collation with the new code in case of next unlocking.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a magnetic memory lock that is unlocked using a pre-stored magnetic code, and more particularly to a magnetic memory lock in which the magnetic code is updated each time the lock is locked.

BACKGROUND TECHNOLOGY In general, each vehicle such as a car is equipped with its own ignition key, and by inserting the ignition key into a key cylinder inside the vehicle and rotating it, the engine can be turned on, that is, the ignition switch can be unlocked. It is possible.

By the way, the above-mentioned ignition key has uniqueness due to its shape and magnetic code using magnetic material.
Diversion to third parties is prevented.

Problems to be Solved by the Invention However, although such conventional ignition keys are unique, their shape or magnetic code is fixed, and it is difficult to copy the ignition key to a third party. If a copy key is made using a lock key, the lock can be easily unlocked using the copy key, and the safety of the lock is compromised.

Therefore, in view of such conventional problems, the present invention provides a magnetic memory type lock that uses a magnetic code as an unlocking method and changes the magnetic code each time the lock is locked, thereby preventing unlocking using a copy key. 1. The purpose is to provide.

Means for Solving the Problems In order to achieve the above object, the magnetic memory lock of the present invention, as shown in FIG. and the key (b), the magnetic reading part (C) of the magnetic body (a), the magnetic code rewriting part (d) to the magnetic body (a), and the key (
b) A key cylinder (f) equipped with an electromagnetic lock (e) that prevents the unlocking operation, and a magnetic code of the magnetic body (2L) detected by the magnetic reader (c), which is manually read in advance. a code verification means (g) that releases the electromagnetic lock (e) when the codes match and enables the key (b) to be unlocked; Random number generation means (h) that detects that the locked position is set from the position and randomly generates a new code, and converts the darkness generated by the random number generation means (h) into a magnetic code. and output it to the magnetic code rewriting unit (d),
It is constituted by providing a magnetic code updating means (i) for rewriting a new magnetic code in the magnetic body (a) and storing the new magnetic code in the code verification means (g).

Effects With the above configuration, in the present invention, when the lock is locked, a new magnetic code is rewritten on the magnetic body (a) of the key (b) via the magnetic code updating means (i), and the new magnetic code is Since the magnetic code is stored in the code checking means (g), code checking is performed using the new magnetic code the next time the lock is unlocked.

Therefore, even if a copy key is created, once the lock is unlocked and locked, the magnetic code will be completely different, making it impossible to unlock with the copy key.

In addition, the new magnetic encryption mentioned above uses random number generation means (h)
Therefore, it is completely impossible for a third party to predict a new magnetic code.

Example Hereinafter, embodiments of the present invention will be described in detail based on the drawings.

That is, FIGS. 2 and 3 show an embodiment of the magnetic memory lock according to the present invention, and an example in which the magnetic memory lock is applied to an ignition switch 10 of an automobile will be described below.

The ignition switch IO includes a key cylinder 12 that is attached to the vehicle body side such as an instrument panel or a steering column, and an ignition key 14 that is removably received in a key hole 12a of the key cylinder 12.
It is equipped with

As shown in FIG. 2, the ignition switch 10 has an OFF position, a accessory position B, an ON position C, and a starter position determined by the rotation angle of the ignition key 14 inserted into the key hole 12a. be done.

At the OFF position A, all electrical systems are disconnected, at the accessory position 22B, the indicator lamp and radio electrical systems are short-circuited, at the ONN position, the ignition coil electrical system is short-circuited, and at the starter position 111D, the starter motor Actuation takes place.

When the engine is running, it is in the ONN position (starter position only when starting), and when the ignition key 14 is returned to the accessory position B from this engine operating state, the engine is stopped, and the ignition is moved to the OFF position. The key 14 is attached and detached.

Therefore, in the ignition switch IO, from the perspective of engine operation, the ON position C is the unlocked position, and the accessory position B is the locked position.

The ignition key 14 is an insertion portion that is received in the key hole 12a as shown in FIG. 4&, the unlocking shape portion 16 uniquely set in advance (in addition, this unlocking shape portion 16
is not necessarily necessary. ) and a magnetic body 18 in which a magnetic code can be rewritten.

On the other hand, around the keyhole 2a of the key cylinder 12,
The ignition key 1 received in the key hole 12a
A magnetic reading section 20 and a magnetic code rewriting section 22 are provided facing the magnetic body 18 of No. 4, and an electromagnetic lock 24 is provided at the bottom of the key cylinder 12.

The electromagnetic lock 24 has a lock pin 24b urged in the locking direction by a tension spring 24a, and is disposed opposite to one end of the lock pin 24b, and an excitation ON signal causes the lock pin 24b to resist the urging force of the tension spring 24a. The solenoid 24c moves to unlock the ignition key 14.

The magnetic reading unit 20 is connected to a code matching means 26, and detects the magnetic code written on the magnetic body 18 of the ignition key 14 inserted in the OFF position of the ignition switch 10, and The detected code is output to the code matching means 26.

The code verification means 26 is provided with a storage unit 28, in which the magnetic code is stored in advance, and the code verification unit 26 stores the stored code in the storage unit 28 and the magnetic read The read code detected by the unit 20 is verified (compared).

Further, the code verification means 26 is connected to the solenoid 24.0 of the electromagnetic lock 24, and turns on the solenoid 24c when the stored code and the read code match.
A signal is output, and the electromagnetic lock 24 is released.

On the other hand, the ignition switch IO is provided with a random number generating means 30 that detects that the ignition key 14 has been rotated from the ON position C to the accessory position B and generates a random number according to the code. There is.

The random number generating means 30 includes an amplifier 3 that amplifies the random number signal output from the random number generating means 30.
2 to the magnetic cryptographic updating means 34.

The magnetic cipher updating means 34 converts the random number signal input thereto into a magnetic cipher signal, outputs it to the magnetic cipher rewriting unit 22, and also outputs it to the cipher verification means 26, and rewrites the magnetic cipher signal of the former. rewriting the code in the magnetic body 18 of the ignition key 14 with a new magnetic code determined by the random number through the unit 22, and storing the new magnetic code in the storage unit 28 of the latter code checking unit 26; The next code verification is performed using this new code.

With the above configuration, the ignition switch 1 of this embodiment
0 will be explained using the flowcharts of FIGS. 4 to 6.

The flowchart in FIG. 4 shows an example of the processing of the control program executed by the code verification means 26. When the ignition key 14 is inserted into the key hole 12a of the key cylinder 12 to start the engine, this is first detected in step I; If the judgment is YES, the code matching circuit is closed in the next step (■).

Then, the magnetic code of the magnetic body 18 read by the magnetic reader 20 provided in the key cylinder 12 is read in step
In the next step (2), it is determined whether the detected magnetic code and the code stored in advance in the storage unit 28 match. If YES, the process proceeds to step V, where the electromagnetic lock 24 is turned ON ( Excitation) signal is output to release the lock.

Therefore, by releasing the electromagnetic lock 24 in this way, the ignition key 14 can be rotated, and the engine can be started by rotating the ignition key 14 to the starter position and driving a starter motor (not shown). Can be done.

Furthermore, after starting the engine, the ignition key 14 should be turned on.
It is set to position C.

By the way, No in the above step ■ and the above step ■
If it is determined that
Outputs an OFF (, emotion) signal to the electromagnetic lock 2.
The locked state of 4 is maintained.

On the other hand, the flowchart shown in FIG.
The accessory-position B or OFFFF position color is set from position C, and when the accessory-position B is set or the accessory-position B is passed, step X detects this.

Then, the random number generating means 30 performs the next step ℃
A random number corresponding to the magnetic code to be written in the magnetic material 18 is generated, and in the next step (2), this random number signal is outputted to the magnetic code updating means 34 via the amplifier 32.

The flowchart in FIG. 6 shows an example of the processing of the control program in the magnetic encryption updating means 34. When a random number signal is input from the random number generating means 30, this is detected in step XX. Next step XX
I closes the circuit for renovating magnetic cryptography.

Then, in the next step xX■, the random number signal is converted into a magnetic code to create a new magnetic code, and in the next step Along with outputting to
In step χXI'/, the new magnetic code signal is output to the storage section 28 of the code verification means 26.

In this way, by inputting a new magnetic code signal to the magnetic code rewriting section 22, the magnetic body 18 of the ignition key 14 is rewritten with a new magnetic code, and a new magnetic code is written to the storage unit 28. By inputting a code signal, the new code is stored.

Therefore, the next time the ignition key 14 is operated, it will be performed using the new magnetic code, and the engine will be started and stopped by following the same steps as in the flowcharts of FIGS. 4, 5, and 6. The magnetic code of the magnetic body 18 and the memory code of the storage unit 28 are updated each time the engine is stopped.

Therefore, even if the copy key is created by a third party, after at least one engine start from the time the copy key was created, the magnetic encryption of the original ignition key 14 and the magnetic encryption of the copy key will be different. is completely different, and since the electromagnetic lock 24 cannot be released with the copy key, the ignition switch lO
N switching becomes impossible and the engine cannot be started.

Furthermore, since the new magnetic cipher is determined by the random number of the random number generating means 30, it is completely impossible to predict the subsequent magnetic cipher, and the effect of the innovation of the magnetic cipher can be ensured. .

In this embodiment, the case where the magnetic memory lock of the present invention is applied to the ignition switch 10 of an automobile is disclosed, but of course the lock is not limited to the ignition switch 10, and can be applied to, for example, commonly used doors, safes, etc. It goes without saying that the present invention can be applied to locks.

As described in detail about the invention, in the magnetic storage lock of the present invention, the magnetic code written in the magnetic material of the key is rewritten with a new magnetic code each time the lock is locked, making it easy to create a copy key. This can significantly improve the safety of the lock.

In addition, since the above-mentioned new magnetic code is determined by random numbers, it is completely impossible to predict the new magnetic code, which has the excellent effect of ensuring the uniqueness of the lock. .

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram showing the concept of the present invention, FIG. 2 is a schematic configuration diagram showing an embodiment of the present invention with a front view of a key cylinder, and FIG. 2 is a schematic diagram showing the cross section taken along line ■-m in Figure 2, Figure 4 is a flowchart showing an example of the processing of the control program executed by the cryptographic matching means used in the present invention, and Figure 5 is the random code diagram used in the present invention. FIG. 6 is a flowchart showing an example of processing of the control program executed by the number generating means. FIG. 6 is a flowchart showing an example of processing of the control program executed by the magnetic cryptography updating means used in the present invention. 10...Ignition switch (magnetic memory lock),
DESCRIPTION OF SYMBOLS 12... Key cylinder, 14... Ignition key (key), 18... Magnetic material, 20... Magnetic reading part, 22... Magnetic code rewriting part, 24... Electromagnetic lock, 26... ... Code checking means, 28... Storage section,
30... Random number generation means, 34... Magnetic cryptography reforming means. Engraving of drawings by two other authors (no changes in content) Figure 2 Figure 3 Figure 4 Figure 5 Figure 6 Procedural amendment, salmon) May 18, 1932

Claims (1)

[Claims] (1) A key provided with a magnetic material capable of rewriting a magnetic code; and a key that receives the key and blocks a magnetic reading section of the magnetic material, a magnetic code rewriting section for the magnetic material, and an unlocking operation of the key. A key cylinder equipped with an electromagnetic lock, and a magnetic code of the magnetic material detected by the magnetic reading section are compared with a code input in advance, and when the codes match, the electromagnetic lock is released and the key is pressed. a code verification means that enables an unlocking operation; a random number generation means that detects that the key is set from an unlocked position to a locked position and randomly generates a new code; and the random number generation means magnetic code updating means for converting the generated code into a magnetic code and outputting it to the magnetic code rewriting section, rewriting a new magnetic code in the magnetic body, and storing the new magnetic code in the code verification means; and,
A magnetic memory type lock characterized by being provided with.