JPH082341Y2 - Electric lock control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of use] The present invention relates to an electric lock control device for controlling to unlock and lock an electric lock.

[Conventional technology]

Conventionally, code locks are used in lockers and storages in addition to fireproof safes, but in the case of fireproof safes, in order to unlock the code lock and open the safe door, a dial provided on the safe door Was unlocked by rotating the dial to the predetermined number on the scale plate to the left and the number of times to the right, and then opening the safe door.

[Problems to be solved by the device]

As described above, in the conventional code lock, it is necessary to accurately store the number of dials that should be rotated to the right or left of the code lock at the time of unlocking. . Further, if the user forgets how many times he or she has turned during unlocking, or turns too many times, there is the inconvenience of having to start over from the beginning.

The present invention solves the above problems and makes it easy to adjust the dial for unlocking operation.In addition, the current for operating the electric lock is reduced during the unlocking period to improve the battery life required for unlocking work. An object is to provide an electric lock control device that lengthens.

[Means to be solved by the invention]

The above object of the present invention is achieved by an electric lock control device whose construction is shown in FIGS. The device is a rotary that sends out an A-phase pulse train signal and a B-phase pulse train signal having a 90-degree phase difference for creating a PIN with an arbitrary number of digits by rotating one end protruding from the surface of the safe door 1 as a dial. The encoder 2 and the A-phase and B-phase pulse train signals are input, controlled by an output signal of a rotation direction detection circuit 41 that determines whether the rotation of the encoder 2 is clockwise or counterclockwise, and applied from the rotary encoder 2. The A-phase output signal to be added is added when it is determined that the rotation direction detection circuit 41 is rotating clockwise and is subtracted when it is determined to be counterclockwise rotation. At the time of addition, the value next to the value "99" is set to "0".
The addition / subtraction counting circuit 42 controlled by the reset circuit 40 for counting "0" and resetting with the first pulse from the rotary encoder 2 and the first storage means for storing the personal identification number output from the addition / subtraction counting circuit 42 RAM3
And a dial numeral display 16 for displaying the input data stored in the RAM 3, and a second for storing the registration code of the safe user.
RAM5 as storage means, ROM6 as third storage means for storing a hidden number known only to the safe meter, and input data in RAM3 as the first storage means described above as the second storage means.
Of the input data collating circuit (7) for sequentially collating the stored data in the RAM 5 as the storing means of the above or the ROM 6 as the third storing means and sending out an output signal only when they match. A parallel circuit of a semiconductor switch 10 and a high resistance element 11 that are conductive when receiving an output pulse signal that continues for an unlockable time t, a semiconductor switch 12 that is conductive when receiving an output pulse that continues for an unlocking allowable time T, and an electromagnetic solenoid. An electromagnetic solenoid drive circuit 8 for freely moving the lock 21 attached to the safe door 1 engaged with the safe body, a dry battery 9 as a power source, and the above dry battery. The voltage comparison circuit 44 having a hysteresis circuit that changes the threshold voltage of the voltage of 9 and the voltage value of the reference voltage source 43 according to the history of changes in the input signal.
When the voltage of the dry cell 9 is within the specified drop voltage value range, the unlocking indicator light 19 is made to blink by the blinking circuit 44, and the buzzer 33 is alarmed when the voltage falls below the specified drop voltage value range. It is composed of a low voltage detection circuit 35 for generation.

[Action]

According to the present invention, the safe user rotates one end of the rotary encoder 2 as the dial 2a to store the personal identification number in the RAM 3 as the first storage means and the dial number display 16 to store the personal identification number. Display the PIN code. Further, the input data collating circuit 7 sequentially reads the registration number of the safe user stored in the RAM 5 or the ROM 6 as the second storing means, collates it with the personal identification number in the RAM 3 as the first storing means, and matches it. Only when the solenoid 13 in the electromagnetic solenoid drive circuit 8 is energized for the unlockable time t, and at the same time, the current is reduced by the unlocking allowable time T having a longer duration to activate the dry battery as a power source. Lengthen.

〔Example〕

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 4 (A), the fireproof safe is provided with a dial 2a attached to one end of the rotary shaft of the rotary encoder 2 and a display substrate 15 on the front side of the safe door 1, and the end of the safe door 1. 6V dry battery 9,9 as a power source is attached to the part, and dial number indicator 16, confirmation switch 1 on the display board 15
7. A hidden number calling switch 18, an unlocking indicator light 19, and a setting indicator light 20 are attached. Also, as shown in FIG. 4 (B), a safe box lock 21 is attached to the side surface of the safe door 1, and a CP not shown on the back side of the fireproof safe door 1.
The U board 22 is attached.

FIG. 5 is a control command system diagram of the electric lock. As shown in FIG. 5, this command system device is incorporated in the CPU board 22 and mounted on the back side of the safe door 1, and is displayed on the front side of the safe door 1. Board
It is connected to the equipment built into the 15.

The microcomputer 24 is a ROM for storing a program for operating the computer, and a RAM3 as a first storage means for storing the personal identification number of the safe user, which is calculated by the pulse signal transmitted from the rotary encoder 2.
And RAM _5a , RAM as second storage means for storing registered personal identification numbers of two safe users (for example, master and wife).
_{In addition} to the RAM 5 having _5b , the timing pulse oscillation circuit 23 is also connected to the reset circuit 25 which is operated by the initial customer number setting switch 26 to reset the arithmetic circuit of the microcomputer 24, and the calling switch 27. ROM6 and electromagnetic solenoid drive circuit 8 as a third storage means for storing a personal identification number for use in an emergency (for example, when a customer forgets his or her personal identification number) known only to a safe maker.
An electromagnetic solenoid that engages with the body of the safe via the lock and restrains or releases the movement of the Kannuki 21 attached to the safe door 1.
13 are connected. The microcomputer 24 includes a rotary encoder 2 provided on the front side of the metal door 1 via a waveform shaping circuit 26, a dial number display 16 for displaying a personal identification number via a display drive circuit 16a, and an unlocking indicator light 1
9, setting display 20, buzzer 33 that operates when dry battery 9 drops below 3.6V via buzzer switch 32,
Further, a confirmation switch for activating the buzzer 33 when the secret code displayed through the switch input circuit 31 is correct.
A low-voltage detection circuit 35 for the dry battery 9 is connected via 17, a hidden number calling switch 18, a dry battery 9 for power supply, and a voltage detection switch 34.

An end of the rotary encoder 2 is rotatably attached to the surface of the safe door 1, and a dial 2a is attached to this end. The rotary encoder 2 belongs to the publicly known, and an example of the configuration thereof is one in which a radial through hole is formed along the entire circumference of a disk provided orthogonal to the rotation axis to rotate the upper air rotation axis. Based on this, the movement of the through hole is photoelectrically detected, and the rotation angle of the rotation shaft is output as a pulse train signal.
The rotary encoder 2 used in the present embodiment outputs two pulse train signals of A phase and B phase having a 90-degree phase difference by using two sets of the through hole and the photoelectric means. FIG. 6 (A) shows a pulse train signal when the dial 2a of the encoder is rotated clockwise, and the phase of the A phase pulse is 90 degrees behind that of the B phase pulse.
Indicates two pulse train signals when the dial 2a of the rotary encoder is rotated counterclockwise, and the A-phase pulse leads the B-phase pulse by 90 degrees.

Further, the dial 2a of the rotary encoder of this embodiment is
In case of rotating 360 degrees, as an example, A pulse train, B pulse train
Each pulse train produces 40 pulses. The above 40
When a pulse is input, the microcomputer 24 displays a numerical value of 40.
Is displayed and “40” is displayed on the dial numeral display 16.

The dial 2a of the rotary encoder is rotated by a safe user in a clockwise or counterclockwise direction according to a personal identification number, and the personal identification number in this embodiment is composed of an arbitrary number of digits. For example, the security code is "12345678" 8
Assuming that it is a digit, enter the PIN number "12" when unlocking.
The rotary encoder dial 2a is used to send the separated two-digit number to the microcomputer 24 by dividing the lowest-order number into two digits such as "34", "56", "78".
Is rotated clockwise or counterclockwise, and when the highest digit "12" is displayed on the dial numeral display 15, the rotation of the dial 2a is stopped. By this stop, the dial number display 16 is sequentially displayed as 0, 1, 2 ... 12 and is sequentially displayed as 99, 98 ,. The number 99 means the maximum number in the two-digit number.

If the personal identification number is 7 digits of "1234567", it is divided as "1""23""45""67".
In addition, since the original position of the dial 2a is not provided when the dial 2a is rotated, the operation of "returning to the original position" is not required.

In this embodiment, the microcomputer 24 has the following functions.

When the A-phase pulse train signal and the B-phase pulse train signal for the two most significant digits of the personal identification number sent from the rotary encoder 2 are received, it is determined whether the rotary direction of the rotary encoder 2 is clockwise or counterclockwise. However, the following formula N = a × 100 + b × A However, in the clockwise rotation, a = 0, b = 1 In the counterclockwise rotation, a−1, b = −1 A is 2 according to the pulse number of the pulse train signal A. A function for calculating the numerical value N of digits and storing the calculated numerical value in the RAM 3 as the first storage means and simultaneously displaying it on the dial numeral display 16.

It is visually confirmed by the safe user that the PIN code of the highest division displayed above is correct, and when the confirmation switch 17 is pressed, the buzzer sounds to let the safe user confirm, and the PIN codes of the succeeding divisions are also sequentially the same. Functions that act on.

The safe user's registration number stored in the RAM 5 as the second storage means or the registered personal identification number known only to the safe manufacturer stored in the ROM 6 as the third storage means are sequentially read out to the input data matching circuit 7. , A function of comparing with a personal identification number stored in the RAM 3 as the first storage means and sending a control signal to the electromagnetic solenoid drive circuit 8 when they match.

The voltage across the dry battery 9 is compared with a reference voltage, and when the dry battery falls within a predetermined voltage value range, the unlocking indicator light blinks as a battery dead notice, and when the dry battery falls below the predetermined voltage value range, the battery runs out. Ability to do.

A function of supplying a required current to the drive circuit 8 of the electromagnetic solenoid 13 for an unlockable time t and reducing the supplied current during an unlockable time.

 Next, the operation of this embodiment will be described.

FIG. 7 is a flowchart of the microcomputer 24.

Safe user rotates the dial 2a of the rotary encoder 2 in accordance with personal identification code (Step S _1). The low-voltage meter reading circuit 35 measures the voltage of the dry battery 9 as a power source and judges whether or not the specified voltage value 6V is held (step S ₂ ).
When 6V is held, the rotation direction of the rotary encoder 2 is judged and pulse counting is performed (step
S ₇ ), when it is determined that the voltage value of the dry battery 9 is within the range of ₄ V to 3.6 V (step S ₄ ), the unlocking indicator light 19 is blinked (step S ₅ ), and it is determined that the voltage is 3.6 V or less. the stopper mode by actuating the buzzer 33 (step S _6). Step
In S _7, when the pulse count is completed, safe user presses the confirmation switch 17, and the buzzer 33 is sounded as "beep" by pressing the switch, to confirm (step
S ₈ ), then it is determined whether all the secret codes have ended (step S ₉ ), and if it has ended, the confirmation switch 17 is pressed to sound the buzzer 33 (step S ₁₀ ), and all the secret codes are If you determine that it is not finished,
Return to before S ₇ . Confirmed in step S ₁₀ switch 17
When is pressed, it is determined whether or not the numeric value by the operation of the rotary encoder 2 and the secret code match (step S
_11), matching unlocked in indicator 19 and simultaneously drives the magnetic solenoid 13 when had is lit (step S _12),
After a predetermined time the stop mode (step S _14). In step S _11, the buzzer 3 when not match
3 is the ringing to stop mode (step S _13).

[Effect of device]

Since the present invention is configured as described above, it has the following effects.

The dial of the rotary encoder was rotated to generate a predetermined data signal, and the PIN was formed by this signal.Therefore, as in the conventional method, the dial of the dial code lock was rotated right and left many times. There is no need to move it to match the target scale number, and the locking and unlocking operation became easier.

Since the password for unlocking the safe door is provided for two persons, there is the convenience that, for example, the master and the wife, the manager and the sub-manager can use their own passwords.

Since a secret number that is managed by the safe maker side and not disclosed to the public is also provided as a personal identification number, by notifying the manufacturer even in an emergency such as when the customer forgets his / her own number,
It can be unlocked through sales companies.

As a power source, dry batteries are used, and when the voltage drops to the specified level, the battery replacement notice display and battery replacement display are provided, so the batteries can be replaced before the battery life and the secret code stored in the storage device will be erased. You don't have to.

It can be widely used as a control device for electric locks in lockers, storage cabinets, etc. in addition to safes and fireproof cabinets.

[Brief description of drawings]

1 to 3 are views showing the constitution of the present invention,
FIG. 1 is a block diagram showing the structure of the present invention, and FIG. 2 (A).
Is an electromagnetic solenoid drive circuit diagram, FIG. 2 (B) is an explanatory diagram of the timing of its drive current waveform, FIG. 3 is a low voltage detection circuit diagram for detecting the voltage of a dry cell as a power source, and FIGS. 4A and 4B are views relating to the embodiment of the present invention, wherein FIG. 4A is a front view of a safe as this embodiment, and FIG.
Is a side view thereof, FIG. 5 is a configuration block diagram of the present embodiment, and FIG. 6 (A) is a voltage waveform diagram showing a relationship between phases of two pulse train signals when the dial of the rotary encoder is rotated clockwise. FIG. 6 (B) is a voltage waveform diagram of two pulse train signals when rotating counterclockwise,
FIG. 7 is a flowchart for unlocking the personal identification number of the microcomputer. 1 ... Safe door, 2 ... Rotary encoder, 3 ... RAM as first storage means, 5 ... RAM as second storage means, 6 ... ROM as third storage means, 7 ... Input data collation circuit, 8 Electromagnetic solenoid drive circuit, 9
…… Batteries, 10,12 …… Semiconductor switch, 11 …… High resistance element, 13 …… Electromagnetic solenoid, 15 …… Display board, 16 ……
Dial number display, 17 …… Confirmation switch, 18 …… Hidden number call switch, 19 …… Unlocking indicator, 20 …… Setting indicator, 21 …… Kanuki, 22 …… CPU board, 24 …… Microcomputer 25 ... Reset circuit 26 ... Initial number setting switch 27 ... Call switch 30 ... Display drive circuit 33 ... Buzzer 35 ... Low voltage detection circuit 40 ...
… Reset circuit, 41 …… Rotation direction detection circuit, 42 …… Addition / subtraction counting circuit, 43 …… Reference voltage source, 44 …… Voltage comparison circuit,
45 …… Blinking circuit.

Claims (5)

[Scope of utility model registration request] 1. An A-phase pulse train signal and a B-phase pulse train signal having a 90-degree phase difference for producing a personal identification number having an arbitrary number of digits by rotating one end protruding from the surface of a safe door (1) as a dial. Is input to the rotary encoder (2) and the A-phase pulse train signal and the B-phase pulse train signal, and a rotation direction detection circuit (41) for determining whether the rotation of the encoder (2) is clockwise or counterclockwise. ) Output signal, and the A phase output signal applied from the rotary encoder (2) is added by the judgment of the clockwise rotation of the rotation direction detection circuit (41), and is added by the judgment of the counterclockwise rotation. A reset circuit (40) that subtracts and counts the value next to the value "99" as "00" at the time of addition and resets it with the first pulse from the rotary encoder (2).
An addition / subtraction calculation circuit (42) controlled by the RAM, a RAM (3) as a first storage means for storing the personal identification number output from the addition / subtraction counting circuit (42), and a RAM (a first storage means As a dial number display (16) for displaying the input data stored in 3) and a second storage means for storing the registration number of the safe user.
The input data in the RAM (5) and the RAM (3) as the first storage means is collated with the stored data in the RAM (5) as the second storage means, and an output signal is transmitted only when they match. The input data collating circuit (7) and the snapper (21) attached to the safe door (1) engaged with the safe main body in response to the output signal of the input data collating circuit (7) are made movable. An electric lock control device comprising an electromagnetic solenoid drive circuit (8) and a dry battery (9) as a power source. 2. The personal identification number is a pair of personal identification numbers individually assigned to two safe users, and is a registered personal identification number stored in the RAM (5) as the second storage means. 2. The electric lock control according to claim 1, wherein the secret code number sent from the rotary encoder (2) is a secret code number sequentially compared with the secret code number from the safe user in the input data collating circuit (7). circuit. 3. The personal identification number is a personal identification number known only to the safe maker, and the ROM (6) as a third storage means.
And the secret code number sent out from the rotary encoder (2) known only to the safe maker and the secret code number sequentially compared in the input data collating circuit (7). The electric lock control circuit according to claim 1. 4. The electromagnetic solenoid drive circuit (8) is capable of unlocking time (t) from the input data collating circuit (7).
A parallel circuit of a semiconductor switch (10) and a high-resistance element (11) that conducts upon receiving a continuous output pulse signal, and a semiconductor switch (12) that conducts upon receiving an output pulse that continues for an unlocking allowable time (T). The electric lock control circuit according to claim 1, characterized in that the electric lock control circuit is constituted by a series circuit including an electromagnetic solenoid (13). 5. The voltage comparison circuit (44), wherein the dry battery (9) is provided with a hysteresis circuit in which the voltage value of the dry battery (9) and the voltage value of the reference power source (43) differ in threshold depending on the history of changes in the input signal. When the voltage of the dry cell (9) is within the specified voltage drop range, the unlocking indicator light (1
9) blinks and the low voltage detection circuit (3) that activates the buzzer (33) when the voltage falls below the specified voltage drop range.
5. The electric lock control circuit according to claim 1, which is connected to 5).