JPH0721957U - Operation control device - Google Patents

Abstract

(57) [Abstract] [Purpose] To further extend the remote operation distance between the key and lock device in the operation control device. A lock device 11, a key 13 for mechanically unlocking the lock device 11, a first resonance circuit 14 fixed to a key head 13c of the key 13 and comprising a series circuit of a capacitor 15 and a coil antenna 16. , Locking device 1
The oscillator circuit 22 and the second resonance circuit 26, which are attached to the first coil antenna 22 and include the coil antennas 22a and 26a;
2 and the second resonance circuit 26, and the operation control circuit 20 that generates an output when the second resonance circuit 26 detects the resonance of the first resonance circuit 14, and is driven by the output of the operation control circuit 20. The controlled device 21 for unlocking or locking the locking device 11 is provided, and the crystal oscillator 17 is connected in parallel with the capacitor 15 of the first resonance circuit 14. Since the Q value of the resonance circuit is dramatically increased by connecting the crystal resonator 17 to the first resonance circuit 14, the remote operation distance can be further extended.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a lock device, and more particularly, to an operation control device that combines a mechanical lock device and an electronic lock device using a remote control signal.

[0002]

[Prior art]

 For example, as disclosed in Japanese Examined Patent Publication No. 4-15141, a vehicle key device in which a key coil provided on a key and a rotor coil provided on a lock are magnetically coupled is known. This key device includes an annular core arranged around a key insertion hole of a vehicle lock. A rotor coil is wound around the annular core, and an information detecting signal is supplied to the rotor coil by the signal generating means. The signal transmitted to the rotor coil is detected by the signal detecting means. The control means fetches the output signal of the signal detection means, compares the information based on this output signal with the determination information, and outputs the engine drive permission signal to the engine drive section only when the contents of both match. The key that can be inserted into the key insertion hole of the lock has a shaft core that is close to the annular core at two locations to form a magnetic circuit when the key is inserted, and a rotor coil and a magnet that are wound around the shaft core when the key is inserted. It has a key coil to be coupled and an information generating means for generating a signal containing specific information from the key coil in response to the signal induced in the key coil.

When the key is inserted into the key insertion hole of the lock and the axial core is brought close to the annular core to form a set of magnetic circuits, the signal from the signal generating means is transmitted to the key coil via the rotor coil. Induced. When the information generating means responds to this signal, a signal containing specific information is generated from the key coil. When this signal is induced in the rotor coil, this signal is detected by the signal detection means and supplied to the control means. The control means compares the information based on the output signal of the signal detection means with the determination information, and outputs the engine drive permission signal to the engine drive section only when the contents of the two match.

In this vehicle key device, information for driving the engine is exchanged by magnetically coupling the lock-side annular core and the key-side shaft-shaped core, and the information from the key-side is transferred to the lock-side. Since the engine can be driven only when the information matches the information, the circular core and the axial core do not have to detect the information due to the adhesion of dust or read the wrong information by operating the keys. The engine can be reliably driven by magnetic coupling with.

However, the above-described vehicle key device has a drawback that the device is upsized because both the key and the lock use annular cores. In addition, since the signal transmission distance is short in the electromagnetically coupled remote control, there is a problem that the desired magnetic coupling cannot be obtained unless the shaft-shaped core provided on the key is sufficiently brought close to the lock-shaped annular core.

In order to solve the above-mentioned drawbacks, the applicant of the present invention has proposed an operation control device which is not known but is disclosed in, for example, Japanese Patent Application No. 4-210543. This operation control device comprises a lock device, a key for mechanically unlocking the lock device, a first resonance circuit fixed to the key head of the key and comprising a series circuit of a capacitor and a coil antenna, and a lock device. And an oscillation circuit including a coil antenna, a second resonance circuit attached to the lock device and including the coil antenna, and an operation control circuit connected to the oscillation circuit and the second resonance circuit. The operation control circuit drives the oscillation circuit at a plurality of different frequencies, the second resonance circuit causes the first resonance circuit to resonate at the particular frequency, and the second resonance circuit causes the first resonance circuit to resonate at the first resonance circuit. The resonance of the circuit is detected, and accordingly, the operation control circuit sends a drive signal to the controlled object.

When the key is inserted into the locking device and rotated, the locking device is mechanically unlocked. The locking device is electrically unlocked via the remote control signal by electromagnetic inductive coupling between the first resonant circuit and the second resonant circuit of the locking device. In this operation control device, since the core is not used for the first resonance circuit, the oscillation circuit of the lock device, and the second resonance circuit, the structure of the key and the lock device can be simplified and the device can be downsized. Further, the lock device can be electrically unlocked by the key from a position sufficiently separated from the lock device by electromagnetic induction coupling between the first resonance circuit and the second resonance circuit of the lock device.

[0008]

[Problems to be solved by the device]

 By the way, in the above operation control device, since the first resonance circuit provided in the key and the oscillation circuit and the second resonance circuit provided in the lock device are composed only of the capacitor and the coil antenna, The Q value could not be increased so much, and there was a limit. When the Q value of the resonance circuit is small, the coupling coefficient (mutual induction coefficient) between the first resonance circuit on the key side and the second resonance circuit on the lock device side becomes small, and the sensitivity for detecting resonance decreases. Therefore, since the electromagnetic inductive coupling between the first resonance circuit on the key side and the second resonance circuit on the lock device side cannot be increased, the detection sensitivity of resonance cannot be improved, and therefore the transmission / reception distance of the remote control signal is further increased. There was a drawback that could not be lengthened. By the way, since the longest effective operating range of the key of the operation control device and the lock device is about 2 to 10 cm, the installation location of the oscillation circuit and the second resonance circuit is the lock device. There is also the inconvenience of being limited to the vicinity of the key insertion hole.

Therefore, the present invention provides an operation control device capable of further increasing the transmission / reception distance of a remote operation signal between the key and the lock device by dramatically increasing the Q value of the resonance circuit. The purpose is to

[0010]

[Means for Solving the Problems]

 An operation control device according to the present invention comprises a lock device, a key for mechanically unlocking the lock device, a first resonance circuit fixed to a key head of the key and comprising a series circuit of a capacitor and a coil antenna, An oscillation circuit attached to the lock device and including the coil antenna; a second resonance circuit attached to the lock device and including the coil antenna; and an operation control circuit connected to the oscillation circuit and the second resonance circuit. The operation control circuit drives the oscillating circuit at a plurality of different frequencies, and when the oscillating circuit is driven at a specific frequency and the first resonant circuit resonates with the specific frequency, the second resonant circuit operates as the first resonant circuit. The resonance of the resonance circuit is detected, and accordingly, the operation control circuit sends a drive signal to the controlled object. In this operation control device, a vibration element having a mechanical vibrator is connected in parallel with the capacitor or the coil antenna of the first resonance circuit.

The oscillator circuit intermittently outputs outputs of different frequencies according to the output of the operation control circuit. The output of the operation control circuit causes the oscillator circuit to generate an output with a continuously changing frequency. The oscillation circuit and the second resonance circuit of the lock device are composed of individual coil antenna-condenser circuits. The oscillation circuit and the second resonance circuit of the lock device are composed of the same coil antenna-capacitor circuit.

In the illustrated embodiment, the lock device has a cylinder lock, and when the key inserted into the key hole of the cylinder lock is rotated to the start position, a drive signal is applied from the operation control circuit to the oscillation circuit. It

[0013]

[Action]

 By connecting a vibrating element having a mechanical oscillator in parallel with the capacitor or the coil antenna of the first resonance circuit, the Q value of the resonance circuit is dramatically increased. Therefore, once the oscillating circuit and the first resonant circuit resonate at a specific frequency and the resonant current flows through the first resonant circuit, a comparison is made with the conventional resonant circuit consisting of only the capacitor and coil antenna. Then, the resonance current continues to flow. Therefore, the resonance of the first resonance circuit can be easily detected by the second resonance circuit, so that the transmission / reception distance of the remote operation signal between the key and the lock device can be further increased.

[0014]

【Example】

 An embodiment of an operation control device according to the present invention applied to a vehicle lock device having a cylinder lock will be described below with reference to FIGS. As shown in FIG. 1, an operation control device 10 according to the present invention includes a lock device 11 having a cylinder lock 11a, a transmission / reception circuit 12 having the coil antennas 22a and 26a attached to the lock device 11, and a lock device 11. A key 13 for mechanically locking or unlocking the cylinder lock 11a is provided. The key 13 includes a key blade 13b having a notch 13a for giving a key code, a key head 13c formed at an end of the key blade 13b, and a first resonance circuit 14 fixed to the key head 13c. Is equipped with. The first resonance circuit 14 is composed of a coil antenna-capacitor circuit in which a capacitor 15 and a coil antenna 16 are connected in series, and a crystal oscillator 17 as a vibrating element having a mechanical oscillator is provided at both ends of the capacitor 15. It is connected. The coil antennas 16, 22a and 26a are respectively wound on the ferrite bars 16a, 22b and 26b. As shown in FIG. 2, the capacitor 15 of the first resonance circuit 14, the coil antenna 16, and the crystal oscillator 17 are mounted and wired on one surface of the printed board 18. The first resonance circuit 14 resonates when a remote operation signal having a constant frequency is received due to the combination with the capacitor 15 and the coil antenna 16 or the natural frequency of the crystal oscillator 17. The first resonance circuit 14 is housed in a resin case 19 having a lid 19a.

FIG. 3 is a block diagram showing an electric circuit of the operation control device of the present invention. An operation control circuit 20 is provided in the lock device 11, and terminals of the operation control circuit 20 are connected to a transmission / reception circuit 12 and an actuator (controlled body) 21 such as a relay for driving a starter motor of an automobile. The transmission / reception circuit 12 has an oscillation circuit 22 including a coil antenna 22a, a relay 23, a relay control circuit 24, and a frequency sweep oscillator 25, and the oscillation circuit 22 is driven by the output of the operation control circuit 20. The transmitting / receiving circuit 12 includes a second resonance circuit 26 including a coil antenna 26a, an AM detection circuit 27 that detects the output of the second resonance circuit 26 in synchronization with the frequency of the frequency sweep oscillator 25, and an AM detection circuit 27. A waveform shaping circuit 28 for shaping the output signal waveform of the above into a rectangular pulse shape and applying this signal to the operation control circuit 20 as a resonance detection signal.

In the above structure, when the key 13 is inserted into the key hole 11b of the cylinder lock 11a in the lock device 11 and rotated, the lock device 11 is mechanically unlocked. Further, when the key 13 is rotated to the start position, a drive signal is applied from the operation control circuit 20 to the frequency sweep oscillator 25 and the relay control circuit 24 in the oscillation circuit 22. In this case, FIG. 4 the frequency f ₁ of the frequency sweep oscillator 25 continuously changes as shown in _{(A), f 2, f} 3, ····, relay control circuit 24 in synchronism with the output of the f _n is Driven as shown in FIG. 4B, the relay 23 is turned on and off. Therefore, it is possible to intermittently generate a plurality of outputs of different frequencies from the oscillation circuit 22. At this time, when the first resonance circuit 14 resonates at the frequency f ₂₀ , the first resonance circuit 14 resonates when the oscillation circuit 22 generates a signal at the frequency f ₂₀ . At the same time, a resonance current flows in the first resonance circuit 14, and energy is accumulated in the first resonance circuit 14 including the crystal oscillator 17. In this embodiment, since the crystal oscillator 17 is connected in parallel with the capacitor 15 of the first resonance circuit 14, as shown in FIG. 6, the resonance characteristics of the resonance circuit 14 of this embodiment are the same as those of the conventional resonance circuit. It is sharper than the characteristics. Therefore, since the Q value of the resonance circuit increases dramatically, the resonance current of the first resonance circuit 14 continuously flows, and the energy stored in the first resonance circuit 14 is retained for a relatively long time. You can When the first resonance circuit 14 resonates, it is connected to the second resonance circuit 26 by electromagnetic induction so that the second resonance circuit 26 resonates, and as shown in FIG. 4 (C), the second resonance circuit 26 resonates. To do. The output waveform of the second resonance circuit 26 at this time is, as shown in FIG. 5B, a waveform delayed by the time t _D from the output waveform of the frequency sweep oscillator 25 shown in FIG. 5A. Is approximately equal to the echo waveform from the first resonant circuit 14. The delay time t _D is proportional to the overall Q value of the crystal resonator 17, the capacitor 15, and the coil antenna 16 in the first resonance circuit 14 in the key 13. The output signal of the second resonance circuit 26 is detected by the AM detection circuit 27 in synchronization with the frequency of the frequency sweep oscillator 25, and the output signal of the AM detection circuit 27 has a constant level as shown in FIG. 4 (D). Rise beyond. The output signal of the AM detection circuit 27 is sent to the waveform shaping circuit 28, and the waveform shaping circuit 28 shapes the waveform into a rectangular pulse as shown in FIG. 4 (E), and this signal is used as a resonance detection signal. Twenty. As a result, the operation control circuit 20 gives an unlocking signal to the actuator 21 and operates the actuator 21. For example, the actuator 21 is a relay that energizes the starter motor.

In the above-described embodiment, since the crystal oscillator 17 is connected in parallel with the capacitor 15 of the first resonance circuit 14 in the key 13, the Q value of the resonance circuit is dramatically increased, and the first resonance circuit The energy stored in 14 can be retained for a relatively long time. Therefore, even if the distance between the first resonance circuit 14 in the key 13 and the transmission / reception circuit 12 in the lock device 11 is long, the resonance of the first resonance circuit 14 is caused by the second resonance circuit 26. In effect, the actuator 21 can be operated reliably. The key difference of the key 13 can be set by connecting the crystal resonator 17 having a different natural frequency to the first resonance circuit 14.

The embodiment of the present invention is not limited to the above-mentioned embodiment, and can be modified. For example, although the oscillation circuit 22 of the transmission / reception circuit 12 and the second resonance circuit 26 are configured as separate circuits in the above embodiment, the oscillation circuit 22 and the second resonance circuit 26 are formed by the same coil antenna-capacitor circuit. Can be used by one. In this case, the operation control circuit 20 gives an output to the transmission / reception circuit 12 to drive the coil antenna-capacitor to oscillate as an oscillation circuit, and then the operation control circuit 20 is switched to set the coil antenna-capacitor to the second resonance. It can also be used as a circuit. Further, in the above-described embodiment, as shown in FIG. 4, the output of the operation control circuit 20 is configured to intermittently output a plurality of outputs of different frequencies from the oscillation circuit 22. The oscillator circuit 22 may generate an output having a continuously changing frequency. In this case, the relay 23 and the relay control circuit 24 in the circuit of FIG. 3 are unnecessary. Although the crystal oscillator 17 is connected in parallel with the capacitor 15 of the first resonance circuit 14 in the above embodiment, the crystal oscillator 17 may be connected in parallel with the coil antenna 16. Further, a ceramic oscillator may be used instead of the crystal oscillator.

In the above-described embodiment, an example in which the invention is applied to a lock device attached to an automobile is shown. However, the invention can be applied to a lock device other than the automobile, for example, a lock device for a luggage locker or other operation control device. It's obvious.

[0020]

As described above, in the present invention, the Q value of the resonance circuit is dramatically increased by connecting the vibration element having the mechanical oscillator to the resonance circuit on the key side having the coil antenna and the capacitor. It is possible to extend the remote control distance further. Therefore, there is an advantage that the degree of freedom of the installation place of the oscillation circuit and the resonance circuit on the lock device side increases.

[Brief description of drawings]

FIG. 1 is a perspective view of an operation control device according to the present invention applied to a vehicle lock device having a cylinder lock.

FIG. 2 is a perspective view showing the configuration of the key head shown in FIG.

FIG. 3 is a block diagram showing an electric circuit used in the operation control device of the present invention.

FIG. 4 is a waveform diagram showing output signals of various parts when the circuit of FIG. 3 is in resonance.

5 is a partially enlarged view of the waveform of FIG.

FIG. 6 is a graph showing resonance characteristics of a conventional resonance circuit and a resonance circuit according to the present invention.

[Explanation of symbols]

10. ． ． Operation control device, 11. ． ． Locking device, 1
2. ． ． Transmitter / receiver circuit, 13. ． ． Key, 14. ． ． First
Resonance circuit of 15. ． ． Capacitors, 16, 22a, 2
6a. ． ． Coil antenna, 17. ． ． Crystal oscillator (vibration element), 18. ． ． Printed circuit board, 20. ． ． Operation control circuit, 21. ． ． Actuator (controlled body), 2
2. ． ． Oscillator circuit, 23. ． ． Relay, 24. ． ． Relay control circuit, 25. ． ． Frequency sweep oscillator, 26. ． ．
Second resonance circuit, 27. ． ． AM detection circuit, 28. ． ．
Wave shaping circuit

Claims (6)

[Scope of utility model registration request] 1. A lock device, a key for unlocking the lock device mechanically, a first resonance circuit fixed to a key head of the key and comprising a series circuit of a capacitor and a coil antenna, and attached to the lock device. And an oscillation circuit including a coil antenna, a second resonance circuit attached to the lock device and including the coil antenna, and an operation control circuit connected to the oscillation circuit and the second resonance circuit, and the operation control circuit is different. When the oscillation circuit is driven at a plurality of frequencies, the oscillation circuit is driven at a specific frequency, and the first resonance circuit resonates with the specific frequency, the second resonance circuit detects the resonance of the first resonance circuit. As a result, the operation control circuit sends mechanical signals to the controlled object in parallel with the capacitor or coil antenna of the first resonance circuit in the operation control device. Operation control apparatus characterized by connecting the vibrating element having a. 2. The operation control device according to claim 1, wherein the oscillation circuit and the second resonance circuit of the lock device are composed of individual coil antenna-capacitor circuits. 3. The operation control device according to claim 1, wherein the oscillation circuit and the second resonance circuit of the lock device are composed of the same coil antenna-capacitor circuit. 4. The operation control device according to claim 1, wherein the oscillation circuit intermittently outputs outputs of different frequencies according to the output of the operation control circuit. 5. The operation control device according to claim 1, wherein the oscillation circuit generates an output having a frequency that continuously changes according to the output of the operation control circuit. 6. The lock device has a cylinder lock, and when the key inserted into the key hole of the cylinder lock is rotated to the start position, a drive signal is applied from the operation control circuit to the oscillation circuit. ~ The operation control device according to any one of claims 3.