JPH0358426B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field] The present invention relates to an electric lock system.

[Background technology] Generally, when operating an electric lock, an operation unit sends an on/off signal for the electric lock to open or close a door or other part, but the electric lock cannot be locked even if the door is open. If a (lock) signal was sent, the door would be locked even though it was open, and as a result, if the door was left closed, the door would be destroyed. In addition, even if the door is closed when going out, the user has to lock the door again, which causes trouble and forgetfulness.

[Object of the Invention] The present invention has been provided in view of the above-mentioned points, and provides an electric lock system that is provided with a switch that works with the opening/closing part, locks automatically, and cannot be locked when the opening/closing part is open. The purpose is to

[Disclosure of the Invention] Examples of the present invention will be described below with reference to the drawings.
Figure 1 shows a specific circuit diagram, and 2 is an electric lock circuit, which includes a latching relay Ry ₁ and a diode D ₂ .
~ D ₆ , a lock switch SW ₁ , an unlock switch SW ₂ , etc. The lock switch SW ₁ and the unlock switch SW ₂ are operated to drive the latching relay Ry 1, and the latching relay Ry _{1 is} activated. It opens and closes contacts r ₁ and r ₂ to control the opening and closing of the electric lock. One contact r ₁ of the latching relay Ry ₁ is a diode D _2,
D3 constitutes a so-called remote control relay, and the other contact _r2 turns the electric lock on and off. The latching relay Ry ₁ changes the direction of current flow using the diodes D ₂ and D ₃ and the contact r ₁ . Furthermore, the locking switch SW ₁ and unlocking switch SW ₂ shown in the figure represent relay contacts that are interlocked with the secret switch circuit. Reference numeral 1 denotes a control circuit consisting of a latching relay Ry ₂ , diodes D ₁ , D ₆ , D ₇ , a capacitor C, a door switch SW ₃ that turns on and off in conjunction with the opening and closing of an opening/closing part such as a door, etc. The electric lock is not turned on when the door is open, and the electric lock is automatically locked when the door is closed. _r3 ,
_r4 is the contact point of latching relay _Ry2 . still,
AC is alternating current.

Next, the operation will be explained. In addition, as shown in Figure 2 and below.
LED ₁ and LED ₂ are light emitting diodes for indicating whether the electric lock is unlocked or locked. The resistors R ₁ and R ₂ are not strong enough to drive the latching relay Ry ₁ , but are limited resistors for lighting the light emitting diodes LED ₁ and LED ₂ . Now, the door is open, door switch SW ₃ is off, and contact r ₁ is on the b terminal side.
When the other contacts r ₂ to r ₄ are in the state shown in Figure 2, the electric lock is in the unlocked state, and the capacitor C is connected to the diode D ₇ and the contact r ₄ as shown by arrow 1 from the AC power source AC.
Electric current flows through the battery and charges the battery. At this time again,
As shown by arrow 2, resistor R ₁ , light emitting diode
Current flows to LED ₁ , the coil of latching relay Ry ₁ , diode D ₃ , and contact r ₁ , lighting up light emitting diode LED ₁ , indicating that the electric lock is unlocked. Here, in order to prevent the electric lock from locking even if locking switch SW ₁ is operated, diode D ₁ and contact R ₃ are inserted to prevent current from flowing to latching relay Ry ₁ , and the electric lock is forcibly locked. I'm trying to unlock the electric lock.

Next, when the door is closed, the door switch _SW3 is closed as shown in FIG. 3, a current flows as shown by arrow 1, and the latching relay _Ry2 is driven. Therefore, the contacts r ₃ and r ₄ of the latching relay Ry ₂ are reversed to the b terminal side, and the charge of the capacitor C is transferred to the diode D ₄ ,
Discharge occurs in the loop of latching relay Ry ₁ , diode D ₃ , and contact r ₁ . Therefore the latching relay
Ry ₁ is driven, contact r ₁ is reversed to the a terminal side, contact r ₂ is also reversed and closed, and the electric lock is locked. Also, since the contact r ₁ is reversed to the a terminal side, the current flows through the contact r ₁ , the diode D ₂ , the coil of the latching relay Ry ₁ , and the light emitting diode as shown by arrow 3 in Figure 3.
The light emitting _{diode LED 2 lights} up to indicate that the electric lock is locked. Of course, the current at this time is limited by the resistor _R2 , and the latching relay _Ry1 is not driven.

Next, the case where the electric lock is unlocked in a locked state will be explained with reference to FIG. unlock switch
When SW ₂ is turned on, current flows to contact R ₁ , diode D ₂ , latching relay Ry ₁ coil, unlock switch SW ₂ , and diode D ₄ as shown by the arrow.
Drives latching relay Ry ₁ . Therefore, the contact
At the same time, r ₁ is reversed to the b terminal side, contact r ₂ is also opened, and the electric lock is unlocked. Also, at this time, current flows to the light emitting diode LED ₁ , the latching relay Ry ₁ , the diode D ₃ , and the contact r ₁ as shown by arrow 2.
The light emitting diode LED ₁ will be lit to indicate that the electric lock is unlocked.

Additionally, when the door is closed, turn the lock switch.
The case where SW ₁ is turned on will be explained with reference to FIG. When lock switch SW ₁ is turned on, contact R ₃ , diode D ₄ , lock switch SW ₁ ,
Coil of latching relay Ry ₁ , diode D ₃ ,
It flows to contact r ₁ and drives latching relay Ry ₁ . Therefore, the contact _r1 of the latching relay _Ry1 is reversed to the a terminal side, and the contact _r2 is closed to lock the electric lock. When contact r ₁ is reversed to the a terminal side, contact r ₁ , diode D ₂ , and latching relay are connected as shown by the arrow.
Current flows to the coil of Ry ₁ and light emitting diode LED ₂ , lighting up light emitting diode LED ₂ , indicating that the electric lock is locked. In this way, when the door is closed, the electric lock can be locked using the lock switch _SW1 .

[Effects of the Invention] As described above, the present invention provides an electric lock system in which an electric lock attached to an opening/closing part of a door or the like is turned on by a lock switch and turned off by an unlock switch. The first switch opens and closes the contact in the direction of the current flowing in the opposite direction when each switch is turned on, and maintains the state of the contact.
latching relay, the first contact of the first latching relay that switches the first and second diodes that regulate the direction of the current flowing through the excitation coil of the first latching relay, and the first contact of the first latching relay that switches on the electric lock. ,
The second contact of the first latching relay is turned off, the door switch is linked with the opening/closing part and turns off when the opening/closing part is open, and the contact is driven by the AC power when the door switch is turned on to open/close the contact. a second latching relay that maintains the state of the contact when the electric lock is off and the door switch is off, a capacitor that is charged by the AC power supply when the electric lock is off and the door switch is off, and a capacitor that cuts off the current to the lock switch when the door switch is off. a first contact of a second latching relay that is
A third diode blocks current from flowing to the latching relay, and when the door switch is on, the second latching relay is energized and the charge in the capacitor drives the first latching relay. A second latching relay that turns on the second contact of the latching relay to turn on the electric lock.
When the door switch is on, the second latching relay is driven and the first contact of the second latching relay is switched to enable power to be applied to the locking switch, and the locking switch or unlocking switch is activated. Since the electric lock is turned on and off by a switch, when the opening/closing part such as the door is open, the door switch is off.
The second latching relay is not energized, so the current to the lock switch is cut off at the first contact of the second latching relay, so even if the lock switch is turned on, , electric locks are not locked, so even if the opening/closing part is closed, the opening/closing part will not be damaged unlike conventional ones, and when the opening/closing part is closed and the door switch is turned on, the second The latching relay is energized,
The second contact of the second latching relay switches, the charge in the capacitor energizes the first latching relay, turns on the second contact of the first latching relay, and this second contact The electric lock can be turned on by turning on the electric lock, and the electric lock can be automatically locked by closing the opening/closing part on the outside.
Automatic locking has the effect of eliminating the need to forget to close the opening/closing part. Furthermore, since it is constructed from latching relays, capacitors, diodes, etc. without using any IC parts, it is highly resistant to noise and has the advantage that there is very little risk of malfunction due to noise.

[Brief explanation of drawings]

FIG. 1 is a specific circuit diagram of an embodiment of the present invention, and FIGS. 2 to 5 are explanatory diagrams of the same operation. SW ₁ is a lock switch, SW ₂ is an unlock switch,
SW ₃ is the door switch, Ry ₁ is the first latching relay, r ₁ is the first contact, r ₂ is the second contact, Ry ₂ is the first latching relay, r ₃ is the first contact, r ₄ is the second contact, D ₁ is the third diode, D ₂ is the first
diode, _D3 is the second diode, AC is the alternating current power source.

Claims (1)

[Claims] 1 In an electric lock system in which an electric lock attached to an opening/closing part of a door, etc. is turned on by a locking switch and turned off by an unlocking switch, the electric current flows in the opposite direction when the unlocking switch and locking switch are turned on. A first latching relay that opens and closes a contact depending on the direction of the current and maintains the state of the contact, and first and second diodes that regulate the direction of the current flowing through the excitation coil of the first latching relay. The first contact of the first latching relay that switches, the second contact of the first latching relay that turns on and off the electric lock, and the second contact of the first latching relay that operates in conjunction with the opening/closing part and turns off when the opening/closing part is open. a second latching relay that is driven by AC power when the door switch is turned on and opens and closes the contacts to maintain the state of the contacts; a first contact of a second latching relay that interrupts current to the lock switch when the door switch is off; A third diode blocks current to the latching relay, and when the door switch is on, the second latching relay is energized and the charge stored in the capacitor drives the first latching relay. second relay
and a second contact of a second latching relay that turns on the contact of the door switch to turn on the electric lock. Switch the first contact to enable power to be applied to the lock switch side,
An electric lock system characterized in that an electric lock is turned on and off by a locking switch or an unlocking switch.