JP5210790B2 - Electric lock system - Google Patents

Description

  The present invention relates to an electric lock system.

  In Patent Document 1, “an electric lock provided on the door, on the other hand, a control panel provided in a place other than the door and remotely controlling the electric lock; And a plurality of switches connected to the two wires in a state of being connected in series to each other on the electric lock side, and connected in parallel to the switches. A zener diode is provided, and a trigger input portion of the switching element and a zener diode are connected in series to each other on the control panel side, and connected to the two wires, thereby opening and closing a plurality of switches on the electric lock side. An electric lock system that detects a state with a switching element on the control panel side is disclosed.

  The object of the invention described in Patent Document 1 is that this type of electric lock system has a large number of wires (for example, a total of six wires are required), so that the connection between the electric lock side and the control panel to be remotely controlled is 2 It is to be able to do with the wiring of the book, and thus to simplify the construction related to the wiring.

  However, although the invention described in Patent Document 1 has the advantage that the number of wirings is small, the electric lock side corresponds to the monitored side, and the remote control panel corresponds to the monitor side. The control board (control means) on the lock side can self-determine, for example, whether or not it is a signal for unlocking once, whether or not it is a continuous unlocking, the state of the lock or the open / closed state of the door. Can not. Therefore, the invention described in Patent Document 1 needs to correspond to the electric circuit of the control panel that remotely controls the switch configuration on the electric lock side, including the number of wires.

  Further, in Patent Document 2, on the premise of the basic electric lock system described in Patent Document 1, the control means together with the relay means disposed in the door between the electric lock side and the control panel to be remotely controlled. The relay means in the door outputs the lock signal and the unlock signal output from the remote control control panel (signal output means side) to the electric lock side as they are. In addition, the control means on the electric lock side receives a radio wave signal (locking signal or unlocking signal) from a so-called remote controller, and based on the mode of the radio wave signal (locking signal or unlocking signal), It is the structure which outputs to an electric lock as it is.

Therefore, in the invention described in Patent Document 2, as in the invention described in Patent Document 1, the relay means on the control panel side and the electric lock side that are remotely controlled must always not only unlock the signal but also the locking signal. It was necessary to output to the lock. That is, the electric lock itself does not make a self-judgement of the mode of the release signal, the unlocked state, the door open / closed state, and the like.
JP 10-325270 A Japanese Patent Laid-Open No. 10-176446

  An intended purpose of the present invention is that an electric lock system is generally provided with an input to a control means of an electric lock or an electric strike (electric lock side) provided on a door or door frame, for example, on a wall surface of a building. Because it was necessary to connect to each “exclusive port” to accommodate various external devices such as operation indicators, interphones, timers, etc., wiring construction was complicated (so-called many wires) It is to eliminate the wiring construction corresponding to the external equipment as much as possible.

  Further, as described in Patent Document 1 and Patent Document 2, the electric lock system has to complicate each control function of the control means on the electric lock side and the control panel for remotely operating the electric lock. Expertise regarding is required. Therefore, the intended purpose of the present invention is to enable the locking / unlocking of the lock only by the “contact point” and to simplify the configuration of the control means of the electric lock. Etc. is to eliminate the need for specialized knowledge about electric locks.

  In addition, when the unlocking signal for changing the lock state from the locked state to the unlocked state is acquired, the electric lock control means discriminates the single unlock signal or the continuous unlock signal with a simple configuration. Then, the state of the lock is controlled based on the discrimination. In addition, by providing a non-voltage contact output means electrically connected to the control means on the electric lock side on the electric lock side, it is possible to electrically connect simple switches, timers, etc. It is to be able to lock / unlock by the signal output means.

  An electric lock system according to the present invention comprises a no-voltage contact output means provided on a door or a door frame and outputting a single unlock signal and a continuous unlock signal in response to a signal from the signal output means, and the no-voltage contact. It has a control means that is electrically connected to the output means via a signal line, and is composed of an electric lock or an electric strike provided on the door or door frame, and the control means is a single / continuous unlocking thereof. When the signal input unit acquires “some signal” from the no-voltage contact output means, the one-time unlocking signal is a one-shot signal within T time or a continuous unlocking signal exceeding T time If the determination signal is a one-shot signal, the lock state is temporarily changed from the locked state to the unlocked state and then automatically returned to the locked state again. If it is a continuous unlocking signal, Although state from temporarily locked state to the unlocked state, characterized in that continues to hold the lock until obtaining the OFF signal of the continuous unlocking signal to unlock state.

(A) When the one-time / continuous unlocking signal input unit obtains “some signal” from the no-voltage contact output means provided on the door or door frame, the once-unlocking signal is T time Therefore, it is not necessary to give the control means a complicated control function (a difficult program) for the lock.
(B) Since the non-voltage contact output means for electrically connecting to the control means of the electric lock is provided on the electric lock side via a signal line (including a line), the non-voltage contact output means Various signal output means (external devices) such as a timer for a continuous unlocking signal and an interphone for a single unlocking signal can be easily connected. In other words, since it is possible to lock / unlock only by “contact point”, the dealer, the contractor, etc. do not need to have specialized knowledge about the electric lock.
(C) In order to use the present invention, for example, when the remote control panel including a monitoring monitor is disposed at an appropriate position, the electric lock is a prerequisite (locked state). ) Can be confirmed.
(D) The invention according to claim 3 can enable or disable the contact input for an unauthorized unlocking action such as a wiring short circuit that is assumed from the viewpoint of security.

  Hereinafter, the best mode for carrying out the present invention shown in FIGS. 1 to 6 will be described.

(1) Environment for Implementing the Invention FIG. 1 is an electric lock system showing an embodiment of the present invention, and in particular, schematically shows the overall configuration of an electric lock locking system X. 2 and 3 show the main part of the electric lock system X at the implementation level.

  1 to 3, 1 is an electric lock or electric strike (electric lock side 1A), while 2 is a non-voltage contact output means electrically connected to the electric lock or electric strike 1, and 3A is a signal. It is an output means. The electric lock 1 is incorporated in the free end portion of the door 8, and the electric strike 1 is incorporated in a lateral recess of the door frame.

  The no-voltage contact output means 2 is provided on the door 8 or the door frame. The no-voltage contact output means 2 is preferably provided in the lock box (control box) of the electric lock 1 or an appropriate place inside the door when the electric lock 1 is built in the free end of the door 8. Or, it is disposed on the current-carrying metal fitting. Furthermore, a typical example of the signal output means 3 is an operation indicator. The operation indicator 3 is provided on the wall surface of the door or the wall surface of the building, and is a single unlock signal switch 3a and a continuous unlock signal switch. 3b respectively.

  In this embodiment, the signal output means also includes various external devices 3A such as a timer for continuous unlocking signals provided on a wall surface of a building, an interphone for once unlocking signals, and the like. These signal output means 3 and 3A can be connected to the no-voltage contact output means 2 on the electric lock side 1A through a cable (commonly called “wiring”) 6 in a contact manner. The no-voltage contact output means 2 includes, for example, a power supply 4 and an input terminal 5. Of course, the power supply 4 may be a power supply panel connected to the wall of the building or the power supply connected to the no-voltage contact output means 2 via a connection cord instead of the electric lock side 1A. In short, it is sufficient that electricity (voltage) can be supplied from the non-voltage contact output means 2 by the control means 11 on the electric lock side 1A.

  By the way, as shown in FIG. 1, a signal line (wiring) 6 for electrically connecting the no-voltage contact output means 2 of the electric lock 1 is a power line 6a that constantly supplies DC power to the electric lock 1, and two types Two or one signal line 6b for supplying the electric lock 1 with "one-time unlock signal" and "continuous unlock signal", respectively, and the self-information output unit 18 of the electric lock 1 A self-information signal line 6c for supplying information (closing and locking signal) to the no-voltage contact output means 2 and a signal line 6d for the communication port 13 for supplying a message to the control panel (not shown) corresponding to the electric lock 1 It is configured.

  Here, the electrical configuration of the electric lock side 1A will be described with reference to FIG. In this embodiment, the lock is the electric lock 1 attached to the free end of the door 8. The electric lock 1 includes a control means 11 in, for example, a lock box 1a. The control means 11 is generally called a “control board”, but is an information processing unit mainly composed of a so-called microcomputer. Therefore, the control unit 11 has a storage unit (ROM) 12, information stored in the storage unit 12 (information processing shown in FIG. 6), the microcomputer and the communication port 13 correspond to the control unit 11. ing.

  Further, the electric lock 1 has a power input unit 14 and a one-time / continuous unlocking signal input unit 15 for receiving signals on the electric lock side 1A. The power input unit 14 is connected to the control means 11 of the electric lock via the power line 6 a, and the power (drive signal) input to the control means 11 via the power input unit 14 is electrically connected via the output unit 16. It is sent to a drive unit (actuator) 17 inside the lock.

  As is well known, an unlock signal or a lock signal is given to both terminals of the drive unit 17, and a dead bolt (not shown) of the electric lock 1 moves forward and backward from the front of the lock box 1a to engage with the strike (or electric strike 1). escape.

  Furthermore, the electric lock 1 sends self-information (closed and locked signal) from the control means 11 to the non-voltage contact output means 2 on the condition that the self (here, the electric lock 1) returns to the locked state again. Self-information output unit 18. In addition, the communication port 13 described above is also provided.

  In addition, the electric lock 1 includes various known switches (reed switch 19a, micro switch 19b) 19 as shown in FIG. Further, the electric lock 1 has a contact input type valid / invalid changeover switch 20, and this valid / invalid changeover switch 20 enables the contact input for an illegal unlocking action such as a wiring short circuit. Or for invalidation.

(2) Characteristic part of the invention The electric lock system X of the present invention is based on the precondition that the electric lock (hereinafter also referred to as “lock”) 1 is normally locked, and is used for a single unlock signal. The control means 11 provided in the electric lock 1 has two signal lines 6b for the continuous unlocking signal, and the control means 11 provided in the electric lock 1 makes the "some signal" once / continuous unlocking signal input unit 15 through the signal line 6b. When acquired, it is a one-time unlocking signal based on the information of “one-shot signal” stored in the storage unit 12 (T-second information as if one shot of a pistol was fired), or continuous unlocking When it is determined whether the signal is a signal and it is determined that the signal is an unlocking signal once, the electric lock 1 is unlocked for a certain time (T seconds + several seconds) and then for a certain time (for example, 8 seconds). (Seconds) after that, it automatically returns to the locked state again.

  Thus, in the present embodiment, the “some signal” includes a “telegram”, and the control means 11 includes one signal line 6b for unlocking signal and a single / continuous unlocking signal input unit 15. Alternatively, when “some signal” is received through the communication port signal line 6d and the communication port 13, respectively, the storage unit 12 is accessed, and first, “pulse” or “message” is inquired.

  FIG. 4 is an explanatory diagram relating to the lock state, the door state in the lock state, and the “closing and locking signal” when the control means 11 obtains a one-time unlock signal (one-shot signal) that is an example of a pulse. is there.

  As described above, the one-time unlock signal (one-shot signal) is a very short voltage signal such as T-second information, for example, 0.1 second, that is, one shot of a pistol. Since the release signal signal line 6b shown in FIG. 2 is electrically connected to the “no-voltage contact output means 2”, when an unlocking signal flows through the signal line 6b once, the signal line 6b 6b instantaneously increases in voltage. The four rectangular waves in FIG. 2 indicate that a total of four release signals have flowed to the control means 11 via the signal line 6b and the one-time / continuous unlock signal input unit 15.

  When the control means 11 acquires the unlocking signal once, the control means 11 controls the lock state to the unlocked state for a certain time (T seconds + several seconds). Here, the “certain time” means a time sufficient for a person to normally enter and exit, for example, 8 seconds. The solid line part of the rectangular wave indicating the lock state is longer than the solid line part on the ON side of the rectangular wave of the one-time unlock signal. The time for holding the unlock state is the time of the one-time unlock signal. Means longer. Also, the width of the third rectangular wave (the rightmost waveform in the drawing) indicating the lock state is longer than the previous two rectangular waves because the time during which the lock is unlocked (setting) This means that the control means 11 has once again acquired the unlocking signal within (time).

  When the lock is unlocked, the door can be opened as a matter of course. In FIG. 4, after the lock is unlocked, for example, 2 seconds after unlocking, the door opens and remains open until just before a certain period of time, in other words, the door remains within the unlocking time of the lock. Indicates that there was an opening and closing once. In addition, the second and subsequent times indicate that the door has not been opened artificially although the lock has been unlocked based on the first unlock signal. Thus, when the state of the lock is the unlocked state, the door can be opened by attempting to open the door. Also in this embodiment, as in the conventional embodiment, the control means 11 can acquire the door closing signal via the microswitch 19b of the various switches 19.

  By the way, the control means 11 of the electric lock 1 according to the present embodiment provides the “closed and locked” to the non-voltage contact output means 2 via the self-information output unit 18 on the condition that the electric lock 1 returns to the locked state again. "Signal" can be provided, but the generation of the "close and lock signal" corresponds to a single unlock signal and the state of the lock.

  That is, after the control means 11 confirms that there is a single unlocking signal and that the lock is in the locked state, the self-information signal is used as the information on the electric lock 1 (self) (the closed and locked signal). This is applied to the non-voltage contact output means 2 via the line 6c. FIG. 4 shows that a total of three times self-information is given to the control panel side.

  FIG. 5 is an explanatory diagram relating to the lock state, the door state in the lock state, and the “closing and locking signal” when the control means 11 acquires a continuous unlocking signal which is an example of a pulse. The reason why the components of the continuous unlocking signal are taken into account in the present embodiment is the time required for obtaining a “certain time” regarding the unlocking state of the lock as well as the single unlocking signal. However, for example, when the lock is unlocked, the door is opened and closed several times so that people can go in and out many times, and people often go in and out. In light of the empirical rules of daily life, such as opening the required time and opening for a long time for moving, the electric lock 1 is held in the unlocked state for a longer time than the case of the single unlocking signal. This is because, based on the operation of the operation button of the output means, the control means 11 returns to the locked state after acquiring the OFF signal for cutting the continuous signal. Note that, regarding the OFF signal of the continuous signal, the control unit 11 determines that the voltage of the signal line 6b is in a no-voltage state.

  The detailed description of FIG. 5 uses that of FIG. 4. To put it briefly, as in the case of a single unlock signal, when a continuous unlock signal flows through the signal line 6 b shown in FIG. The continuous unlocking signal flows to the control means 11 via the signal line 6b and the once / continuous unlocking signal input unit 15. When acquiring the continuous unlocking signal, the control means 11 controls the lock to the unlocked state for the required time (T seconds + minute unit or time unit) each time. Here, the “required time” refers to a time sufficient to open a door to receive, for example, a stool, and in this example, it is 1 minute or 2 minutes. The solid line part of the rectangular wave indicating the unlocked state of the lock is longer than that of FIG. 4 because the time for holding the unlocked state is much longer than the time for the single unlocking signal. means. In the state of the door, for example, when the lock is unlocked for the first time, it means that the door is opened and closed twice. In addition, the timing which outputs from the self-information output part 18 is the same as that of the case of a once unlocking signal.

  FIG. 6 is a flowchart showing the control content of the electric lock 1. With reference to FIG. 6, a specific configuration relating to signal processing of the present invention will be further described.

  In the present embodiment, it is assumed that the electric lock 1 is in a locked state. Therefore, the initial state on the electric lock 1 side is a locked state and a closed state as shown in FIGS. 4 and 5. This initial state is the same as the last locked state (prerequisite state) of the flowchart of FIG. Therefore, if the operation button 3a for the unlocking signal is pressed once among the operation buttons of the signal output means 3 shown in FIG. 1, the once unlocking signal becomes a high voltage via the signal line 6b. Flows to the electric lock side 1A.

  Therefore, the electric lock (self) 1 is first supplied with a high voltage from the control panel side 2A in the determination step S1 of “signal input?” In which a signal is acquired via the once / continuous unlocking signal input unit 15. It is determined whether or not a signal has flown (whether or not a signal is input). When a high voltage does not flow from the control panel side 2A, the control means 11 determines “NO” and returns to the initial state (holds the locked state).

  On the other hand, when the signal is received by the once / continuous unlocking signal input unit 15 or when the communication port 13 receives the signal “Yes”, in the determination step S2, the “some signal” is “pulse” or “ Judge "message". As described above, the “some signal (voltage or telegram)” includes “telegram” in the present embodiment, and the control means 11 has one signal line 6b for unlocking signal and once / continuous. When “any signal” is received via the unlock signal input unit 15 or the communication port signal line 6d and the communication port 13, respectively, the storage unit 12 first determines whether it is “pulse” or “telegram”. Inquire. Here, when it is determined that the “some signal” is “pulse”, the control unit 11 proceeds to step S3.

  In the determination step S3, the control means 11 determines whether the pulse width is a one-time unlocking signal (T seconds) based on the information of the “one-shot signal” stored in the storage unit 12 or continuous unlocking. It is determined whether the signal is (T seconds or more?).

  Therefore, when the control means 11 determines “Yes (T seconds or more)”, the process proceeds to step S4. On the other hand, when it determines “NO (T seconds)”, the control means 11 proceeds to step S5. Here, since it is assumed that the operation button 3a for unlocking signal has been pressed once, the process proceeds to step S5.

  In step S5, the control means 11 holds (controls) the locked state for a certain period of time as shown in FIG. When the electric lock 1 is in the unlocked state, the door can be opened. Therefore, in step S6, it is determined whether or not “the door is open?”. If the door is opened “Yes” when it is unlocked once, the process proceeds to step S7, where it is determined whether or not the door is closed. In step S7, when the door is closed "Yes", the lock is automatically locked, and when it is determined "NO", the "loop" is repeated.

  On the other hand, when the door is not opened when unlocked once, the process proceeds to step S8, and it is determined whether or not a fixed time (set time) has elapsed. Since the control means 11 is in the unlocked state once (the dead bolt is retracted), after confirming that the set time has elapsed “Yes”, the state of the lock is automatically changed to the locked state. Return (control to lock again).

  On the other hand, when the operation button 3b for the continuous unlocking signal is pressed among the operation buttons of the signal output means shown in FIG. 1, the continuous unlocking signal becomes a high voltage via the signal line 6b. Flows to the electric lock side 1A. That is, the continuous unlocking signal also flows through the signal line 6b in the same manner as when the operation button 3a for the unlocking signal is pressed once. Therefore, the electric lock 1 first acquires a signal via the once / continuous unlocking signal input unit 15, and the following determination step S2 and determination step S3 are as described above.

  In the determination step S3, when the control means 11 determines “Yes (T seconds or more)”, the control unit 11 proceeds to step S4, and the lock is continuously unlocked. Since this continuous unlocked state is the “required time” as described above, the process proceeds to determination step S9. For example, when the reason for pressing the operation button 3b for the continuous unlocking signal is moving, since the required time is considerably long, the control means 11 continues to wait for the OFF signal of the continuous signal for that long time. That is, in the determination step S9, it is determined whether or not there is a continuous signal OFF signal. If “NO” in the determination step S9, the “loop” is repeated. On the other hand, when “Yes”, the process proceeds to the determination step S10 to check whether “closed door?” Exists. If “NO” in the determination step S10, the “loop” in the determination step S9 is repeated. On the other hand, when “Yes”, the lock state is returned to the locked state (control to lock again).

  In this embodiment, the control means 11 of the electric lock 1 has returned to the locked state again, regardless of whether the signal is once unlocked or continuously unlocked. As a condition, a “closing and locking signal” is given to the non-voltage contact output means 2 through the self-information output unit 18 and the self-information signal line 6c. Therefore, when the present invention is used, the control panel side including a monitoring monitor (not shown) can confirm that the electric lock 1 has returned to the precondition.

  By the way, as an additional matter in the present embodiment, there is a case where “some signal” is determined as “telegram” in the above-described determination step S2. In such a case, the flow proceeds to the message side flowchart. Since the specific configuration of the flowchart on the telegram side is not a limiting requirement of the present invention, its details are omitted. The flowchart on the telegram side includes at least a determination step S11 for determining whether or not the communication is on the control panel side (including a monitoring monitor) (not shown), and a determination step S12 for determining whether or not the command is a lock command. In S12, when “NO”, the “loop” is repeated. On the other hand, in the case of “Yes”, the lock state is held in the locked state through the confirmation step S13 in which the door is in the closed state (assuming that when the door is in the unlocked state, the lock is controlled again).

  In the example shown in the embodiment of the invention, the OFF signal of the continuous unlocking signal is based on the operating force on the signal output means 3. The valid / invalid changeover switch 20 is an item that should be taken into consideration because it is intended to validate or invalidate the contact input against an illegal unlocking action such as an expected wiring short circuit. In FIG. 1, the non-voltage contact output means 2 is disposed outside the lock box 1a of the electric lock 1. However, as shown in FIG. In addition, a non-voltage contact output means 2A may be provided. Moreover, the control board of the electric lock 1 may be one or two.

  The present invention is mainly used in the locksmith and joinery industries.

1 to 6 are explanatory views showing the best embodiments of the present invention. FIG. 7 is a schematic explanatory view showing another arrangement example of the no-voltage contact output means.
BRIEF DESCRIPTION OF THE DRAWINGS Schematic explanatory drawing which shows the whole structure of the electric lock system which shows one Example of this invention. The block diagram which shows an electrical structure. The block diagram which shows the principal part of the electric lock system X of an implementation level. Explanatory drawing regarding the state of the lock | rock at the time of a once unlocking signal, the state of a door, and a "close door and locking signal". Explanatory drawing regarding the state of the lock | rock at the time of a continuous unlocking signal, the state of a door, and a "closing door and locking signal". The flowchart which shows the control content of an electric lock. Schematic explanatory drawing which shows the other example of arrangement | positioning of a non-voltage contact output means.

Explanation of symbols

X ... Locking system, 1 ... Electric lock or strike, 1A ... Electric lock side, 2A ... No-voltage contact output means, 3A ... Signal output means, 3a ... Single unlock signal switch (operation button) 3b: Switch for continuous unlocking signal (operation button), 6: Cable (wiring), 6a ... Power supply line, 6b ... Signal line for unlocking signal, 6c ... Self-information signal line, 6d ... Signal for communication port Wire, 8 ... Door, 11 ... Control means, 12 ... Storage part, 13 ... Communication port, 14 ... Power supply input part, 15 ... Single / continuous unlocking signal input part, 16 ... Output part, 17 ... Drive part (actuator) ), 18... Self-information output unit, 19... Various switches, 20.

Claims (3)

A non-voltage contact output means provided on the door or door frame and outputting a single unlock signal and a continuous unlock signal in response to a signal from the signal output means, and via the no-voltage contact output means and the signal line The control means comprises an electric lock or an electric strike provided on the door or door frame, and the control means has a one-time / continuous unlocking signal input section as the no-voltage contact. When “any signal” is acquired from the output means, it is determined whether the one-time unlocking signal is a one-shot signal within T time or a continuous unlocking signal exceeding T time. If the signal is a one-shot signal, the lock state is temporarily changed from the locked state to the unlocked state and then automatically returned to the locked state. On the other hand, when the discrimination signal is a continuous unlocked signal The lock state is temporarily changed from the locked state Although the unlocked state, electric lock system, characterized in that continues to hold the lock until obtaining the OFF signal of the continuous unlocking signal to unlock state. The control means for the electric lock according to claim 1, wherein the electric lock is returned to the locked state again, and the "closed and locked signal" is sent to the non-voltage contact output means via the self-information output unit. An electric lock system characterized by giving. 2. The control means according to claim 1, wherein a valid / invalid changeover switch is electrically connected to the control means. When the changeover switch is in an invalid state, the control means is a one-shot signal or a continuous unlocking signal. An electric lock system characterized by not determining whether or not it is.

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