RU2694992C2 - Sensor button unlocking electric lock - Google Patents

Abstract

FIELD: physics.SUBSTANCE: invention relates to electric lock unlocking sensor button. Button comprises a housing inside which there is a printed circuit board with an electronic circuit. Circuit is configured to be connected to control device for activation of signal for unlocking of electric lock and comprises semiconductor elements, as well as electrically connected to their circuit external sensitive element. Semiconductor elements of the electrical circuit are connected in parallel and include elements of a sensor circuit for processing commands connected by an input to a sensitive element, a switch and a storage capacitor.EFFECT: simplified design of sensor button.3 cl, 2 dwg

Description

The invention relates to the field of electrical engineering and electronics and can be used mainly in access control systems (ACS) for signaling to unlock the electric lock.

For example, in the state of the art, the connection pattern of the electromagnetic door lock is known, in which it is connected to the power supply unit via the ACS controller. A mechanical push out button with a closing (normally open) contact, installed inside the protected area or room, is connected to the controller. To unblock the door, pressing the push button of the exit input of the controller “button” closes to ground, which is a command to the controller to break the power supply circuit of the electromagnetic lock winding (Z-5R controller with Matrix-II EH reader. Operation Guide, http: // www.ironlogic.ru).

In some other schemes for connecting controllers, the lock is latched and the voltage is removed from it. In this case, when pressing the exit exit button, the ACS controller briefly energizes the lock, which causes the door to unlock.

In any case, the command to unblock the door is supplied by closing the normally open contacts connected to the input “button” to the contact “ground” of the access control controller.

The main disadvantage of the known scheme is the low reliability of the push button, which is a mechanical element subject to constant physical impact, oxidation of contacts, etc., which inevitably leads to mechanical wear.

In order to increase reliability and durability, compared with a mechanical exit button, a device such as a touch button can be used in the wiring diagram of an electric lock (for example, according to the RF patent for utility model No. 6452, IPC G05B 7/02, publ. 16.04.1998 g.) comprising a housing with holes for fasteners and an inside printed circuit board with an electronic circuit containing semiconductor elements and, electrically connected to their circuit, an external sensing element.

When the device is triggered, the output contact closes to "ground", which gives the ACS controller a command to open the electric lock. The use of this scheme is able to provide higher reliability and durability compared with a mechanical button.

However, a separate source with an output voltage of 12 V or 24 V is required to power the electronic component circuit, and, consequently, additional functional elements that provide power that generally complicates the design of the touch button, increasing labor costs during production and installation .

The objective of the proposed invention is to expand the Arsenal of technical means of a similar purpose, by creating a touch button that combines functional properties that provide power from a control device and forming at the input of a controller a control signal to unlock an electric lock using a single connector using a two-wire connection circuit. generally simplify the design of the touch button, as well as reduce labor costs in its production and installation.

The task is solved by a touch button unlocking an electric lock having a case inside which a printed circuit board is installed with an electronic circuit made with the ability to connect to the control device to activate the signal to unlock the electric lock and containing semiconductor elements, as well as an external sensing element electrically connected to their circuit This semiconductor elements of the electrical circuit are connected in parallel with each other and include elements of the sensory command processing circuit, under The input to the sensitive element, the switch and the storage capacitor.

In the particular case, the storage capacitor can be connected to the circuit of the electronic elements of the touch button not directly parallel to the input, but through a resistor or diode. This inclusion does not change the principle of operation, but can reduce the discharge current of the capacitor, which will allow the use of a capacitor with a smaller capacity. At the same time, drawdown indicators to the lowest level will also improve.

In addition, the switch can be made, for example, in the form of a transistor switch, which will increase the operating current in the circuit, without the risk of the touch button's electronic circuit failing, or a field-effect transistor, for example, an IRF540 field-effect transistor.

At the same time, to protect the electronic circuit and the transistor switch against voltage surges in the circuit, parallel to the input, in the reverse polarity, diodes, zener diodes, varistors can be installed.

Also, in the particular case, parallel to the input, two LEDs can be connected in series to the electronic circuit of the touch button, which will further stabilize the power supply of the electronic circuit and provide illumination of the external sensing element without additional wires.

In addition, if in the particular case there is a task to make the button circuit do not need to respect the polarity when connected, it is advisable to install a diode bridge at the input of the electronic circuit. In this embodiment, the application of the circuit is free from any controllers, and can be independently used in the electronic circuit of the touch button for switching power circuits of not only electrolocks, but also calls and other actuators. At the same time, the current and switching voltage depends only on the parameters of the electronic component used as a switch. For example, if the field-effect transistor IRF540 is used as a switch, then (in accordance with the reference parameters), the switching current will reach 30 A, and the switching voltage - 100 V.

The invention is illustrated FIG. 1 and FIG. 2 drawings.

FIG. 1 shows the structural block diagram of the ACS consisting of the controller (6) and the touch button (1) connected to it (1), the power source (8) and the electric lock actuator (7).

Figure 2 shows a graph of the retention time of the capacitor at the input of the low potential controller, necessary for the formation of a control signal to unlock the electric lock.

The touch button (1) preferably has a plastic case with holes for fasteners (not shown). Inside the case there is a printed circuit board with an electronic circuit, on which an external sensing element (2) and electrically connected semiconductor elements are mounted, which form a parallel electrical circuit from sequentially installed sensory command processing circuit (3), switch (4) and storage capacitor (5 ) (with a capacity of 100–200 μF). The possibility of implementing the touch button (1) is achieved by interacting with other access control devices shown in FIG. 1 - the controller (6), the actuator (7) of the electric lock and the power supply unit (8). The combination of the above devices forms the simplest access control system, aimed exclusively at solving the problem of opening the door through the proposed touch button. The control device of such a system, directly providing the formation of a signal to unlock the electric lock, is the controller (6). It is a complex device containing a multitude of electronic elements, however, within the framework of the claimed invention, only that set of its elements is considered, which directly ensures the operation of the proposed touch button, namely, power connectors (9), voltage converter (10), connector exit button (11), and a logic chip (12). We will show them on the example of the most well-known “Z-5R” controller from Ironlogic, while not being limited to them, since These elements of the controller, ensuring the formation of the required signal, are not new and are included in the electronic circuits of most ACS controllers.

The operation of the touch button unlock electric lock as follows.

The case of the touch button is mounted on the inside of the entrance door on the surface of the door leaf, either on the door frame or on the wall next to the door, and then connected to the controller (6) via its “exit button” connector (11). The controller (6) is powered through the power supply unit (8) from a standard AC mains voltage of ~ 110 - 220 V with a frequency of 50/60 Hz. The power supply unit (8) converts an alternating current into a constant voltage of 12-24 volts, which is used to supply the controller (6) and the electric lock actuator (7) that are connected to it via the corresponding connectors (9). The controller PCB also has a voltage converter (10) that reduces the supply voltage from 12 to 5 V, which feeds the electronic elements of the circuit, in particular, the logic chip (12), and also the electronic circuit of the touch button (1) from it via the connector “ exit button ”(11), designed to connect the touch button (1). Thus, in the normal operating mode of the controller at the input of the logic chip there is a voltage of about 5 V. At the same time, the logical chip (12) is programmed to accept only 2 signals at the input - a logical “unit” that activates the lock lock signal in the normal mode at the output of the chip, as well as a "zero", which activates at the output of the chip a control signal to unlock the electric lock.

After powering 12 V to the controller (6), there is a constant or pulsating voltage on its “output button” connector (11), about 5 volts. The storage capacitor (5) of the touch button (1) is charged with this voltage, storing the charge, as a result of which the voltage at its terminals is an additional source of voltage sufficient for self-supplying the semiconductor elements mounted on the touch button printed circuit board. When acting on the sensitive element (2) of the touch button (1), the command signal from it is fed to the command processing circuit (3), which, in turn, gives a signal to the switch (4), which closes to ground, that leads to the discharge of the storage capacitor (5) to a logic zero, and then its slow charge, and since the latter is electrically connected to the “exit button” connector (11), this voltage drop at the input of the logic chip (12) is perceived as a command to generate a control signal to unlock the electric lock, in re ultate which produces an immediate lock unlocking doors.

It is of fundamental importance for activating the signal to unlock the electric lock, which has a low electric potential retention time at the input of the logic chip (12), which should be sufficient for its operation. In this regard, the storage capacitor (5) used in the electronic circuit of the sensor button is essential and necessary for the implementation of the proposed technical solution element. When the sensor circuit (3) is triggered, the contacts “+” and “-” of the switch (4) close. As a result, the capacitor is discharged, thus providing for a certain time the retention of low electric potential. After the discharge of the capacitor, the electronic circuit of the touch button is de-energized. As a result, the switch opens again, after which the capacitor immediately switches from the discharge state to the charge state. At the same time, the capacitor retention time of a low electric potential is enough to trigger a logic chip, i.e. receiving at its input a logical "zero" activating the control signal to unlock the actuator (7) to unlock the electric lock.

In order to confirm the possibility of the operation of the scheme of the proposed touch button, FIG. 2 shows a graph, for the example of calculations of which the Ironlogic controller “Z-5R” was taken. The graph shows that the controller hold time at the input in the zero state (200 ms) is the sum of the capacitor discharge time (68 ms) - starting from the threshold voltage (2.87 V) of the logic chip of the controller to the voltage (1.5 V) of the termination the operation of the electronic circuit of the touch button, and the capacitor charge time (132 ms) - to the threshold voltage (2.87 V) of the operation of the logic chip for activation of the control signal supply.

Claims (3)

1. Touch button for unlocking an electric lock, having a case inside which a printed circuit board is installed with an electronic circuit made with the ability to connect to the control device an activation signal for unlocking the electric lock and containing semiconductor elements, as well as an external sensitive element connected to their circuit, that the semiconductor elements of the electrical circuit are connected in parallel with each other and include elements of the sensory command processing circuit connected by the input to the sensor, switch and storage capacitor. 2. Touch button according to claim 1, characterized in that the switch is made in the form of a transistor switch or a field effect transistor, for example, an IRF540 transistor. 3. Touch button according to claim 1, characterized in that the control device for activating the signal to lock / unlock the electric lock is made in the form of a controller or a diode bridge mounted at the output of the electronic circuit.

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