HU197456B - Circuit arrangement for alarming apparatuses - Google Patents

Abstract

Field of the Invention The present invention relates to a switching arrangement for an alarm device comprising an alarm unit (s) connected to a thyristor operated from a power supply unit (1). It is an object of the invention that the first thyristor (Th1), the first time delay unit (2) and the second time delay unit (3) connected to the power supply unit (1) are connected in parallel and the cathode and control electrode of the first thyristor (Thl) is a secondary coil of a first transformer (Trl) connected to the primary coil of the first transformer (Trl) by a series of switching contacts (MKa), and together there is a resistor (R8) and a capacitor (C3) connected in parallel to the power supply unit (1). in parallel with the serial RC circuit capacitor (C3), and the output of the first time delay unit 20 (2) is connected to the control electrode of the second thyristor (Th2), which control electrode and cathode of the second thyristor (Th2) are on the secondary coil of the second transformer (Tr2) and the second transformer ( Tr2) prime coil is also connected in parallel to the serial RC circuit capacitor (C4) consisting of resistor (R7) connected to the power supply and capacitor (C4) and the anode of the second thyristor (Th2) directly to one of the terminals of the power supply unit (1). and the second time delay unit (2, 3) common to the common point and the exciter coil of the relay (MR) connected to the other terminal of the power supply unit (1), further comprising a third extinguishing thyristor (Th3) which is parallel to the resistor ( RIO) and a circuit consisting of a capacitor (C6) are connected in series to the power supply unit (1) and the control electrode of the third thyristor (Th3) is connected to the output of the second time delay unit (3), and the second thyristor (Th2) and the third thyristor are connected. (Th3) cathode is a serial RC tag having a resistor The l (R9) diode (D3) is connected in parallel and the alarm unit (s) are connected to the relay (MR) contacts. (1st to 2nd) 197456 -1-

Description

The present invention relates to a circuit arrangement for an alarm device comprising an alarm unit (s) connected to a thyristor powered from a power supply.

The sad fact is that they are breaking into more homes and holiday homes.

Although excellent locks are manufactured, this does not appear to be a sufficient barrier to burglars. For this reason, the objects to be protected are also recently equipped with various alarm systems. 10 Some of these provide an audible alarm when the door is tensioned by closing contacts, while others, and these more expensive devices, operate sensitively to infrared or ultrasound movement in the space to be protected. Both systems can operate from a battery or from a lighting network. When the battery is powered from the battery, it does not matter how much .watcher the standby power is. If they have 20 mains power supplies, you can simply disarm the network by turning off the power. In modern rental homes, the meters are always located outside the apartment, so you can disarm the alarm system by disconnecting the network before the burglar starts operating.

Another problem is turning them off and on. If this can be done outside the object with a hidden switch, it can be monitored and the burglar can disarm it after the field visit. We also don't have enough phone lines to let the nearest police station know about a violent intrusion and act upon 35 burglars. It would also not be safer for the owner of the CB radio to find out about an unauthorized guest via this, because his location may be more than 10 kilometers away from his apartment and by the time he reaches 40, he would only find his plundered apartment.

With all these negative facts in mind, the invention was invented, which, while not providing 100% security, has 45 impacting the burglar's state of mind with unexpected and delayed alarms, and secondly, if a burglar does, substantial help with a photo of the burglar provides law enforcement agencies for 50 subsequent investigations. It is also indifferent how much one can obtain this relative security.

Accordingly, the present invention provides a circuit arrangement for an alarm apparatus comprising alarm units connected to a thyristor operated from a power supply 55, and wherein the first thyristor, the first time delay unit and the second time delay unit 60 are connected in parallel and the first thyristor and a second transformer secondary winding connected to its control electrode, the contact connected to the primary winding of the first transformer being connected in series 65 and connected in parallel to a capacitor of a series RC circuit consisting of a resistor and capacitor connected in parallel to the power supply; output is connected to a control electrode of a second thyristor, which control electrode and cathode of the second thyristor are second transformer secondary is connected to a coil and the primary winding of the second transformer is also connected in parallel to the capacitor of a serial RC-circuit consisting of a resistor and capacitor connected to the power supply, and the anode of the second thyristor directly to one of the power supply terminals connected via a relay excitation coil to the other terminal of the power supply, the circuit arrangement further comprises a third resistor thyristor connected in parallel to the power supply by a circuit consisting of a resistor and a capacitor, and the control electrode of the third thyristor is connected to the second time delay unit. , and a serial RC member is inserted between the cathode of the second thyristor and the third thyristor, a resistor of which is connected in parallel with a diode and the alarm unit heads) are connected to the contacts of the relay.

Preferably, the alarm unit is an audible unit, such as a siren, and / or the alarm unit is a light unit, such as a lamp.

Preferably, an automatic camera is also attached as an alarm unit.

It is further preferred that the time delay implementing units comprise a two-base diode, wherein the emitter of the two-base diode is connected to a divider consisting of a resistor and a capacitor, and a single resistor is connected to the two bases.

In a further preferred embodiment, any number of switching contacts are connected in parallel to the primary circuit of the second transformer driving the second thyristor.

The invention will now be described in more detail by way of exemplary embodiments, in the accompanying drawings. The

Figure 1 is a block diagram of a circuit arrangement according to the invention, a

Figure 2 is a more detailed drawing of an exemplary embodiment.

Figure 1 is a block diagram of a circuit arrangement implementing the recognition of the present invention. The circuit arrangement includes a power supply unit 1 for supplying each unit, which comprises a DC voltage source U and a commissioning switch K connected in series with it. Other components of the circuit are electrically connected to the non-common points of the U DC source and the K switch. These individual components are: a series circuit consisting of an R8 resistor and a capacitor C3, wherein the capacitor C3 is connected in series with the primary winding of the first transformer Tr-1 and a switch contact MKa. A secondary winding of the first Tri transformer is coupled between the cathode and the control electrode of the first Thl thyristor. The anode of the first thyristor Thl is connected to a direct current source U, while its first and second time delay units 2 and 3 are connected in series with its cathode and one of the terminals of the second time delay unit 3 is connected to the commissioning switch K. The third component, which is coupled in parallel with the power supply 1, comprises a second series RC path comprising R7 resistor and capacitor C4. Here, the capacitor C4 is connected in series with the primary winding of a second transformer Tr2 and a switch contact MK1. The secondary winding of the second Tr2 transformer is coupled between the control electrode and cathode of the second Th2 thyristor, which is the second Th2 thyristor anode for the DC source and cathode at the common point of the two series-connected units 2 and 3 and via a K switch. An RC circuit comprising a serial resistor R9 and a capacitor C5 and a parallel resistor RIO and a capacitor C6 is connected between the second thyristor cathode of Th2 and the power supply unit 1, whereby the R9 resistor of the serial RC circuit is open to the cathode of the second Th2 thyristor. Diode D3 is connected in parallel.

At the common point of the capacitor C5 and the RIO resistor is the cathode of a third thyristor Th3. The anode of the third Thyristor Th3 is connected to the power supply 1 and the control electrode is connected to the output of the second time delay unit 3.

Figure 2 is a drawing of an exemplary embodiment of the present invention showing that unit 2 and unit 3 are similarly formed with bipolar diodes D4 and D5, and unit R3 connected to the first thyristor thyrode cathode of the first time delay unit 2; a resistor connected in series with a capacitor C1 and having a common point between capacitor C1 and resistor R3 connected to the emitter of a bipolar diode D4. A resistor R1 is connected to one of the bases of the bipolar diode D4, which is also connected to the cathode of the first thyristor Th1, and to its second base is connected a resistor R2 which is coupled to a capacitor C1.

The structure of the unit 3 implementing the second time delay is the same as the first unit. Here is 4

A resistor R6 and a capacitor C2 are connected to the emitter of a two-base diode D5, while a resistor R4 is connected to one base and a resistor R5 is connected to the other base.

In this exemplary embodiment, the output of the first time delay unit 2 is connected via diode D1 to the control electrode of the second thyristor Th2, and the output of the second time delay unit 3 to the third thyristor controller Th3 is also connected to diode D2.

In the exemplary embodiment of Fig. 2, the contacts of the MR relay can be connected to any actuator, such as an audible alarm unit, a light detector unit, or even an automated device for capturing a photo of a burglar. Figure 2 also shows contact switches MK1 ... MKn that can be connected to individual windows or other break-in points in the housing. These MK1 ... MKn contact switches are connected in parallel so that closing any one of them will activate the unit. Between the cathode of the first Thl thyristor and the power supply 1, an LD1 LED can be connected via resistor R12, which gives a light signal. Resistor R11 is connected in parallel with resistor R3 and condenser C1.

The operation of the circuit arrangement according to the invention is as follows:

When the front door is opened or energized, the switch contact MKa of the microswitch, preferably fitted therein, closes and capacitor C3 charged via resistor R8 is discharged through the first transformer Tri, i.e. voltage is applied to the first transformer Tri through the secondary winding of the first transformer Tri. first thyristor and turns it on. When the first Thl thyristor is energized, that is, it is powered, the first time delay unit 2 receives power supply. The time constant of unit 2 is selected such that when the owner returns home, i.e. opens the door, it is time to turn off the circuit by turning off the arming switch K. If this does not occur, such as by an unauthorized person, then the output signal of the 2 units will elapse after the time created by the 2-unit time constant, which is practically a period of grace

Through diode D1, this can be omitted, the second thyristor Th2, which has a cathode connected to the MR relay excitation coil, is switched on and actuated. The MR relay pulls in and contacts the appropriate alarm, siren, camera, light, CB transmitter, etc. activates. When the second Th2 thyristor starts to drive, it also extinguishes the first Th1 thyristor and thereby turns off the first unit that delivers the first time delay. However, since unit 3 is coupled to the cathode of the thyristor Th2, it remains on. At the same time as the MR relay excitation coil is energized, the second time delay unit 3 is energized and, depending on the time constant set, fires a third thyristor Th3, acting as a resistor, on the C5 and capacitor R9 It deactivates the second Th2 thyristor through diode D3. As a result, the MR relay releases and disables the alarm units. The third Th3 thyristor goes out after the quenching pulse is generated. This is achieved so that the value of the R10 resistor is selected such that the current flowing through the third thyristor Th3 is below its holding current. The whole circuit is switched off and the closed thyristors ensure that there will be no power consumption.

Of course, the triggering of a new impulse will cause the alarm unit to turn on again. However, this triggering pulse can occur not only through the switch contact MKa, which is located at the door or front door, but also through any of the switch contacts MKI ... MKn. In this case, capacitor C4 is charged through resistor R7 and starts the second thyristor Th2 through the second transformer Tr2. The MR relay will then pull on without delay and switch on the alarm units. There is no need for a grace period for the MKI ... MKn switch contact located on a window or other non-entrance door. An unauthorized intruder will break the window so that he can open it afterwards. However, there is a need for a time delay at the front door in order to allow a person who is lawfully in a position to disarm the alarm system.

On exit, the C4 capacitor cannot charge due to the closed state of the front door switch. From the outside - out of sight - it then turns on the arming switch K and sets up the system. After the door has been closed, the MKa switch contact on the door is opened and the device is again suitable for charging the capacitor C3, ie for installing the alarm units.

Advantages of the circuit arrangement according to the invention are as follows:

It works with state-of-the-art thyristor technology, which does not require the installation of heat and humidity sensitive structural elements (such as electrolytic capacitors, etc.) as opposed to conventional transistor systems.

It is turned on and off inside the object to be protected and not visible from the outside, so it is tamper protected.

The multi-pair MR relay allows you to operate other electronic equipment than the siren, possibly via power switches such as reflectors, or directly on the phone, UHF transmitter, etc.

In the event of an intrusion attempt, after a specified period of time, the alarm is turned off, but it returns to the "monitoring position", so that it does not deplete the battery or unnecessarily disturb the environment. Thus, if the burglar would give up his intention to intrude as a result of the alarm being triggered, he would be alerted again in a later attempt.

At the same time as the alarm siren is triggered - that is, after a delay time, an appropriately positioned camera and a flash can be used to record the intruder.

Independent of the lighting network, there is no need for a battery that requires constant maintenance - which is costly - because it has no power consumption in the "monitor" position. thus, 3 so-called so-called operation systems flat element for long months.

Claims (6)

PATENT CLAIMS A circuit arrangement for an alarm device comprising an alarm unit (s) coupled to a power supply operated thyristor, characterized in that a first thyristor (Thl), a first time delay unit (2) and a second time delay unit connected in series to the power unit (1). (3) is connected in parallel, and a secondary winding of a first transformer (Tri) is connected between the cathode and the control electrode of the first thyristor (Th1), the switch winding (MKa) of which is connected in series with the primary winding of the first transformer (Tri); connected to the power supply unit (1) in parallel with a series RC circuit capacitor (C3) consisting of a resistor (R8) and a capacitor (C3), and the output of the first time delay unit (2) is connected to a control electrode of a second thyristor (Th2) and the second thyristor (T h2) is connected to the secondary winding of the second transformer (Tr2) and the primary winding of the second transformer (Tr2) is also connected in parallel to the capacitor (C4) of the series RC circuit consisting of a resistor (R7) and a capacitor (C4) connected to the power supply (1), and the anode of the second thyristor (Th2) is directly at one of the terminals of the power supply unit (1), cathode at the common point of the first and second time delay units (2, 3) and through the excitation coil (MR) of the relay (MR) coupled, the circuit arrangement further comprises a third extinguisher thyristor (Th3) connected in series with a parallel circuit of a resistor (RIO) and a capacitor (C6) connected to the power supply (1) and a third thyristor (Th3) controller its electrode is connected to the output (3) of the 10 time delay units, and a serial RC member is inserted between the cathode of the second thyristor (Th2) and the third thyristor (Th3), with a resistor (R9) diode (D3) connected in parallel, and the relay unit (s) the relay (MR). contacts. A circuit arrangement according to claim 1, characterized in that it comprises an alarm unit, such as a siren, as an alarm unit. The circuit arrangement according to claim 1 or 2, characterized in that the alarm unit comprises a light signaling unit, such as a lamp. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that an automatic camera device is also connected as an alarm unit. 5. Circuit arrangement according to any one of claims 1 to 3, characterized in that the time delay implementing units (2, 3) comprise a bipolar diode (D4, D5), wherein the emitter of the bipolar diode (D4 and D5) is a resistor (R3 and R6) and a capacitor. Cl and C2) are connected to a stationary divider, while the two bases are connected to a resistor (R1 and R2, respectively R4 and R5) and output to the first base. 6. A switching arrangement according to any one of claims 1 to 4, characterized in that any number of switching contacts (MK1 ... MKn) are connected in parallel to the primary circuit of the second transformer (Tr2) driving the second thyristor (Th2). 2 drawings, 2 figures