DE1220289B - Receiving circuit for rapid changes in status, preferably capacity changes, responsive alarm devices - Google Patents

Description

Receive circuit for rapid state changes, preferably Capacity changes, responsive alarm devices The invention relates to a receiving circuit for rapid changes in state, preferably changes in capacitance, appealing alarm devices in which a measuring bridge over one from an RC element existing differentiating circuit controls an electronic switch.

Such a receiving circuit mainly requires room protection systems, when an interferer penetrates the area to be protected because of the associated Change in capacitance between the electrodes. Detune the associated measuring bridge and thus activate a connected alarm device. Usually react though such alarm devices not only on an intruding interferer, but also on temperature influences; so speaks z. B. a capacitance relay with one on the Characteristic kink working oscillator in the form of a transistor on each still so slowly occurring change in the measuring capacitance. The transistor collector is connected on the one hand to a grounded battery and on the other hand via the Tuning capacitor to the indicator relay, which is also grounded, and the oscillator coil connected, the other end to the base of the transistor and to the measuring electrode is connected, while a tap .dieser oscillator coil to the transistor emitter is led. Such false positives caused by temperature fluctuations slow changes in capacity are generally prevented with an in-between the measuring electrodes and the alarm device provided differentiator, because then only rapid state changes, i.e. those with a sufficiently large differential quotient, make the alarm device respond. But then they can because of them low susceptibility to failure, transistors used as a switch for the alarm device not be provided because their low input resistance is a disproportionate large capacitor for the differentiator would require.

In previously known room protection systems, a tube is therefore used as an electronic switch, as FIG. 1 shows in such a system. After closing the two switching paths Sch 1, Sch 2 of the manually operated switch Sch, the measuring bridge MB , which is already somewhat detuned in the idle state, is fed from the alternating voltage generator Ge via the supply diagonal so that an alternating voltage is constantly present at its measuring diagonal mh. The feed capacitor K1 is thus charged via the amplifier V and the directional conductor Grl with the polarity shown in the drawing. Thus, every change in the bridge detuning also results in a change in the voltage of the storage cord battery K 1, and only these voltage changes in the storage capacitor K1 reach the receiving circuit controlling the alarm generator W via the differentiating element K2, R1, with the rectifier Gr2 used in the Graetz circuit each The change in the charge of the storage capacitor K 1 is evaluated in such a way that the polarity shown in brackets always arises at the resistor R 1. Then each time the tube Rö becomes conductive and in turn actuates the alarm relay X, which is held by its self-holding contact x 1 and gives an alarm by means of the alarm clock W until the short-circuiting circuit x 1, Ta of the alarm relay X is interrupted by the button Ta.

This direct current control of the tube Rö by galvanic coupling via the resistor R 1 can only be carried out to a limited extent when a transistor is used as an electronic switch instead of the tube Rö. Because of the base residual current IBo, which cannot be avoided in a transistor, and because of the thermal instability of each transistor, the base resistance R 1 must not be selected too large, as otherwise the voltage drop resulting from the base residual current IBa at the base resistance R 1 would always make the transistor conductive, at least if this is the case at higher temperatures, since the base residual current IBo then assumes high values. On the other hand, in a capacitive room protection system, the resistance R 1 of the differentiating element must be made correspondingly large in order to be able to detect changes in state during a period of, for example, five minutes, since slow movements of an intruder should also be reported, as already mentioned.

The invention is therefore based on the object of these mutually contradicting To bring demands in line, namely despite a differentiating circuit with high discharge resistance the electronic switch a low input resistance, So in particular a transistor, a lower emitter-base resistance for the purpose high temperature stability. to be connected upstream, i.e. to create a differentiating circuit, the long times with a normal capacitor and an electronic switch with a low input resistance. According to the invention, this becomes achieved in a receiving circuit of the type mentioned in that in the input circuit of an electronic input circuit adapted via an input transformer Switch, in a manner known per se, a non-linear resistance than through the Differential pulse controllable alternating current switch for one to the electronic Auxiliary AC voltage that can be applied to the switch input is effective. Advantageously, can continue an electronic switch with a low input resistance is used as an electronic switch be. In a further embodiment of the invention, a directional conductor or two anti-parallel connected Directional guide, preferably with defined threshold values, as a non-linear resistance used, where. the peak value of the auxiliary voltage is below the threshold value of the directional conductor lies. This ensures that the differential resistance through in the idle state the downstream receiving circuit is not loaded in terms of direct current and continues to do so the auxiliary AC voltage cannot control the receiving circuit. Possibly are the input circuit of the receiving circuit from the differentiating resistor through suitable means, for example a blocking capacitor, to separate direct current. In a further embodiment of the invention, the auxiliary AC voltage can be connected in anti-parallel Directional ladders one from an ohmic resistor and the anti-parallel connected Pick up directional ladders existing voltage divider, -wherein. this one preferably lies in the bridge measurement diagonal - and wherein the anti-parallel-connected directional conductor can lie in the discharge circuit of the differentiating capacitor, because then no additional Voltage source is required to generate the auxiliary AC voltage: More advantageous Way, directional guides, preferably made of the same material, directional guides, used with the same voltage characteristics and the same temperature behavior because temperature influences can be eliminated within wide limits.

Further details of the invention emerge from the in the drawing with their circuit illustrated embodiments. It shows F i g. 2 the mode of action a direct current-controlled directional conductor used as an alternating current switch, F i g. 3 the coupling of a receiving circuit containing transistors to the Differentiator by means of a directional guide,.

F i g. 4 and 5 the coupling of a receiving circuit containing transistors to the differentiating element by means of a choke coil that can be pre-magnetized by direct current, , F i g. 6 shows a further embodiment in which the auxiliary AC voltage of Bridge measuring diagonal is taken and two directional guides connected in anti-parallel serve for coupling.

F i g. 2 shows the characteristic curve of a directional guide having a threshold value. In the idle state (working point A), an alternating voltage Uw applied to the directional conductor Gr which is below the threshold value (working point B) will not generate any current IG ,, in the directional conductor. If, on the other hand, the operating point is shifted to C by a direct voltage applied to the directional conductor in the forward direction, then, as shown, direct current with a high alternating current component flows through the directional conductor.

In Fig. 3 are of the bridge circuit including the differentiating element according to FIG. 1 only the resistor R 1 and the rectifier Gr2 are shown. Parallel to the differential resistor R1 are a capacitor K3 as a passage for alternating current, which must be small compared to the capacitor K2, and the series circuit, consisting of the secondary winding II of the transformer Ü1, through which the auxiliary AC voltage is fed, the directional conductor Gr3 and the primary winding I des Input transformer 02 for the transistor Tr, the directional conductor Gr3 being connected in such a way that the direct voltage generated at the differential resistor R 1 flows through the directional conductor Gr3 in the forward direction. As long as there is no direct voltage at the differential resistor R 1, the directional conductor Gr3 blocks the passage for the alternating voltage and, because of its threshold value, also for the direct voltage, so that the time constant of the differentiating element K2, R 1 is only determined by the size of the capacitor K2 and the resistor R1 will. If, on the other hand, the direct voltage component exceeds the threshold value of the directional conductor Gr3, this becomes conductive for both the direct voltage and the alternating voltage. The auxiliary AC voltage thus penetrates via the input transformer Ü2 to the transistor Tr and this activates the alarm relay X, which then holds itself via the self-holding contact x1. At the same time, it is true that the resistance value of the primary winding I of the input transformer U2, which is low for direct current, is now also connected in parallel to the high differential resistance R 1. The directional conductor Gr3 now also forms a low resistance for direct current; however, because the alarm device W has already responded, this is meaningless. .

Used in place of a directional guide, another non-linear resistor used as a DC controllable AC switch, for example a choke coil Dr1, which can be pre-magnetized by direct current, which this swelling effect does not have, so must by switching on the capacitor K4 between the differentiating resistor R1 and the primary winding I of the input transformer 02 have a direct current effect are prevented from each other (see Fig. 4). Furthermore, when using non-linear resistances without an absolute blocking effect for the alternating current - the so always let a certain residual alternating current through - by taking suitable measures provision must be made for this, for example by means of a corresponding gear ratio of the input transformer Ü2 or by a bias voltage to be selected accordingly of the transistor Tr that this is only activated when the nonlinear resistor Dr serving as an alternating current switch with direct current is controlled.

In Fig. 5, the direct current flowing through the differential resistor R 1 is still sent through the control winding of the direct-current bias inductor Dr2. The rectifier Gr2 is thus omitted, since the choke coil Dr2 always represents a low resistance for alternating current regardless of the direction of the direct current flowing through its control winding, if it is premagnetized at all. The auxiliary alternating voltage fed in via the transformer 01 makes the transistor Tr conductive as long as the choke coil Dr2 represents a high resistance for alternating voltage and the alarm relay Y remains attracted so long that the alarm clock W is not switched on. If, on the other hand, a sufficiently high direct current flows through the control winding of the choke coil Dr2, it forms a short circuit for the auxiliary alternating voltage fed in via the transformer U1. The transistor Tr 2 blocks and the alarm relay Y drops out and thus gives an alarm through its normally closed contact y2 until the transistor Tr is permeable again after the direct current flowing through the differential resistor R 1 has decayed and the alarm relay Y is activated again by pressing the Ta button became. The relay Y is then held by its self-holding contact y 1 until the transistor Tr blocks again.

In Fig. 6 the auxiliary AC voltage of the voltage amplified by the amplifier V of the bridge measurement diagonal is taken by means of the transformer ü3. Its primary winding I lies in the measuring diagonal mn, which means that the alarm voltage passes through the secondary winding II via the rectifier Grl to the storage capacitor K1 with a parallel discharge resistor R 5 and from there to the differentiating circuit K 2, R 1 during the secondary winding III of the transformer Ü3, the voltage divider formed from an ohmic resistor R6 and the directional conductors Gr5, Gr 6 connected in anti-parallel. This results in a trapezoidal alternating voltage of different steepness with a constant peak value at the anti-parallel-connected directional conductors Gr5, Gr6, if the smallest peak value that occurs during operation, the voltage output at the secondary winding 111 of the transformer U3, is approximately twice as large as the threshold values of the anti-parallel-connected directional conductors Gr 5, Gr 6 is. The temperature dependence of this trapezoidal voltage is low and not disturbing because the comparative directional conductors Gr 3, Gr 4 consist of the same material, namely are generally silicon diodes. These anti-parallel-connected directional conductors Gr 5, Gr 6 are in series with the capacitors K1, K2 and the resistor R1. Since the capacitors K1, K2 represent a short circuit for alternating current, both the trapezoidal auxiliary alternating voltage applied to the anti-parallel-connected directional conductors Gr 5, Gr 6 and a corresponding direct current differentiating pulse with different current directions via the differentiating capacitor K2 are applied to the resistor R IL. This is because no directional conductors are provided here in the discharge circuit of the differentiating capacitor K2.

They are replaced by the anti-parallel-connected directional conductors Gr 3, Gr 4, one of which is connected to the beginning of the primary winding I and the other to the end of the primary winding 11 of the transformer U 4. Depending on the polarity of the voltage drop of R1 (differentiating pulse) caused by the discharge or charge surge, one of these directional conductors Gr3, Gr4 serves as a DC-controlled alternating current switch. The further operation of the circuit is similar to that of the circuit shown in F i g.1, only here was an energized with open transistor Tr relay Y used. This triggers the alarm when the transistor Tr becomes conductive, i.e. the relay Y drops out and the alarm clock W switches on with its normally closed contact y.

Claims (7)

Claims: 1. Receiving circuit for rapid state changes, preferably capacity changes, responsive alarm devices in which one An electronic measuring bridge via a differentiating circuit consisting of an RC element Switch controls, d a d u r c h g e - indicates that in the via an input transformer (1 ')' 2) matched input circuit of an electronic switch (Tr), in itself known way a non-linear resistance (Gr3) than by the differentiating pulse controllable alternating current switch for one connected to the input of the electronic switch (Tr) auxiliary alternating voltage that can be applied acts. 2. receiving circuit according to claim 1, characterized in that the electronic switch (Tr) is one with a low Input resistance is used. 3. Receiving circuit according to claim 1, characterized characterized in that the non-linear resistance consists of a directional conductor (Gr 3) or two directional ladders (Gr3, Gr4) connected in anti-parallel. 4. Receive circuit according to claim 1 or 3, characterized in that the peak value of the auxiliary voltage is below the threshold of the directional guide (Gr3) and that the transmission ratio of the input transformer (Ü2) is dimensioned so that this low auxiliary AC voltage able to control the electronic switch (Tr). 5. Receiving circuit according to claim 1 or the following, characterized in that the peak value of the auxiliary AC voltage, the characteristic curve of the non-linear resistance (Gr 3 or Dr), the transmission ratio of the input transformer (Ü2) and the threshold value for the control of the electronic switch (Tr) , if necessary by a corresponding bias voltage, are determined so that the electronic switch (Tr) cannot be controlled by the partial alternating voltage passing through the non-modulated, non-linear resistor (Gr3, Dr). 6th Receiving circuit according to Claim 1 or the following, characterized in that the Transmitter input via a high, roughly in the order of magnitude of the differential resistance (R1) lying non-linear direct current resistor (Gr3) parallel to the differentiating resistor (R1) is connected. 7. Receiving circuit according to claim 1 or the following, characterized in that the Iüifs AC voltage can be tapped on anti-parallel directional conductors (Gr 5, Gr 6) of an ohmic resistor and the anti-parallel connected directional conductors (Grg, Gr6) existing voltage divider, which is preferably in the Brückerimeßdiagonal , whereby the anti-parallel-connected directional conductors (size 5, size 6) can be located in the discharge circuit of the differentiating capacitor (K2). Considered publications: Austrian patent specification No. 196 759.