NL8004913A - DC REPORTING SYSTEM. - Google Patents

Description

Η. 0.29.333 ♦

The present invention relates to a direct current reporting system with at least one conductor loop which can be switched from a central output and which can be connected to a DC voltage source, on which a number of signaling devices each having at least one resistor and a conductor loop terminating resistor are connected, wherein the resistance value of the individual signaling devices can be changed in a jump manner in each case by a signaling switch and in which a measuring device for determining the total resistance of the conductor loop and a processing device 10 are present in the central unit.

DC signaling systems for fire protection, emergency calls or other hazard monitoring devices are widespread as they require only a small amount of equipment.

In each case, several reporting devices are connected in parallel to each reporting line or reporting loop. The terminating resistor provides a quiescent current, via which the line is monitored. In the event of an alarm, the signaling alarm device changes its resistance and thereby the total resistance of the line. The rising or falling current serves as an alarm criterion. However, it is not possible to determine in the exchange with the known systems which reporter of the conductor loop has generated the alarm.

It is true that reporting systems are already known in which the individual reporting devices of a conductor loop can be identified. In any case, this is not about DC-25 reporting systems. Yeeleer requires considerably more switching equipment for the system and for the individual reporting devices.

The object of the invention is to provide a direct current reporting system, wherein the individual reporting devices of a conductor loop can be identified when an alarm is switched on.

According to the invention, this object is achieved with a system of the type mentioned in the preamble, in that each reporting device has, in addition to the resistance to be changed, a fixed longitudinal resistance included in the conductor loop, which in in a memory device, the values of the total resistance possible at different states of the conductor loop are recorded and that a comparator is provided to compare the prevailing value of the total resistance by comparing the O 7 Λ Λ 0 1 7 2 determine the recorded value of the report state of the conductor loop, as well as the individual report device.

As a result of the design according to the invention of the individual 5 reporting devices, each with a fixed and a variable resistance, the separate conductor loop becomes a resistance network with an entirely determined total resistance. This total resistance is changed when one or more reporting devices are addressed; in this case, a completely determined resistance value is created when a specific reporting device 10 is addressed. These particular resistance values can be simply calculated and registered as a comparison value in the exchange. By comparing the measured resistance value with these registered prescribed values, it is then possible to determine without any doubt which reporting device or reporting devices appeal.

The processing in the exchange is particularly simple when each reporting device has two series resistors, the fixed longitudinal resistance in each reporting device having the same value, while the variable resistance connected in series with each reporting device has a different value. The resistance variation for giving an alarm occurs in the individual signaling devices, preferably in that a parallel-connected signaling switch is closed or opened. In another embodiment of the invention, the variable resistors are connected in parallel to the conductor loop in the individual signaling devices, wherein the resistance variation can take place here by opening or closing a signaling switch connected in series to the resistor. In this case, the system is particularly simple and economical to construct, if the individual signaling devices are each equipped with the same building elements, i.e. with equal resistances.

In such reporting systems, the conductor loops often have a long line length between the exchange and the reporting devices, so that the line resistance with a high value is included in the total resistance. For this case it is advantageous to allow the determination of the pure line resistance by means of additional devices and measures. In another embodiment of the invention, a voltage limiting circuit is provided at least at the input of the first signal device of a conductor loop. This voltage limiting circuit can be formed, for example, by a Zaner diode 40 and an oppositely pole-connected diode connected in series 8004913> 3.

The pure line resistance can now be determined by means of such a voltage limiting circuit. For this purpose, a measuring device can be present in the central unit, in which two different interrogation voltages above the response threshold of the voltage limiting circuit in the signaling devices can be connected to the conductor loop, wherein the current difference that occurs during this can also be determined and derived therefrom the line resistance can be determined with the selected voltage difference in a sub-10 device. Here, the effect is used that, above the response threshold of the voltage limiting circuit, an increase in the loop spaming does not cause an increase in the voltage in the subsequent signaling devices. The increased line current therefore only flows over the line 1 up to the voltage limiting circuit, so that the line resistance can be calculated from this.

In an advantageous embodiment, a terminating diode is also connected in parallel to the terminating resistor of the conductor loop and is connected anti-parallel to the diode or the diodes in the individual signaling devices. When a correspondingly polarized voltage is applied to the conductor loop, the termination diode bridges the termination resistance, so that the measured total resistance includes only the line resistance and the longitudinal resistance of the individual signaling device. With equal values of the longitudinal resistances and with known line resistance, the number of switched-on signaling devices can therefore be calculated from the exchange.

It is expedient for the torch to have the longitudinal resistances in the individual signaling devices and the terminating resistance of the conductor loop dimensioned such that the voltage drop across the longitudinal resistance of the individual signaling device is always greater than the tolerance of the contact point of the associated voltage limiting circuit. This ensures that this only addresses the voltage limit in the first signaling device.

The invention will be explained in more detail below with reference to the drawing, in which Fig. 1 shows the circuit of a reporting device in a DC reporting system according to the invention; Fig. 2 illustrates a possible variant of the circuit of a signaling device of Fig. 1; Fig. 3 shows the arrangement of a reporting system with a block diagram fi n 4 913 4 for the facilities of the exchange; and FIG. 4 shows the switching on of signaling devices with only longitudinal resistors.

Fig. 1 shows the connection of a conductor loop to a central Z. The exchange has a variable DC voltage source with which voltage is applied to the two-wire line L. The individual signaling devices M1, M2, etc. are then suspended on this line L.

The line is finally terminated with a terminating resistor R ^.

The individual signaling devices each contain, as illustrated at M1, a longitudinal resistance R1 and a transverse resistance R2.

In Fig. 1, the transverse resistance from the center is arranged for the longitudinal resistance. However, a circuit according to Fig. 2 is also possible, in which the transverse resistance of the reporting device M, seen from the center, lies behind the longitudinal resistance R1.

In the event of an alarm, one of the two resistors R1 or R2 is varied in steps. In general, the transverse resistance R2 varies from the value R = oo to a value which may be approximately in the kOhm range. This is done, for example, in that, as can be seen in Fig. 3, a signaling switch S is closed by a push button 20. In this case, the diode is not necessary. In general, therefore, in the quiescent state (R2 = "*>) in the presence of a positive voltage, current flows only over the longitudinal resistor R1 and over the terminating resistor R1. The terminating resistor R ^ also has a parallel-connected terminating diode D ^, which short-circuits the terminating resistor BA in the case of reverse polarity line chip.

The signaling circuit of the signaling device M1, like the other signaling circuit, also has a voltage limiting circuit consisting of a Zener diode Z and a diode D connected in series with it. This voltage limiting circuit only works when a positive voltage according to FIG. 1 is connected; it has no influence on voltage reversal.

The construction of the devices in the central Z as well as the function of the system will now be explained in more detail with reference to Fig. 3. As shown in Fig. 1, the reporting line has the form of a line loop L with in this case two switched-on reporting devices M1 and M2, as well as the line termination A with the terminating resistor R1 and the terminating diode D1. Each reporting device has a longitudinal resistance R11 and R12, respectively, as well as a transverse resistance R21 and R22, respectively. The transverse resistance can be triggered on the line via an alarm switch S1 or S2 open in the idle state 40, in the case of 8004913 * J »5. In addition, each signaling device has a voltage limiting circuit, each with a Zener diode Z1 and Z2 and a diode D1 and 1) 2, respectively.

For measuring the line current, a measuring resistor R 1 is provided in the plant, over which the voltage drop is measured with the aid of a voltage meter SM and the total resistance of the conductor loop is processed to determine the line current, respectively. The measured value for the line current I or for the total resistance R ^ of the conductor loop is passed through the analog-digital converter AB for processing. The DC voltage source is each set on the control device S1 via the digital-analog converter BA to the desired values II, II and T2, respectively.

Normally the conductor loop is called up, a voltage value U3 is set on the DC voltage source, which has the polarity shown in FIG. 3 and does not cause the voltage limit in the signal devices M1 and M2, respectively. Thereby, a total resistance R ^ of the conductor loop is measured, which is composed of the pure line resistance R ^, the signaling resistors and the terminating resistor R ^. In the quiescent state this total resistance is at n switched-on signaling devices with equal longitudinal resistances R1: EG = EI + SA + n *

When one or more reporting devices are addressed, this total resistance is changed accordingly. The measured resistance R1 is applied to a comparator YG and compared there with the relevant resistance values from a comparison memory YSP. The result is carried out via a processing device AW, in the case of Fig. 3 the following possibilities exist: a) idle state * b) reporting device M1 responds * c) reporting device M2 responds; (d) reporting devices M1 and M2 respond.

35 In addition, a line short circuit and line interruption can also be observed.

The comparison values for the comparison value memory YSP can be arbitrarily calculated and entered into this memory. However, they can also be automatically determined upon commissioning of the system, as further illustrated in the block diagram 8004913 6 of FIG.

When the system is switched on, the control device ST initially sets a line voltage II with the polarity shown on the conductor loop via the digital-analog converter. This voltage 5 is so great that the Zener period Z1 in the reporting device M1 certainly responds. The current flowing is determined over the measuring resistor Bjj and with the aid of the voltage meter SM, outputted over the analog-digital converter AB and written into the memory SPI. Thereafter, a voltage-value U2 is set by the control device ST on the conductor loop, which value AU is greater than the voltage value U1. Again the line current is measured; the current variation Δ I is determined via the subtractor SUB and is applied to the sub-device BIY. In addition, the sub-device of the control device ST is given the value AU and calculates according to the instructions

AU

1 - Ai the pure line resistance R ^. This line resistance is recorded in the memory SPL.

The control device ST now transmits the interrogation voltage U3 to the conductor loop; as mentioned, U3 is so small that the voltage limitation in the signaling devices is not yet effective.

The measurement result for the total resistance R ^ is recorded in the memory SPG. Since this is the quiescent state, this total resistance is composed of the longitudinal resistances R1 of the signaling devices, the line resistance R ^ and the terminating resistor R ^. The terminating position HA is approximately the same as the longitudinal resistance R1 equal for all signaling devices; the line resistance has already been determined as described above. Thus, the number n of the 30 reporting devices can now be determined according to the following rule: _ ¾ ~ BL · ~ HA n ~ R1

This calculation can be performed in the calculation circuit RE, the individual values from the memories SPI, SPG and SPA 35 being supplied.

In case R ^ R ^ and R ^^> R1, the result of the subtracting operation R & - R ^ - becomes small relative to the starting values R ^ and Rq_. Therefore, the result is not very accurate. In this case, a more accurate determination can be made by a further resistance measurement. This measurement takes place with 8004913 - 7 polarity reversed line voltage. The variable DC voltage source G then supplies a reverse polarity with respect to FIG. 3, which amount corresponds to the voltage D3. In this pole, the terminating diode D ^ is conductive and the terminating resistor 5 R ^ is short-circuited. At the exchange, a resistance R ^ is now measured, which is composed only of the line resistance R ^ and the longitudinal resistances of the signaling devices. From this, the number of connected signaling devices can now be calculated more accurately in the calculating circuit HE, since the high-impedance resistor has been switched off.

As mentioned, each reporting state of the system is characterized by a certain value of the measured total resistance on the line loop. This will be explained once more on the basis of a number example. It is assumed that in FIG. 3 the resistors R11, R12, R21 and R22 each have a value of 5 kOhm. The terminating resistor R ^ will have a resistance of 200 kOhm. Then the following resistance values for the different line states are obtained:

Resting state. 210 kOhm 20 Alarm device from signaling device 1: 10 kOhm »» - »2i 15 kOhm h» »» 1 and 2: 8.33 kOhm

If the conductor is reversed so that the termination resistor is short-circuited, a resistance of 10 kOhmj is measured, from which it can be concluded that two signaling devices (n = 2) are connected to the conductor loop.

lie. 4 shows a different circuit possibility for the individual reporting devices, wherein each reporting device M5, M6 etc. has two longitudinal resistors R51, R52, R61, R62 etc., each.

The signal switches S5, S6, S7, etc. are closed in the rest state, so that the (variable) resistors R52, R62, R72 are bridged. Resistors R51, R61, R71 and so on all have the same value, while resistors R52, R62, R72 and so on may differ in value. For example, R51 = 1 kOhm, 35 R61 = 2 kOhm and R71 = 4 kOhm. If one of the reporting devices responds and a specific reporting switch S5, S6 or S7 is opened accordingly, the relevant reporting device in the exchange can be identified without difficulty.

8004913

Claims (11)

1. DC signaling system with at least one central conductor outgoing conductor loop which can be connected to a DC voltage source, on which a number of signaling devices each having at least 5 a resistor and a conductor loop termination resistor are connected, the resistance value of the individual signaling devices being in each case a report switch can be varied in steps and wherein a central measuring device for determining the total resistance of the conductor loop and a processing device are present, characterized in that each report device (M1, M2) in addition to the variable resistance (12; 121, 122) has a fixed resistor (H1; 111, 112) incorporated in the conductor loop (1), which in the center (Z) in a memory device (YSP) shows the conductor loop (1) at different states possible values of the total resistance (1 ^) have been recorded and that a comparator (YG) is present to be compared g to determine the respective prevailing measured value of the total resistance (1 ^) with the recorded values, the reporting state of the conductor loop and of the individual reporting devices 20 (M1, M2). DC signal system according to claim 1, characterized in that the variable resistor (12) in the individual signal devices (M1, M2 ...) is each connected in parallel to the conductor loop and by a signal switch connected in series therewith. (S1, S2) on the conductor loop can be switched on. Signaling system according to claim 1, characterized in that the variable resistor (152, 162 ...) is connected in series with the fixed resistor (151> 161) at each signaling device (M5, M6 ...) and is connected by a Signal switch (S5, S6 ...) connected in parallel in the conductor loop can be switched on. Signaling system according to Claim 1 or 2, characterized in that the individual signaling devices (M1, IE) are each equipped with identical components of equal values. Signal system according to one of Claims 1 to 4 »35, characterized in that a voltage limiting circuit (Z, D) is provided at least at the input of the first signal device (M1) in the conductor loop. 6. Signaling system according to claim 5, characterized in that the voltage limiting circuit is formed by a Zener diode 40 (Z) and an oppositely polar diode 8004913 S 's (D) connected in series therewith. Reporting system according to any one of claims 1 to 6, characterized in that the voltage (ï1, ΤΓ2, ÏI3) supplied by the DC voltage source (G) in the center (z) can be varied. Reporting system according to claim 7> 1, characterized in that in the center (Z) there is a measuring device (E ^, SM) for determining the pure line resistance (E ^) of the conductor loop, two different, above the response threshold 10 of the voltage limiting circuit in the signaling devices, interrogating voltages (ï1, ΙΓ2) can be switched on the conductor loop (i), and the current difference (ΐΐ) which can then be determined in a subtractor (ΐΐ) and the selected voltage difference ( ΔΤΓ) the line resistance (E ^) can be determined in a sub-device (ΒΓ7). Reporting system according to any one of claims 5 to 8, characterized in that. the terminating resistor (E ^) of the conductor loop has a terminating diode (B ^) connected in parallel, which is connected anti-parallel to the diode or diodes (B, B1, D2) 20 in the individual signaling devices (M1, M2). 10. Signaling system according to claim 9, characterized in that the voltage source (G) in the center (z) can be reversed in such a way that the terminating resistor (E ^) of the conductor loop. short-circuited by the parallel-connected terminating diode (B ^), whereby the number of connected signaling devices can be calculated from the known values of the line resistance (E ^) and the longitudinal resistances (E11, E12) of the individual reporting devices (M1, M2). Signaling system according to any one of claims 2 to $, characterized in that the longitudinal resistors (E11, E12) 30 in the individual signaling devices (M1, M2) and the terminating resistor (E ^) of the conductor loop are dimensioned such that that the voltage drop across the longitudinal resistance (E11, E12) of the individual signaling device. (M1, M2) is greater than the tolerance of the response point of the associated associated voltage limiting circuit (Z1, B1). 8004913