EP1197936A2 - Alarm system - Google Patents

Abstract

The system has warning devices and possibly other line elements that respond to at least one hazard criterion connected to a two-wire line and a central station with stored warning device addresses and a program for monitoring warning device states. A test circuit checks the operating states of the network using a test unit. A test processor has evaluation software and a switch arrangement for selective connection of the test unit(s) to the line. The system has a number of warning devices (M1-Mn) and possibly other line elements that respond to at least one hazard criterion and are connected to a two-wire line (Linie A) and a central station connected to the line with stored warning device addresses and a program for monitoring warning device states. A test circuit (10) in the central station checks the operating states of the network using a test unit and contains a test processor (20,22) with evaluation software and a switch arrangement (30,33) for selective connection of the test unit(s) to the line. Independent claims are also included for the following: a method of measuring the resistance of sections or lengths of line in hazard warning systems and a method detecting a short circuit between the line and a screen.

Description

The invention relates to a hazard detection system according to the preamble of Claim 1.

Hazard detection systems, for example fire alarm systems, usually have one Larger number of hazard detectors connected to a two-wire alarm line are connected. This can be designed as a stub or as a loop which the individual detectors communicate with a control center. Every detector points a sensor or the like which, depending on parameters of its Environment produces measured values. The measured values are sent to the Control center transmit, which usually the individual detectors cyclically queries. To assign the measured values to the individual detectors , it is necessary to assign an identifier or an address to each detector. The address is stored in the detector's non-volatile memory. in the Processor of the control center, the registration addresses are stored, so that the control center with Use a suitable program to monitor the individual detectors can.

The installation and commissioning of such a hazard alarm system is included a considerable effort. Installation work is common Transfer companies that are not designated as specialist companies for such systems can be. However, the commissioning of such an alarm system takes place in usually by specially trained staff.

For the reasons mentioned, there is a need for errors and faults, which occur due to incorrect installation, if possible shortly before commissioning, however, to be discovered and identified at the latest during commissioning.

It is known to provide separate test circuit arrangements that are connected to the signaling line is connected, for example to check short-circuit faults or the reverse polarity of lines.

The invention has for its object to provide a hazard alarm system, in which a multitude of errors can be easily identified and localized can, the effort for the test circuit and the measurement effort are minimal.

This object is achieved by the features of patent claim 1.

In the hazard alarm system according to the invention there is a test circuit arrangement provided, which is part of the headquarters and for example on a special Command of the central control processor the operational state of the network Hazard detection system checked. This is done with the help of at least one test unit, which contains its own test processor in which a test program is stored is. A switch arrangement controlled by the test processor is also provided for the optional connection of the at least one test unit to the signaling line.

In the hazard alarm system according to the invention, the measuring means are for checking the operational condition of the alarm system in the alarm center integrated, so that in connection with an intelligent evaluation software Installation errors can be detected quickly and effectively.

Frequently occurring errors in alarm systems are reverse polarity Cores, exceeding the permissible cable lengths, short circuits or contact of wires or shields as well as swapping detector types and Deviation from the installation plan and changes in contact resistance.

A special test unit in the test circuit arrangement can be used for such errors are provided, with all test units with a test processor are connected. However, this can be provided redundantly.

According to one embodiment of the invention, the test circuit arrangement is a module formed, for example in the form of a plug-in card on which all components of the test circuit arrangement are arranged.

According to one embodiment of the invention, the test circuit arrangement has one Modem connection to check the network via a remote connection. This can take place over the telephone network, for example. With the help of such Possibility can check from a remote location, such as the Place of manufacture of the alarm system. The one in review Results obtained, in particular the errors found, can then read out and transmitted to the remote location via the remote connection. For example, before final commissioning or Acceptance of the alarm system installation errors discovered and rectified become.

It happens more often that when installing a hazard alarm system long cable lengths are used. This can result in the Transmission of signals on the line is weakened or disturbed, so that proper operation is no longer guaranteed. A test unit for A constant current source sees the determination of impermissibly large cable lengths before that to the line via a modulator and a controllable switch is switched. With the help of a data word sent by the test processor via a Modulator is generated and which also contains the address of a detector a detector is controlled and a switch in it causes the wires of the line connect to. The constant current source limits the current on the line a predetermined value, and a voltage measuring device can cover the whole Measure the voltage drop across the shorted section of the line. Since the Voltage drops from the detectors in the section are known the voltage drop caused by the lines depends on the difference of the measured voltage drop and the sum of the voltage drops at the Reporting of the measured section and, if applicable, a measuring resistor via which the Constant current flows to ground. If the voltage drop caused solely by the Line length is determined, is known, the resistance of the line length determine, because the cross-section of the line is known. From the on resistance determined in this way for the lines of the measured section the length of the measured section can therefore also be determined. To this The total length of a line can be determined in this way. It's on the top described way also possible the length of line sections to determine between selected detectors by in the detectors which the Limit the line section, the cross switches are closed one after the other.

The data word to control the individual detectors and to close the Cross switch is preferably voltage modulated according to an embodiment of the invention. A logic circuit and a are usually located in the detector Demodulator, so that the selected or addressed detector determines when it a command is given to close the cross switch. It can also be a Time switching are provided, which after a predetermined time Cross switch opens again to the line length for another section between detectors.

Lines for the networks described often have a shield in the form a braid or a conductive foil that surrounds the wires of the lines.

Such a shield has a very low resistance. she lies either at ground or at a given potential. It can in particular The area of the detectors during installation happens that one wire shields touched and thereby causes a short circuit. With the help of the test unit for one Such a short-circuit can be determined by so-called shielding monitoring. On This is easily done according to the invention in that the potential of Shielding is monitored via the test processor. Deviates the potential of a predetermined value, there is a contact of a wire with the shield in front.

The monitoring circuits described in some cases have considerable space Dimensions. It is therefore advantageous if it is not only determined whether a There is a short circuit, but also where it is. Therefore looks an embodiment of the invention that the shield via a measuring resistor is connected to a potential source. The test circuit arrangement shows as already described at the beginning, a constant voltage source. This ensures for the fact that, in the case of the short circuit described, a predetermined, limited amount Current through the line, across the short circuit and the measuring resistor flows. The entire voltage drop essentially consists of the voltage drop from the line sections and the measuring resistor together. How mentioned, the shield hardly contributes to voltage reduction and can are therefore neglected. Because the voltage drop across the measuring resistor is known is the voltage drop caused by the line calculate. From the current and the line voltage drop, the Determine the resistance of the line section up to the short circuit point. Because the cross section and the specific resistance of the veins is therefore known the resistance also calculate the length of the line to the short circuit. These calculations can be carried out in the test processor.

The length of the line from the control center to the short circuit point is already one essential statement that makes it easier to find a short circuit. Yet it is easier if it can be determined between which neighboring ones A short circuit has occurred. In the method described above, lets determine the length of the line sections between the detectors. Are therefore the individual cable lengths saved in the test processor can then be calculated between which detectors the contact between the shield and Wire or short circuit is present

Ring lines are often used in the hazard alarm systems described. the ends of each with symmetrical circuit arrangements of a center are connected. It is therefore possible to have a ring line from both ends to operate, for example if it is interrupted in the area of the short circuit becomes. In this case, e.g. B. from a central section a stub and the other branch line is operated from the other central section. So that certain detectors can be removed from the alarm system, provides an embodiment of the invention that the detectors in series with on the wire Horizontal isolating switches have to disconnect the cable on both sides a short circuit. In normal operation, the disconnectors are closed however opened on command from the control center. Since the headquarters "knows" between Which detectors are short-circuited can those adjacent to the short-circuit Detectors are controlled to open the disconnector.

Fig. 1

zeigt schematisch eine Prüfschaltungsanordnung nach der Erfindung für eine Gefahrenmeldeanlage.

Fig. 2

zeigt schematisch einen Melder der Gefahrenmeldeanlage nach Fig. 1.

The invention is described below with reference to circuit arrangements shown in the drawings.

Fig. 1

shows schematically a test circuit arrangement according to the invention for a hazard detection system.

Fig. 2

schematically shows a detector of the hazard alarm system according to FIG. 1.

1 shows a test circuit arrangement which is arranged within a box 10 shown in broken lines. The test circuit arrangement 10 is part of a control center (not shown further) of a hazard alarm system which has a ring line. In Fig. 1 only the line A of the ring line is shown. The other end, which is also connected to the control center and to a circuit arrangement symmetrical to the test circuit arrangement 10, is not shown for reasons of simplicity. Line A consists of wires 12 and 14, and in the course of line A a series of detectors M to M _{n is} connected. In Fig. 1, the detectors M1, M2 and M _n are shown. Part of the circuitry of the detectors M is shown in FIG. 2. A cross switch T3 can be seen, which connects the wires 12, 14 in the closed state. The voltage supply U _STAB with a capacitor C and a diode D can also be seen. As a result, the signaling circuit is also supplied with voltage when the voltage on line A drops briefly or approaches zero. The detector M also has a modulator / demodulator 16, which converts a voltage pulse on the line line into logic signals for a logic circuit 18. Logic circuit 18 includes an address memory and multiple input / output lines. It receives a serial data signal (e.g. an address or a command) and executes a command if a received address matches the address stored in the logic circuit 18. This can e.g. B. be the case to operate the cross switch T3 and thus short-circuit the wires 12, 14.

Each detector M has 14 disconnectors on both sides of the cross switch T3 in the wire T1, T2, which are normally closed during the operation of the detectors. In addition, the wires 12, 14 are connected to one another via Zener diodes, which are not specified in any more detail connected so that if the polarity of the detectors is reversed during installation Short circuit arises, which in turn is determined by a short circuit test circuit can be, which will be discussed further below.

The test circuit arrangement 10 has a first test processor 20 and one second test processor 22 (CPU1 or CPU2). The test processor 20 is via a Interface 24 (COM1) with the central processor, not shown, of the central office for the hazard alarm system in connection. The test processor 22 is redundant intended.

A constant voltage source 26 (I _KA ) is connected to the core 12 via a modulator 28 (MA) and a switch 30 (S _1A ). The constant voltage source 26 is connected to a voltage supply 32 (U _STABA ). The test processor 20 controls the modulator 28 and the switch 30 to e.g. B. to put a voltage modulated data word on the line when the switch 30 is closed. Another switch 33, which is also controlled by the test processor 20 (S _2A ), connects the wire 12 to ground when it is closed.

A voltage measuring device 36 (A / D1 _A ) is connected to the wire 12 and its output is connected to the test processor 20. The same applies to a voltage measuring device 38 (A / D2 _A ) which is connected to the wire 14.

The cores 12, 14 are surrounded by a shield 40, which is indicated by dashed lines in FIG. 1. The shield 40 is connected to a shield test unit 42, the output of which is connected to the test processor 20. It contains a test resistor 44 (R _A ), which is connected to the shield 40 and with the other terminal to the potential U _S. In addition, the shield is connected to the positive input of an operational amplifier 46, the output of which is connected to the test processor 20.

The wire 14 is connected to ground via a measuring resistor 46a (R _MA ), the same pole of the resistor 46a, which is connected to the wire 14, being connected to the positive input of an operational amplifier 48, the output of which is connected to the test processor 20.

With the help of the circuit arrangement shown, z. B. the line length of the Determine line A or the wires 12, 14 and also the line lengths between desired detectors M, z. B. between neighboring detectors M. For this, below the description of an embodiment.

1. U_RMA = I_IKA x R_MA

2. U_TX = I_KA x (M_N x 2 x R_TX)

3. U_RL = I_KA x R_L

4. U_LT = U_RMA + U_RL + U_TX

wobei

U_RMA

der Spannungsabfall über Widerstand R_MA,

U_TX

der Spannungsabfall über T1, T2 eines jeden Melders vor M_n,

U_LT

der Spannungsabfall am Linienanschluß A,

R_TX

der Gesamtwiderstand aller Schalter T1, T2 der Melder M1 bis M_n und

R_MA

der Meßwiderstand vor dem Anschluß Minuslinie A ist.

It is said to B. the line length between the detectors M2 and M _{n can be} measured. A normal operating state is assumed in which the switch 30 is closed and the switch 33 is opened. The switches T1 and T2 in the detectors M1 ... M _n are closed. The switch T3 in the detectors M1 ... M _n are open. Line A is thus energized (operating voltage). By controlling the modulator MA, a voltage-modulated signal on the line, for. B. a loop. The data word contains the address of the detector or its communication address and a command to close the switch T3, for example from M _n . After M _{n has received} the command, its switch T3 is closed. _A constant current I _A now flows, caused by the constant current source 26. The current flows through the switches T3 and T1 of M _n , and through the resistor R _MA . With the help of the voltage measuring device 36, the voltage drop at the connection plus line A is measured and fed to the test processor 20. The measured voltage drop is composed as follows:

1. U _RMA = I _IKA x R _MA

2. U _TX = I _KA x (M _N x 2 x R _TX )

3. U _RL = I _KA x R _L

4. U _LT = U _RMA + U _RL + U _TX

in which

U _RMA

the voltage drop across resistor R _MA ,

U _TX

the voltage drop across T1, T2 of each detector before M _n ,

U _LT

the voltage drop at line connection A,

R _TX

the total resistance of all switches T1, T2 of detectors M1 to M _n and

R _MA

the measuring resistance before the connection is minus line A.

After changing equation 4. U RL = U LT - U RMA - U TX RL (M n ) = U LT - U RMA - U TX (M n ) I KA

Equation 2 is calculated in the test processor 20 and the result R _L (M _n ) is stored. This value includes the line resistance between the connection of line A and the detector M _n .

After a certain time t _M , the switch T3 in the detector M _{n is} opened again. This is done with the aid of a suitable time circuit, which is accommodated in the detector, for example in the logic module 18. The line voltage goes back to operating potential.

The above steps are then carried out for detector M2. The result R _L (M2) is also stored in the memory by the test processor 20. Now the difference between the two measurements is formed: Δ R L = R L (M n ) - R L (M n )

For a given conductor diameter (cross section), the cable length between detectors M2 and M _n can be determined: 1 G = A x R L ρ where A is the cross-section of the line and ρ is the specific resistance. The simple length of a wire or a wire section results from 1 = 1 G 2

The same procedure can be used to determine the total length of the line. Is z. B. a ring line is provided, the switch is closed at the other end, which corresponds to the switch 33 of FIG. 1. As a result, a constant current flows through the wire 12 to ground. The voltage at the connection of the wire 12 is now measured via the voltage measuring device 36. The measured voltage can be converted directly into the length of the line: R L = U LT I K 1 = A x R L ρ

The measured values for the line sections and the entire line can be stored in the test processor 20.

With the help of the circuit arrangement shown, a short circuit between the shield 40 and one of the wires are determined as well as the location of the Short circuit.

As already mentioned, the shield 40 consists of a wire mesh or one Foil and is low-resistance and is neglected in the following calculations. Again, a normal operating state is assumed, i. H. Switch 30 is closed and switch 33 is open. Now the short circuit K1 detected and the short-circuit location can be determined.

A

der Querschnitt der Ader,

R_LK

der gemessene Widerstandswert und

ρ

der spezifische Widerstand ist.

The current I _{A of} the constant current source 26 flows. When the short circuit K1 exists, it also flows via the shield 40 and the resistor 44 to the potential Us of the shield monitor 42. The voltage which is established can be measured with the aid of the voltage measuring device 36 , The voltage drop across resistor 44 is known. The voltage drop that is caused by the line to the short-circuit point K1, ie by the wire 12, can thus be calculated from this. This voltage drop U _LA and the current I _A allow the resistance wire section, which is denoted by R _LK , to be calculated. The cable length to the short circuit point is therefore 1 = A x R LK ρ in which

A

the cross section of the vein,

R _LK

the measured resistance value and

ρ

the specific resistance is.

In this way it can be determined at which line distance the short circuit has occurred. Since this line distance still says little about the actual location of the short circuit, this line length can also be related to the determined lengths of the line sections between the detectors M1 ... M _n . It is therefore easy to determine between which detectors the short circuit lies, ie here between detectors M1 and M2.

In a similar way as described above, it can also be determined whether there is a polarity reversal. In the event of polarity reversal, the constant current I _{A flows} through the Zener diode, not shown, and thus brings about a short-circuit current limited by the constant current source 26. By measuring the length of the line, you can determine the location of the short circuit. Since the voltage drop across the measuring resistor 46a also changes in this case, block D _A can be used to determine whether there is a short circuit or the line is undisturbed, which then leads to a corresponding message to the test processor 20.

Claims (19)

Hazard detection system with a large number of detectors (M1 to M _n ) and possibly other line elements that respond to at least one hazard criterion and are connected to a two-wire line (line A), a control center connected to the line (line A), which has a power supply and a central processor in which the addresses of the detectors (M1 to M _n ) are stored for individual control and query of the detectors (M1 to M _n ) and a program for monitoring the status of the detectors (M1 to M _n ), characterized in that a test circuit arrangement (10) is arranged in the control center for checking the operational state of the network formed by line (line A) and detectors (M1 to M _n ) or line elements with the aid of a test unit, the test circuit arrangement (10) contains a test processor (20, 22) which in turn has evaluation software and a switch arrangement (30, 33) controlled by the test processor (20, 22) is provided for selectively connecting the at least one test unit to the line (line A). System according to claim 1, characterized in that the test circuit arrangement (10) is designed as a module, for example in the form of a plug-in card. System according to claim 1 or 2, characterized in that the test circuit arrangement (10) has a modem connection for checking the network via a remote connection. System according to one of Claims 1 to 3, characterized by a test unit for testing the polarity reversal of the detectors (M1 to M _n ) or the line elements. System according to one of claims 1 to 4, characterized by a test unit for checking the line lengths. System according to one of claims 1 to 5, characterized by a test unit for checking short circuits in the line and / or a contact of wires (12, 14) of the line (line A) or the shielding (40) of the line with a wire (12, 14). System according to one of claims 1 to 6, characterized by a test unit for checking the installed network with a predetermined installation plan. System according to Claim 5, characterized in that the test unit has a constant current source (26) which can be connected to the line (line A) via a modulator (28) and a controllable switch (30), the test processor (20, 22) and the modulator (28) generates a data word which contains the address of a detector (M1 to M _n ) and a control signal for a cross switch (T3) connecting the wires (12, 14) and also one with the line (line A) connected voltage measuring device (36) is provided, which is connected to the test processor (20, 22). System according to claim 8, characterized in that the data word is formed by voltage modulation in the modulator (28). System according to claim 8 or 9, characterized in that a time switch is provided which causes the switch (T3) to open. Installation according to one of Claims 8 to 10, characterized in that at least one second switch (33) is provided which connects one wire (14) of the line (line A) to ground in order to generate a constant current flowing in the line (A) , System according to one of Claims 6 to 11, characterized in that a shielding test unit (42) monitors the potential of the shield (40) by means of the test processor (20, 22) and generates a signal if the potential deviates from a predetermined value. System according to Claim 12, characterized in that a measuring resistor (44) is connected to the shield (40), the voltage drop of which is passed to the test processor (20, 22) and from the voltage value at the connection of the line (line A) and the stored value Voltage drop of the measuring resistor (U _RA ) and the constant current (I _A ) determines the line resistance up to the short circuit point and from the resistance the line length up to the short circuit point. System according to one of Claims 1 to 13, characterized in that the detectors (M1 to M _n ) have disconnectors (T1, T2) located in series with a wire (14) for disconnecting the line (line A) on both sides of a short-circuit point (K1). Method for measuring the resistance of line sections or line lengths in alarm systems with the following characteristics: a large number of detectors (M1 to M _n ) and possibly other line elements that respond to at least one hazard criterion and are connected to a two-wire line (line A) a control center connected to the line (line A), which has a power supply and a central processor in which the addresses of the detectors (M1 to M _n ) are stored for individual control and for querying the detectors (M1 to M _n ) and a Program for monitoring the status of the detectors (M1 to M _n ) characterized by the following process steps: a test unit (10) is connected to the line (12, 14) A test processor (20, 22) of the test unit (10), in which the addresses of the detectors (M1 to M _n ) are stored, gives a given detector (M _n ) a command via its address to close one of the wires of the line ( 12, 14) connecting cross switch (T3) in the detector (M _n ) a constant current source (I _KA ) of the test unit (10) generates a constant current (I _A ) on the line (12, 14) a voltage measuring device (36) measures the voltage drop at the connection of the line (12, 14) and gives the measured value to the test processor (20, 22) the test processor (20, 22) calculates the resistance of the sum of the line sections between the connection of the line (12, 14) and the detector (M _n ) by subtracting the resistances of the detectors (M1 to M _n-1 ) and possibly a limiting resistor (R _MA ). Method according to Claim 15, characterized in that the resistance or the line length between adjacent detectors (M _n , M2) is calculated by repeating the steps according to Claim 15 for the adjacent detector (M2) and subtracting the smaller resistance value from the larger one , Method according to claim 15 or 16, characterized in that a time switch in the detectors opens the cross switch (T3) after a predetermined time if it was previously closed. Method according to one of Claims 15 to 17, characterized in that the resistances or the line length of the individual line sections between the detectors (M1 to M _n ) and the predetermined resistance values of the individual detectors (M1 to M _n ) in the test processor (20, 22 ) are saved and during a later measurement during operation the measured resistances for the detectors are compared with the stored resistance values for the detectors. A method of determining a short circuit between the line of a hazard alarm system and a shield for the line, the hazard alarm system comprising: a large number of detectors (M1 to M _n ) and possibly other line elements that respond to at least one hazard criterion and are connected to a two-wire line (line A) a control center connected to the line (line A), which has a power supply and a central processor in which the addresses of the detectors (M1 to M _n ) are stored for individual control and for querying the detectors (M1 to M _n ) and a Program for monitoring the status of the detectors (M1 to M _n ) characterized by the following process steps: the shield (40) is connected to ground via a resistor (R _A ) of the test unit (10) a constant current source (I _KA ) of the test unit (10) generates a constant current (I _A ) on the line (12, 14) a voltage measuring device (36) measures the voltage drop at the connection of the line (12, 14) and outputs the measured value to the test processor (20, 22) the test processor (20, 22) calculates the resistance of the short-circuited line to the short-circuit point (K1) and calculates the line length to the short-circuit point (K1) from the parameters of the line (12, 14).

Images