DE3715196A1 - Alarm signalling system - Google Patents

Abstract

An alarm signalling system having a multiplicity of detectors connected to one or more two-wire loop lines exhibits for each detector a line module which is provided with a control device. The line module contains a switching means which, when the alarm signalling system is taken into operation, is at first open. The first line module connected to the central station receives an address from the central station which is stored in the control device, and then the command for closing the switching means. In this manner, all line modules to which the detectors are connected are provided in succession with addresses, as a result of which they can be selectively activated by the central station and can receive commands and transmit messages to the central station.

Description

The invention relates to a hazard alarm system with a Variety of one or more two-wire star and / or loop lines connected measuring points, whereby the transmission of the message from the measuring point to the control center and the message evaluated and processed in the same (Alarm message, display, etc.) for each measuring point a switching means is provided, which is initiated that can be closed and opened and that Line through to the next measuring point, each Measuring point a control device and a transmission / Receiving device, each measuring point through the Central with the help of a transmitted over the line Address can be controlled and in the activated state the receipt of a command or the transmission of a Message is possible when commissioning the Hazard detection system the switching means of all Measuring points is open, each measuring point through the Central is assigned an address, this address as measuring point address in the control device is stored and the relevant measuring point then controlled via this address and by the control center by a corresponding command Closure of the switching means is caused.

Such a hazard alarm system is already known. For example, EP-OS 0 93 872 describes a method for transmission described by measured values in a monitoring system,  at which measuring points, the chain-like on signal lines transmit measured values to a signal center, in which they are used to obtain differentiated or alarm signals are linked. When starting up are all measuring points by a voltage change of the Signal line separated and then through in each measuring point existing switching elements staggered in time switched back on to the signal line that each Measuring point after a certain time increase subsequent measuring point additionally to the line voltage turns on. There are address memories in the measuring points available, which in a predetermined order from the Signal center off with the addresses of each Measuring points are occupied and then locked before by the switching element the next measuring point of the same Signal line is connected to the signal voltage.

Each individual measuring point can have a fire detector, an ionization smoke detector, an optical smoke detector, a temperature detector or a flame detector Monitoring device in an intrusion protection system, a passive infrared detector, an ultrasonic detector or a noise detector or any measuring point be in a transmission system. About the way how to connect the individual detectors to a measuring point are, none of the mentioned publication Take notes.

The object of the invention is now a Form measuring point in such a way that it is universal can be used, d. H. the connection of the above-mentioned detectors is possible.

This object is achieved in that the measuring point is designed as a line module and a detector section place with first connections with one each Resistance to voltage, with second connections with resistance to ground and third Has connections, each with a Provide a resistor to voltage with a transistor  are, the collector with the connection and the Emitter is connected to ground, the transistor blocked when using the connection as input is.

Such an interface does not allow only the acceptance of a report by a detector also the transmission of control commands to the same.

A further development of the invention is that the address allocation in regular or irregular Periods.

So the address assignment is not on commissioning the alarm system, but also afterwards possible; this is particularly in connection with the Scrambling the addresses to be allocated with regard to an increase in security against sabotage is interesting.

Further advantages result from the subclaims.

The invention is illustrated by an embodiment explained which is shown in the drawing. It shows

Fig. 1 is a block diagram of an alarm system,

Fig. 2 is a block diagram of a line block,

Fig. 3 shows a circuit arrangement of the detector interface and

Fig. 4 shows the time diagram for the exchange of information on the line.

In the example shown in FIG. 1, block diagram of an alarm system Ge drive a plurality of line blocks LB via a line L are connected to a central station Z, wherein each line block LB is, for example, connected to a detector M. The line L can be connected in a star shape or as an annular loop to the control center Z , it is used to supply power to the line modules LB and possibly also to the connected detector M and to exchange data between the control center Z and the line module LB.

The center Z has a memory SP which has as many memory locations as line modules are connected to the center Z. The memory SP has only one memory area if only one line L is connected to the center Z , otherwise a separate memory area is provided for each line L. The address and the type of detector M connected to the line module LB are entered in the memory SP for each line module, and the operating state of the individual detectors M can also be identified in the memory SP .

When the hazard alarm system is started up, the central voltage Z first applies the supply voltage to line L. First, there is no connection between the input E and the output A of each line module LB , so that only the line module LB connected directly to the center Z via line L receives voltage. The center Z first transmits an address which is the same for all line modules LB , for example a data word 00000000 or a specific data word which is automatically loaded from a read-only memory into the address memory of the line module LB ; After this address, the actual individual address of the line module is transmitted from the control center and loaded into the address memory. The line module LB can thus be addressed by the control center. The control center Z then transmits a command to the line module LB to connect the input E to the output A , whereupon the supply voltage reaches the next line module LB. The processes already described are repeated for this line module and for the other line modules, although an address can still be assigned due to the lack of an address after the supply voltage has been installed in the line module, since the line module (s) in front of it are already provided with an individual address .

The line module LB ( FIG. 2) has a control device ST, for example in the form of a microprocessor. A parallel / series converter PS is connected to the control device ST and can be designed, for example, as a shift register. The parallel / series converter PS is connected on the transmission and reception side via corresponding amplifiers V to the input E and the output A , so that all information that is transmitted via the line L passes through it. The control device ST has an address register in which the assigned address is stored. True in the parallel / serial converter ent preserved address with that of the address register match - as the subsequently transmitted command in the control is transmitted device or a message from the control device ST via the parallel / serial converter placed on the line L. As soon as voltage is present on line L , data exchange between the control center and the relevant line module LB is possible. In this state, the address register of the control device ST can either only zeros as an address or, for safety reasons, also contain an address which has been read from a read-only memory of the control device and transferred to the address register as soon as the supply voltage is applied to the control device ST . The address from the read-only memory can be the same for all line modules LB.

The line module LB is then subsequently addressed by the central station Z at the address contained in the address register, the relevant address being transferred to the parallel / series converter. The comparison of the address contained in the parallel / series converter with that in the address register results in a match, so that the subsequently transmitted individual address from the parallel / series converter is taken over into the control device ST and is transferred into the address register. The line module LB can be controlled individually at this address. Another possibility for address acceptance is also conceivable, in that the control device ST is set such that after the supply voltage is switched on, the transmitted address is not subjected to the comparison and is immediately transferred to the address register.

Through the same addressing or a new addressing, the line module LB can now receive the command from the central station Z to close the switching means S. The switching means, which can be designed as a mechanical contact or as an electronic switch, connects the input E to the output A , whereupon the supply voltage reaches the input E of the next line module LB lying in line L. The processes already described are repeated here. As soon as the supply voltage is switched off, the switching means S is opened again.

A detector interface MS , which has various inputs (S) and outputs (E) , is also connected to the control device ST . This is used to connect the actual detector M. For the power supply of the detector, the connection V is provided, while the detector interface MS is prepared for the reception of information from the detector M via the connection D.

The detectors MS interface of FIG. 3 comprises Empfangsein gears E 1, E 2, and D, which are connected via a resistor to the positive operating voltage. In this case the detector signal must have the value "L". The receive inputs E 3 and E 4 are connected to a resistance to ground, so that the detector signal must have the value "H". The transmit / receive connections S 5 to S 8 are also connected via a resistor to the positive operating voltage, so that the detector signal must also have the value "L". However, a signal can also be sent to the detector via the transistor TS , which also has the value "L".

The detectors MS interface according to FIG. 2 and FIG. 3 is used for connection of motion detectors with measurement value transmission, concentrators block locks, emergency detectors, branch distribution, management, etc., wherein wired as required the respective transmitting and receiving terminals.

Addresses, commands and messages are transmitted on line L in the form of data words DA with a length of 8 bits (see FIG. 4) which are supplemented by a parity bit P. As is known, the parity bit is used for data backup and is used on the receiving side to check the transmitted information. The data word DA is preceded by a start bit and followed by a stop bit. The whole forms a section A. The information is transmitted by a frame R , the address being transmitted first in section A 1 and then possibly a command for the relevant line module LB in section A 2 . After a pause P 1 , the activated line module LB has the option of transmitting a message to the center Z in section A 3 . After a pause P 2 has elapsed, the same line module LB or another line module can be controlled by the control center Z in the manner already described. The breaks P 1 and P 2 serve to separate the direction during transmission, so that there is a sufficient safety time between transmission in one direction and transmission in the other direction, within which reflections and transient processes have certainly subsided.

The hazard alarm system according to the invention enables the targeted and also repeated activation of a certain line module, the addresses from the memory SP ( FIG. 1) of the central station Z not only being read cyclically but also being made available according to other aspects. The hazard alarm system also enables the querying and transmission of measured values from detectors to the control center Z. The measured values and alarm messages from the line modules LB are evaluated in the control center Z and printed out, displayed, with information identifying the relevant detector, etc. All known transmission methods can be used as transmission methods on line L , especially those in which the direct current component is as possible is low, so that transmission is also possible via normal two-wire copper lines. The line module LB itself can be used, for example, in the base of a detector.

Not only a single detector but also an evaluation circuit can now be connected to the line module LB , which is used to connect a loop with several detectors.

To increase the security of the alarm system Against sabotage, the address assignment can be made on a regular basis or irregular intervals are made, a scrambling of the addresses of the line modules is provided. That means that in regular or irregular distances between the individual line modules get different addresses.

Claims (12)

1.Danger alarm system with a large number of measuring points connected to one or more two-wire star and / or loop lines, with the message being transmitted from the measuring point to the control center via the line and the message being evaluated and processed in the same (alarm message, display, etc .) A switching means is provided for each measuring point, which can be closed and opened at the command of the control center and connects the line to the next measuring point, each measuring point has a control device and a transmitting / receiving device, each measuring point by the control center with the help an address transmitted via the line can be controlled and in the activated state it is possible to receive a command or send a message, when the hazard alarm system is started up, the switching means of all measuring points is open, each measuring point is assigned an address by the control center, this address as measuring point address se is stored in the control device and the measuring point in question is then controlled via this address and the control center initiates the closing of the switching means by a corresponding command, characterized in that the measuring point is designed as a line module ( LB) and a detector interface (MS) first connections (E 1 , E 2 , D) , each with a resistance (R 1 ) to voltage, with second connections (E 3 , E 4 ), each with a resistance (R 2 ) to ground, and with third connections (S 5 to S 8 ), which are each provided with a resistor (R 3 ) against voltage with a transistor (TS) , the collector of which is connected to the terminal and the emitter of which is ground, the transistor (TS) being used as the terminal Entrance is blocked. 2. Hazard detection system according to claim 1, characterized, that the address assignment in regular or irregular intervals. 3. Hazard detection system according to claim 1 or 2, characterized, that the addresses to be allocated are scrambled. 4. Hazard detection system according to one of claims 1 to 3, characterized in that the detector interface (MS) has a fourth connection (V) for the power supply. 5. Hazard detection system according to one of claims 1 to 4, characterized in that a measured value transmission from the detector (M) is prepared by a voltage signal at the terminal (D) of the detector interface (MS) , the measured value via the first, second and / or third Connections (E 1 to S 8 ) is transmitted. 6. Hazard detection system according to one of claims 1 to 5, characterized in that the transmission of addresses, commands and messages between the center (Z) and the line module (LB) takes place in half-duplex. 7. Hazard detection system according to claim 6, characterized in that in each case first the address and then possibly a command to the line module (LB) and after a pause a message is possibly transmitted, the addressing of the line modules (LB) taking place cyclically at certain intervals . 8. Hazard detection system according to claim 6 or 7, characterized, that for the transmission of address, command and A rigid frame is specified for the message at the beginning and at the end by certain bit positions the data words is selected. 9. Alarm system according to claim 8, characterized in that the frame is divided by certain data words into sections (A 1 to A 3 ), which serve to transmit the address (A 1 ), command (A 2 ) and message (A 3 ) . 10. Alarm system according to one of claims 1 to 3, characterized in that a memory (SP) is provided in the center (Z) , in which the addresses of the line modules (LB) is entered together with the respective detector type and detector number. 11. Hazard detection system according to claim 10, characterized in that the detector states are entered in the memory (SP) . 12. Hazard detection system according to one of claims 1 to 11, characterized, that in the event of an alarm or revisions, the polling cycle will be changed.