EP0004909A1 - Annunciator of danger - Google Patents

Abstract

In the case of a hazard alarm system, the availability of the system is increased by decentralizing the system intelligence. The entire system is divided into small, fully functional system blocks (SYB), with each system block (SYB) connection devices (E1, E2 ... En) for one or more detectors (M) or for one or more subordinate system blocks (SYB), has a programmed control (PST) for querying and evaluating the detector signals as well as connections for display, operating and registration elements. One of the system blocks (SYB1) serves as the control center (Z), while the other system blocks (SYB 2, SYB 3, SYB 4) are subordinate to this control center in one or more hierarchical levels (K1, K2).

Description

The invention relates to a hazard alarm system with a plurality of detectors that can be connected to a central unit via signal lines, the status of the individual detectors in the central unit being ascertainable via test devices and displayable via an evaluation device, and wherein the individual detector signals can be queried and evaluated via a programmed controller is.

With security alarm systems, it is essential that faulty system parts are recognized and displayed. In addition, the system should be available, ie it should be as permanent and as fully operational as possible. In conventional systems, a separate central module is usually required for each message line, which contains both evaluation and display elements, and only forwards alarm and fault messages to a higher-level group display or registration. Due to the constantly increasing number of detectors and detector types connected to a detection system, also due to the further development forever the amount of information to be processed increases more precisely in the case of detectors which display analogously. As a result, more and more modules are required, which due to the increasing number of components also leads to an increased risk of failure.

In newer systems, a central data processing system is often used to process the large amount of information, but also to reduce the number of components. This is associated with the particular risk that the central assemblies will become inoperable, which will result in the failure of the entire alarm system.

The object of the invention is to obtain the advantages of a programmed control for the interrogation and evaluation of the detector signals, but at the same time to keep the risk of failure of such a control as low as possible or to limit it to the smallest possible part of the system.

According to the invention, this object is achieved in a hazard detection system of the type mentioned at the outset in that the system is formed from a number of individual system blocks, each system block connecting devices for one or more detectors or for one or more subordinate system blocks, a programmed controller for interrogation and Evaluation of the incoming detector signals and connections for display, control and registration elements, and that these system blocks are connected to each other with lines in such a way that one of the system blocks can be used as a control center and the other system blocks are assigned to this control center as nodes in one or more hierarchical levels .

In the alarm system according to the invention, the availability is increased by decentralizing the system intelligence. The entire system is therefore divided into small, fully functional system blocks, each of the blocks having its own controller, preferably a microprocessor; this controls all logical processes and processes the detector information that arises at the same time. Each system block has a number of slots in which controller boards for a wide variety of detector types can be inserted. All slots of a system block can be connected to each other by a universal cable bus; in this case, detector interface modules can be inserted in any arrangement. Each system block is expediently fed from its own power supply.

The connection devices in each system block can also have a simple fault and alarm display in parallel with the programmed control for the connected detectors or subordinate system blocks. This serves as a kind of emergency program, so that if the process fails, hazard messages can still be recognized on the detector interface.

The invention is explained in more detail below using exemplary embodiments with reference to the drawing.

• Fig. 1 ein Blockschaltbild für eine erfindungsgemäße Gefahrenmeldeanlage,
• Fig. 2 das Schema eines Systemblocks,
• Fig. 3 ein mögliches Blockschaltbild für eine Melderanschaltung,
• Fig. 4 eine mögliche Schaltungsanordnung für einen Systemblock.

It shows:.

• 1 is a block diagram for an alarm system according to the invention,
• 2 shows the diagram of a system block,
• 3 shows a possible block diagram for a detector connection,
• Fig. 4 shows a possible circuit arrangement for a system block.

Fig. 1 shows the structure of a hazard alarm system from several system blocks SYB. One of them, the system block SYB1, is located in the central office Z. It contains a programmed control system for evaluating the signals arriving from the connected detectors M and the connected, subordinate nodes K. This programmed controller is generally a microprocessor. In addition, a display and operating device AB, for example a data display station, and a registration device RG, for example a printer, are connected to the system block SYB1.

Nodes K1 and K2 are connected to the central station Z. For example, the node K1 contains a system block SYB2, to which the system blocks SYB3 and SYB4 are hierarchically subordinate. The subordinate system block can be accommodated in the same node K1 or in a remote node K2. The subordinate system blocks are connected in the same way as the detector M is connected via two-wire lines. Each system block can be provided with display and operating elements AB or with registration devices RG, if necessary.

The scheme of a system block is shown in Fig. 2. The system block SYB each contains a power supply module SV and a programmed controller PST, which is generally formed by a microprocessor. The system block also has a number of slots E1 .. _' . En for detector connections or for input and output modules. All installation locations are connected to each other and to the programmed control system via a universal bus system DB. This means that detector connections to which several lines can be connected can be plugged in any order.

3 shows the block diagram for. a detector connection, such as can be used in an E1 ... En slot. For example, the individual signal lines with the connected detectors can be connected to the KM terminals. Subordinate system blocks are also connected via these KM terminals. In the signal adaptation SIA, the incoming detector signals are brought into a processable form, for example converted into pulses. Such conversion of current measurements into pulses is shown for example in DE-AS 25 33 382. The evaluation AW generally contains comparison devices in which the detector signals are compared with setpoints and processed to form fault or alarm signals. These can be displayed in an activated display and operating device AB or forwarded via a bus interface BSS.

In order to clarify the mode of operation of a system block, FIG. 4 shows a possible circuit arrangement with the logic links, as is also carried out by a programmed microprocessor. Individual detection lines L1 ... Ln are connected to the system block SYB shown, to which detectors M1, M2 ... Mn are in turn attached. The signal lines each lead to a detector interface MA1 ... MAn, in which the condition of the line or the connected detectors is checked. Depending on this state, a signal r for idle state, a for alarm state or s for fault message appears at one of the three outputs.

For the sake of simplicity, the use of diode detectors is assumed, as shown at M1; This results in the above-mentioned message signals in the following way: An alternating current or a direct current with alternating polarity is transferred from the detector connection MA1 to the message line L1 given. As long as the alarm button AK is in the idle state, the one half-wave of the line current flows via the diode D1 and gives the idle signal r in the detector connection MA1. If the alarm button K is pressed, the other half-wave of the line current flows via the diode D2 and gives the alarm signal a in the detector interface MA1. If the line is interrupted, no current can flow through detector M1 at all. This is evaluated in the detector connection as a fault signal s. This interference signal is also generated if both half-waves can be received due to a line short circuit. If no detector is connected to the line, this would also be reported as a fault signal if appropriate measures were not taken. The output signals of the signaling interfaces MA1 ... MAn are queried synchronously via multiplex interrogators, namely the alarm signals a via the interrogator MX1, the fault signals s via the interrogator X2 and the idle signals r via the interrogator MX3. The serially output alarm signals a and the interference signals s are each forwarded via a comparison device VG. This can be done either directly to a display device connected in the system block or via a two-wire line to a higher-level system block.

The serial incoming fault and alarm signals can be put on a common line via an OR gate OR2. The signals for the individual detection lines can then be output in parallel on a display device by means of a multiplexer which can be switched synchronously with the interrogation device MX1, MX2 and MX3.

In order to evaluate alarm and fault signals only when the line in question is actually busy, this example continues a memory SP is provided, the individual memory locations Sp1... Spn of which are each assigned to an alarm line and in which the occupied state of this alarm line in question can be stored. These memory locations Sp1... Spn are scanned synchronously with the detector connections via the multiplex interrogation device MX7, and the signal read out from the memory location is compared in the comparison device VG with the incoming fault or alarm signal. Such a detector signal is only passed on via the coincidence elements AN1 and AN2 if the memory location in question is marked as occupied. To automatically write to the memory SP, it is preceded by a multiplex input device MX8, which also runs synchronously with the interrogation devices MX1, MX2 and MX3. If the actual status of the signaling system is now to be recorded and saved, i.e. during commissioning, then the BT operating button is still open. The AND gates AN1 and AN2 are blocked via the AND gate AN3 and do not allow any signals emitted by the detector connections to pass. On the other hand, an occupied state is written into the memory SP via the OR gate OR1 and the AND gate AN4, when an idle signal r or an alarm signal a is reported by the relevant detector interface MA1 ... MAn. In these cases, a detector is switched on on the relevant reporting line.

If a disturbance signal s is reported, a logical 0 is written into the memory location Sp in question, that is to say that the relevant detector line is identified as not being used. If the entire memory SP is written, the actual state of the system can be checked via a display device with light-emitting diodes LD1 ... LDn. If this condition is found to be correct, the system can be started using the BT operating button the. Now the AND gate AN4 is blocked via the negation gate NE1, so that the memory state can no longer be changed. Fault signals or alarm signals are only passed on via the AND gates AN1 and AN2 if the memory location in question shows the occupied state.

As mentioned, the functions shown in Fig. 4 can be performed by a programmed microprocessor with memory on. In particular, other detectors, e.g. analog detectors are evaluated and compared with setpoints formed in the microprocessor. Since each system block SYB is equipped in the same way with a microprocessor, data traffic between the individual blocks is possible via a standardized serial interface using a single pair of wires.

This results in a higher availability in the alarm system according to the invention due to the subdivision into mutually independent, program-controlled functional units with a few components, with mutually independent detector interface modules that function without a processor, and with interference-free data transmission between the individual system blocks that works with just a few wires. The failure of a module cannot lead to the failure of the entire system. Even in case of failure of the parent S ^y stemblocks all subordinate blocks remain fully functional.

Claims (4)

1. Hazard detection system with a plurality of detectors that can be connected to a central unit via signal lines, the status of the individual detectors in the central unit being ascertainable via test devices and being able to be displayed via an evaluation device, and wherein query and evaluation of the detector signals can be carried out via a programmed controller, characterized in that that the system is made up of a number of individual system blocks (SYB), each system block connecting devices (E1, E2 ... En) for one or more detectors (M) or for one or more subordinate system blocks, a programmed controller (PST ) for querying and ..Assessing the incoming detector signals and connections for display, control and registration elements, and that these system blocks are connected to each other with lines' in such a way that one of the system blocks can be used as a control center (Z) and the other system blocks of this control center in one or more hierarchical levels below are ordered. 2. Hazard detection system according to claim 1, characterized in that each system block has its own power supply device (SV). 3. Alarm system according to claim 1 or 2, characterized in that each system block (SYB) has a microprocessor for evaluating the incoming signals from connected detectors and / or subordinate system blocks. 4. Hazard detection system according to claim 3, characterized in that in each system block (SYB) the connection devices for the detectors or subordinate system blocks have a simple fault and alarm display parallel to the programmed control.

Images