NO862686L - PROCEDURE FOR TRANSFER OF MEASUREMENT VALUES IN A MONITORING SYSTEM. - Google Patents

Abstract

1. A method of transmitting measured values in a surveillance system for the protection of buildings and having monitoring points (MS) which contain a measuring sensor (M), a measured value transducer (W) and a switch element (S) controlled by a monitoring unit (KE), and which, for the purpose of transmitting signals, are connected in a chain-like manner by way of signal lines (L) to first pairs of terminals (K1) of a signal exchange (Z) in which the signals are then combined to obtain differentiated fault or alarm signals, characterised in that the switching elements (S) provided in the monitoring points (MS) are conductive when put into operation, whereby the line signal on the signal line (L) arrives at all the monitoring points (MS) and permits the latter to synchronize to the synchronizing information contained in the line signal, that all the monitoring points (MS) are brought into a neutral state by a reset command from the signal exchange (Z), that the associated switching element (S) is momentarily opened by a control command of the monitoring unit (KE) at predetermined instant within the time raster defined by the synchronizing information, and that, as a result of this voltage interruption, all the monitoring points (MS), with the exception of the first monitoring point, receive a mark which indicates that the line signal received only serves for synchronization purposes and not for evaluation, and that the first monitoring point (MS1) is the only one to evaluate the signal, perform the corresponding command, give the reply and then switch on the switching element (S1) permanently, whereby the following monitoring point (MS2) receives a line signal without a mark and therefore in turn evaluates the signal, performs the corresponding command, gives a reply and then also switches on the associated switching element (S2) permanently, so that the operation can be repeated at the further monitoring points (MS) until the cycle is terminated at the last monitoring point (MSm) and a fresh cycle is started by a reset command by bringing all the monitoring points (MS) into the neutral state again.

Description

The invention relates to a method for transferring measurement values in a monitoring system for the protection of buildings, according to the introductory part of patent claim 1.

To solve diverse monitoring tasks, measuring points are distributed in extended objects and connected to a signal center via a signal line. In this context, it is increasingly important to know the exact origin of the measurement value, in order to satisfy the requirements for intelligent signal processing, i.e. the measurement location must be identifiable.

The identifiability of the measurement locations can be achieved mainly in three different ways. The oldest known method, which is, however, used very little today, involves running a separate wire from each measuring point to the signal centre. This solution is associated with a very high installation cost. In this connection, modern systems use either the chain step coupler principle, where the measuring points are connected in series and the identification takes place by counting corresponding step pulses (see fig. 1), or by individually fixed-addressed measuring points, which are connected in parallel to the line (fig. 2). A method based on the chain step coupler principle according to fig. 1, is discussed in DE-AS 2 533 382.

The essential difference between the two last-mentioned methods is that with the chain step coupler principle all measuring points can be the same, while with the parallel system the measuring points can be different in terms of their addresses, which is achieved either with the help of switches or special programming aids. It should be self-evident that equal measuring points show the predominant advantage both from a mass production point of view and with regard to maintenance, and also excludes the danger of replacement and misaddressing. The known method for identifying measuring points in transmission systems has the following disadvantages: 1) Higher installation costs because a separate wire must be brought back for each measuring point. 2) The long pauses in the current supply for the separate measuring points arising from the chain step coupler principle require a correspondingly powerful local voltage shift. 3) With the chain stage coupler principle, there is no signal that allows a permanent synchronization of the system, which works with a defined time slot. 4) The chain stage coupler principle reduces the transmission capacity of systems with defined time grids, because after connecting a measuring point, a specific time is first included for their synchronization.

5) Different measurement locations.

The invention is based on the task of providing a method for transferring measured values in a transfer system and a device for carrying out the method, which eliminates the disadvantages mentioned above, and in particular to provide a transfer system which, with the help of small installation equipment, enables a secure identification of the measurement points, the maintenance of the system's synchronization on a defined time frame and the transfer of the system's measurement values to a signal centre, since similar measurement points can be used which are connected in a chain form with the signal centre.

A further task which forms the basis of the invention is that the measuring points are equipped in such a way that they can be controlled via loop-shaped signal lines from both sides from the signal centre.

These tasks are solved by a method of the nature indicated at the outset, by the characteristic features specified in patent claim 1. The invention is further developed by the characteristics specified in the dependent claims.

The method according to the invention avoids a significant disadvantage of the chain step coupler method, namely that the measurement locations that are further away from the signal center receive neither supply voltage nor signal for a longer period of time.

The origin of the signals from the measuring points that appear in the signal centre, i.e. the identification, can be realized according to two methods: Firstly, by counting the sent commands and secondly by the measuring point address, provided that a cycle of especially commands for creating an individual address. By combining the two methods, i.e. by comparing the number of commands sent out with the individual address reported back from the measuring point to the signal centre, a very high degree of security can be achieved in terms of measuring point identification.

The transfer of the measured value can now take place, as described in DE-AS 2 533 382, i.e. at each polling cycle the switching element is made active. However, the transfer can also take place by means of a parallel transfer system, the switching element remaining closed.

A device for carrying out the method according to the invention comprises measuring points which have a measuring quantity sensor, a measuring quantity converter, a control unit, an address store and a switching element. In the following, with reference to the drawings, a preferred embodiment of the invention will be described in more detail. Fig. 1 shows a series-connected, chain-connected monitoring system according to known technology. Fig. 2 shows a parallel addressed monitoring system according to known technology. Fig. 3 is a block diagram of a measuring point MS for carrying out the method according to the invention. Fig. 4 is an embodiment of the monitoring system according to the invention. Fig. 1 shows the structure of a current monitoring system

em according to the chain stage coupler principle. From a signal center Z there extends one or more signal lines L to which a plurality of measuring points MS are individually connected. The measuring points MSm essentially comprise, in addition to the measuring sensor and the measuring converter, a signal receiver, a flow controller, a signal generator and a connecting element Sm. After application of the line voltage on the signal line L, a time element in the measurement location MSI will start to run. After a certain delay, the switching element Sl closes and applies the line voltage to the second measuring point MS2, where likewise a timer begins to run. In this way, all switches for the measurement locations MSm in a signal line L will close one after the other. This relationship can be periodically repeated, so that all measuring points MS for a line are polled cyclically. After application of the line voltage at a measuring point MSm or when closing the relevant switching element Sm, a transfer of the measured value for the measuring sensor M to the signal center Z can take place there.

Buffer capacitors located in the measurement locations ensure energy supply for the measurement locations during the possible occurrence of system-related voltage interruptions.

Fig. 2 shows a current parallel addressed monitoring system. The individual measuring points MS for the entire plant are similar to fig. 1 distributed over different signal lines L and via these signal lines L connected to the signal center Z. Each signal line L consists of a two-wire cable, with which all measurement locations MS in a signal line L are connected in parallel. Each measurement location MS is characterized by a fixed address Am. When sending out this characteristic address Am, the signal center Z can call up each arbitrary measuring point MSm and e.g. cause the release of their measured value. The address signals can e.g. consist of a digital pulse sequence, a specific voltage, frequency or tone sequence, or of arbitrary combinations of these elements. In the case of a large number of measuring points MS per signal line L, only a digital pulse train will be used in practice, because in this connection a fixed arbitrary number of different addresses with integration-friendly elements of modest accuracy can be realized. With the help of additional digital pulse trains, complicated instructions can also be transmitted to one and another addressed measuring point.

A known disadvantage of the mentioned parallel system is the possibility of a measurement location being confused or an incorrect addressing which is difficult to detect. In addition, a wire short circuit will put an entire signal line out of service.

Fig. 3 shows the block diagram for a measuring point MS for the insert in the transfer method according to the present invention. Target MS can be a fire alarm, e.g. an ionization detector, an optical smoke detector, a temperature detector

or a flame detector, or a monitoring unit in an intrusion protection system, e.g. a passive infrared detector, an ultrasonic detector or a noise detector, or any measurement point in a transmission system.

At each measuring point MS, a directionally symmetrical (bilateral) switching element S is arranged, which connects the two input/output terminals 1 and 2 to each other. In building group B, a measuring sensor M, a measuring converter W, a control unit KE, an address store AR and a command store BS are arranged.

The state of the switching element S is controlled by the control unit KE, which also contains means for signal indication. Via clamps 1 and 3a on the one hand, and clamps 2 and 3b on the other hand, the measuring points are connected to each other and to the signal center generally, as can be seen in fig. 4.

Because the connection element S is directionally symmetrical (bilaterally) designed, the measuring points MS can be supplied with power from both sides, i.e. the signal lines can be connected to terminals 1 and 3a as well as to terminals 2 and 3b for the measuring point MS, which entails a simplification and increase of safety during installation.

In addition, the control unit KE contains its own wire short-circuit detector for the left and right connection terminals. When a short-circuit is detected, a reduction of the voltage on the non-short-circuited terminal below the necessary operating voltage will be avoided by opening the switching element S. It is thereby possible to maintain the operation of all measuring points MS up to the wire short-circuit.

The measuring points MS are symmetrical with respect to the connection terminals, i.e. interchangeable. A preferred embodiment of the method according to the invention is that the signal line L from the last measuring point MS is again led back to the signal centre. The monitoring of the measuring site MS can now take place from two sides. Thereby, in connection with the aforementioned short-circuit detector, it becomes possible in the event of a line short-circuit or interruption to maintain the data traffic from and to the measurement locations MS to the full, by simultaneously reporting the line disturbance. In this context, it is of great importance that, according to the present method, one can easily convey the location of the line disturbance. This entails a particular advantage, as it is widely known that detecting wiring faults is very time-consuming and expensive.

Fig. 4 shows an embodiment of a transmission system according to the invention with measuring points MS which are controlled from the signal center Z. Here, as according to fig. 1, all measuring points MSm distributed over one or more signal lines L. The measuring points MS are structured according to fig. 3, i.e. they comprise a directionally symmetrical (bilateral) switching or switching element S, which can pass through the line signal arriving at one of the input/output terminals Kl to the other input/output terminal K2 and insert changes in the passed-through line signal, and in the building groups B a measuring sensor M, a measuring converter W, a control unit KE, an address store AR for storing the individual measuring point addresses and a command store BS for storing the commands.

The changes introduced by the switching element S in the line signal are termed "marking". The marking is noted in the line that emanates from the measuring point MS, as a momentary voltage interruption, which the subsequent measuring point MS indicates that the information coming from the signal center Z is not to be evaluated and is only used for synchronization purposes. During operation, all switching elements S are conductive, so that all measuring points MS can be synchronized on the synchronization information contained in the line signal. A reset command before the start of a cycle for interrogating measured values brings all m measuring points MS to a neutral state, which causes all switching elements S, controlled by the associated control unit KE, at a defined time within the time slot given by the synchronization information , upon short-term opening, inserts a momentary voltage interruption as a marking in the outgoing line signal, whereby all from the first measuring point MSI the following m-l measuring points contain a signal with a marking which they exclusively use for synchronization. Because the measurement locations run synchronously, the introduction of the voltage interruption always takes place at the same time within the defined time slot, which for the rest of the time leads to a disturbance-free transmission of information.

The first measurement site MSI is the only one receiving an unmarked line signal, which causes it to be the only one evaluating the signal, executes the corresponding command, responds, then accepts no command except the reset command and does not insert any further command, leaving the switching element S stay permanently connected. The continuous switching on of the switching element S has the effect that from now on the line signal coming from the signal center Z will reach the subsequent measuring point without marking, after which the same, after evaluation, executes the corresponding command, responds, then likewise only accepts the reset command and keeps it belonging -end coupling element S permanently engaged. This causes the subsequent measuring point MS2 to also be activated, because it receives a line signal without marking. The cycle lasts as long as the described process has been completed in all the measuring points MS located in the signal line L. After the end of the cycle, a reset command is issued to all measuring points MS, with regard to returning to the neutral state and reinserting the aforementioned marking by short-term opening of the coupling element S. A new cycle can then be started.

The possibility of giving individual commands to each individual measuring point is used during operation of the transmission system to transmit an individual measuring point address to each measuring point MS, which they store in their address register AR. In this way, each measuring point MS obtains an identification, which distinguishes them from the other measuring points. This type of addressing avoids any manipulation at the measuring point itself and allows the advantages of a parallel system as well as those of the chain step coupler system to be exploited, without including their disadvantages. Of course, in the event of system failure1, disturbances or maintenance, the addresses can be re-entered in the register at any time.

Claims (9)

1. Procedure for the transmission of measured values in a monitoring system serving for the protection of buildings with measuring points (MS) containing a measuring sensor (M), a measuring converter (W) and a switching element (S) controlled by a control unit (KE), and which for signal transmission is connected in chain form via signal lines (L) to the first pair of clamps (Kl) to a signal center (Z), where the signals for the formation of differentiated disturbance and alarm messages are connected together, as the connecting elements (S) arranged in the measurement locations (MS) are conductive during operation, at the same time that the line signal on the signal line (L) reaches all measuring points (MS) and allows them to synchronize on the synchronization information contained in the line signal, characterized by the fact that upon a reset command from the signal center (Z) all measuring points ( MS) brought into a neutral state, so that at a control command from the control unit (KE) the associated coupling element (S) stays within the v ed synchronization information defined time slots opened for a short time, and that in the event of this voltage interruption, all measuring points (MS) with the exception of the first will receive a marking showing that the received line signal only serves synchronization purposes and not for evaluation, that the first measuring point (MSI) which is the only one to evaluate the signal, executes the corresponding command, issues the response and then engages the switching element (S1) continuously, whereby the subsequent one (MS2) receives a line signal without marking, and therefore in turn evaluates the signal , it executes the corresponding command, issues a response and then likewise engages the corresponding switching element (S2) continuously, so that the process at the further measuring points (MSm) can be repeated until the cycle is terminated at the last measuring point (MSm) and a new cycle can be started due to a reset command, whereby all measuring points (MS) are again brought to the neutral state. 2. Method as stated in claim 1, characterized in that address stores (AR) which are arranged in the measurement locations (MS) in a predetermined order are covered with the address for the measurement location (MS) from the signal center (Z) using appropriate commands. 3. Method as stated in claim 2, characterized in that the address store (AR) located in the measurement site (MS) closest to the signal center (Z) is first assigned the address belonging to the measurement site (MS). 4. Procedure as specified in claim 2, characterized in that the address store (AR) which is located in the measurement site (MS) farthest from the signal center (Z) is first assigned the corresponding address for the measurement site (MS). 5. Method as specified in one of claims 1-4, characterized in that the measurement locations (MS) with respect to the connection of the signal lines (L) are arranged directionally symmetrical (bilateral). 6. Method as specified in claim 5, characterized in that the signal lines (L) from the last measuring point (MS) can be routed back to other terminal pairs (K2) for the signal center (Z), and that the measuring points (MS) can be controlled from the signal center (Z) ) not only via the aforementioned terminal pair (Kl) but also via the other terminal pairs (K2). 7. Method as specified in one of claims 1-6, characterized in that after entry into the address stores (AR) for all measuring points (MS) in a signal line (L) all connecting elements (S) are closed and thus all measuring points (MS ) in the signal line (L) connected in parallel to the signal center (Z). 8. Method as stated in one of the claims 1-7, characterized in that the control units (KE) which are incorporated in the measuring points (MS) can detect a short circuit of the terminal pairs (1, 3A) and (2, 3B) above which the measuring points (MS) is connected to the signal lines (L). 9. Method as stated in one of claims 1-8, characterized in that the measuring points (MS) contain measuring sensors (M) for detecting the course of fire or products caused by fire, for detecting harmful gases or vapors or for detecting intrusion into an unguarded room.