WO2008034527A1

WO2008034527A1 - Method and system for identifying a hazard warning device

Info

Publication number: WO2008034527A1
Application number: PCT/EP2007/007797
Authority: WO
Inventors: Ueding Markus
Original assignee: Novar Gmbh
Priority date: 2006-09-19
Filing date: 2007-09-06
Publication date: 2008-03-27
Also published as: DE102006043867A1; EP2064685A1; DE102006043867B4; ES2527920T3; CN101356554A; CN101356554B; EP2064685B1

Abstract

A hazard warning device which has gone into the alarm state and which then emits flashes of light as individual flashes with a predefined timing pattern can be identified from among a plurality of warning devices of the same kind which are connected to a control centre of a hazard warning system via a two-conductor signalling line and which also emit individual flashes, if the warning device which has gone into the alarm state is switched over to the generation of physiologically perceivable double flashes.

Description

Method and installation for identifying a hazard detector

The invention relates to a method for identifying a signaled in the alarm state danger detector among a plurality of connected via a two-wire reporting line to a control panel of a hazard detection system, individually addressable detectors, at least some of which comprise an LED, after activation by data telegram of the center in a predetermined Blinkenakt flashes flashes as individual flashes.

The invention further relates to a hazard alarm system with a control center which supplies at least one addressable detector with its supply voltage via at least one two-wire signal line and communicates with it bidirectionally via data telegrams, wherein the detector contains at least one sensitive to a physical size sensor and a signal processing circuit, the generated upon receipt of a first data telegram from the control unit a control pulse train for a driver circuit, which emits an LED in one of the control pulse sequence corresponding flashing light flashes as individual flashes.

From DE 10 2004 046 743 Al a security alarm system of the type indicated above is known. Their detectors can automatically respond to one or more accompanying variables, in particular a fire and / or a break-in. The same system may include manually triggered hazard detectors, eg fire alarms and / or panic buttons. At least individual detectors are in addition to the usual, the Operating state signaling LED equipped with another, very bright LED. Each of these detectors has a driver circuit which, when activated, causes the LED to emit flashes of light, each of which consists of a series of very short flash pulses to minimize the required but limited electrical power supply. Their pulse duration and the pulse / pause ratio are chosen so that these flash pulses for the eye merge into a single flash of light.

This danger control system can be operated such that, in the event of an alarm, not only the LEDs of a detector which has gone into alarm but also the LEDs of a configurable number of further detectors thus equipped emit flashes of light, e.g. to identify a danger zone around the detector that went into alarm. For this purpose, the control center sends a corresponding data telegram to the relevant detector whose signal processing circuit then activates the LED via its driver circuit.

In this case, it is difficult for an observer to visually identify, among a plurality of flashing detectors, the person who has entered the alarm state and is thus the initiating detector, because the intense flashes of light cover the light signal of the usual, faint, glare by glare operating control lamp.

From US 2002/0101189 Al a position light for aircraft is known. The position light consists of a large number of annular LEDs arranged one above the other in several levels. It can emit light signals in the form of double flashing lights. However, these are not a criterion for identifying a particular aircraft under a large on number of aircraft equipped with the same position light in the same airspace.

The invention has for its object to provide a method and a system of each of the introductory genus that allow under the conditions mentioned an observer to identify under a plurality of flashes emitting detectors or gone into alarm condition detector without As a result, a significant additional demand for electrical power is created for the detector or detectors.

In a method of the type specified in the introduction, this object is achieved according to the invention in that the alarm that has gone into the alarm state is switched over to the generation of double flashes.

Switching to the generation of double flashes may e.g. be effected by a signal internal, the alarm state representative signal.

Instead, the switching to the generation of double flashes can be effected by a data telegram of the central office.

In particular, the switching can be effected by an AND connection of the detector-internal signal representing the alarm state and a signal derived from a data telegram of the control center.

Because the clock of the individual flashes is generated inside the detector, it makes sense to generate the double flashes in the same clock, ie with the same repetition frequency as the individual flashes. An additional need for power, which is always limited on the reporting line or even from a battery available, can be avoided if the sum of the pulse durations of a double flash in the same order of magnitude as the pulse duration of a single flash is selected.

In a hazard alarm system of the type mentioned above, the above-mentioned object of the invention is achieved in that the signal processing circuit generates a second control pulse train upon receipt of a second data telegram that allows the driver circuit to emit the LED instead of the individual flashes of physiologically detectable double flashes.

A detector that has gone into alarm therefore does not switch automatically to the delivery of double flashes but only after receiving the corresponding command represented by the second data telegram from the control center.

The same problem is solved in a generic same hazard alarm system in that the signal processing circuit of the detector performs a logical AND linkage of a signal representing the alarm state of the detector signal with a decoded from the first data telegram signal and that the signal processing circuit with satisfied AND condition a generates second control pulse sequence, which leaves the driver circuit, the LED instead of the individual flashes physiologically detectable double flashes.

Both solutions can be combined with each other by appropriate configuration of both the control center and the corresponding detector as an OR operation. A detector that has gone into alarm then emits double flashes when it has detected its own alarm status and either receives the first data telegram from the control center, ie the one that triggers the generation of individual flashes when the detector is not in the alarm state, or receives the second data telegram, ie the one that triggers the generation of double flashes.

The pulse duration of a single flash can be between about 5 and about 80 ms, corresponding to a compromise between a physiologically still sufficiently clearly perceptible brightness and the requirement for low power consumption.

The period of the flash cycle can be between about 0.5 and 8.0 s, corresponding to the usual rhythm for optical warning signals.

In order not to increase the power requirement, each of the two flashes of a double flash preferably has about half the pulse duration of the single flash and a pause of about 10 to 150 ms corresponding to a total duration of a double flash of about 15 ms minimum and about 225 ms maximum.

The driver circuit is preferably designed so that both the individual flashes and each of the two flashes of a double flash consist of a series of short flash pulses whose pulse duration between 5μs and 50μs and their pulse / pause ratio in the range of about 1:10.

Preferably, the driver circuit is designed so that it compensates for a falling supply voltage by extending the pulse duration of the flash pulses, which are physiologically perceived as a single flash or a double flash. As a result of this measure, the subjective impression of brightness within the wide, permissible supply voltage range of a detector remains independent of the supply voltage, which can, for example, fall from 42 V at the beginning of a reporting line to 8 V at the end of a reporting line.

The invention is also applicable to alarm systems with radio observers, in which also the problem of visual recognizability of the gone into alarm conditioner detector and at the same time the power consumption needs to be kept small with respect to the life of the respective detector supplying battery.

The method and the alarm system according to the invention are explained below with reference to the drawing, which refers to a simplified embodiment. It shows :

Fig. 1 is a block diagram

Fig. 2 shows two signal diagrams.

FIG. 1 shows in a very simplified manner a hazard alarm system, in this case a fire alarm system comprising a fire alarm center 1, to which a number of automatic detectors, e.g. Smoke detectors and manual, which are triggered by a push button, is connected, of which only an automatic fire detector 3 is representative represented. To the central office 1 more reporting lines can be connected. The detection lines can, as is known, also be closed annularly.

The fire panel 1 includes, as usual, including a supply voltage supply 1.1 for the connected detectors, a detector query part 1.2, a detector control 1.3 and a communication interface 1.4. The usual, other components that are not necessary for the understanding of the invention are not shown. The fire panel 1 communicates with the fire detector 3 and all other detectors bidirectional and individually via the respective communication interfaces sent and received, addressed data messages.

The fire detector 3 comprises a number of circuits which draw their operating voltage from a voltage regulator 31 connected to the reporting line 2a, 2b. Furthermore, a communication interface 32 is connected to the signaling line 2a, 2b. This is connected to a signal processing circuit 33, usually in the form of a μ-controller, which i.a. As usual, a CPU with RAM, ROM and EEPROM includes and receives signals from a sensor 34.

The sensor 34 includes e.g. a temperature sensor, a scattered light measuring chamber and / or a gas sensor and the associated control and evaluation circuits. In the case of a hand-held detector, the sensor, e.g. a push-button switch contact.

The signal processing circuit 33 controls i.a. a driver circuit 35 for a high-current LED 36. The driver circuit 35 receives its operating voltage from the voltage regulator 31. The structure and the operation of the driver circuit are known from DE 10 2004 036 743 Al, Fig. 3. When a control signal or a control pulse sequence coming from the signal processing circuit 33 is present at its input 35. 1, the driver circuit 35 leaves the

High-current LED 36 emitting intense flashes of light in time with this control signal. In this case, each flash of light consists of a large number of very short flash pulses, which generates the driver circuit self-oscillating when applied at its input 35.1 control signal. The timing of the control signal also corresponds to that of a Viewers subjectively or physiologically perceived light flash or light flashes.

The signal processing circuit 33 generates in a first operating state, a control signal Sl with the timing shown in Fig. 2 when it receives from the fire panel 1 via the communication interfaces 1.4 and 32 derived from a first data telegram first command. This decodes an instruction processing 33.1 and applies a signal to a first input of a drive logic 33.2, which then generates the control signal S1, which consists of a pulse train with a pulse duration of e.g. 40 ms and a pulse period of e.g. 1 s exists. In this cycle, the LED 36 therefore emits individual flashes.

In a second operating state, however, the signal processing circuit 33 generates via the drive logic 33.2 a control signal S2 with the time course also shown in Figure 2, in which at the location of each pulse a double pulse occurs whose individual pulses together the same pulse duration as the pulse of the control signal Sl in Fig. 2 have. The generation of the corresponding double flashes therefore does not require more power than the individual flashes in FIG. 2.

In this second operating state, the control logic 33.2 generates the control signal S2 either when it receives the first command from the fire panel 1 via the command processing 33.1 and a signal corresponding to the alarm state at a second input from an alarm decision circuit 33.3 at its first input (as before) , or if it receives at its first input from the fire panel via the command processing 33.1 derived from a second data telegram, second command. In this configuration, the alarm decision circuit 33.3 outputs its output signal only to the error processing 33.1. The fire alarm panel 1 in turn sends this second command in the form of the second data telegram only if it has previously received from the fire detector 3 a data telegram representing its alarm state.

Claims

Patent claims

1. A method for identifying a gone into alarm condition danger detector among a plurality of connected via a two-wire reporting line to a control center of a hazard detection system, individually addressable detectors, at least some of which comprise a high-current LED, after activation by data telegram of the center in a predetermined Blinking flashes flashes as individual flashes, characterized in that the alarm went to the detector is switched to the generation of physiologically detectable double flashes.

2. The method according to claim 1, characterized in that the gone into alarm condition detector is switched to the generation of double flashes by a detector-internal, the alarm condition representative signal.

3. The method according to claim 1, characterized in that the gone into alarm condition detector is switched to the generation of double flashes by a data message of the control center.

4. The method according to any one of claims 1 to 3, characterized in that the gone into alarm condition detectors switched to the generation of double flashes by ANDing the detector-internal, the alarm state signal representative and derived from a data telegram of the center signal becomes.

5. The method according to any one of claims 1 to 4, characterized in that the double flashes are generated at least approximately in the same cycle as the individual flashes.

6. The method according to any one of claims 1 to 5, characterized in that the sum of the pulse durations in the same order of magnitude as the pulse duration of a single flash is selected.

7. danger alarm system, in particular for carrying out the method according to one of claims 1 to 6, with a central unit (1) which supplies at least one addressable detector (3) with its supply voltage via at least one two-wire signal line (2a, 2b) and bidirectional with it communicates via data telegrams, wherein the detector contains at least one sensor (34) which is sensitive to a physical size and a signal processing circuit (33) which receives a first data telegram from the control center (1)

Control pulse sequence (Sl) for a driver circuit (35) generates, which emits a bright LED (36) in a flashing pulse flashes corresponding to the control pulse sequence, characterized in that the signal processing circuit (33) generates a second control pulse train (S2) upon receipt of a second data telegram in that the driver circuit (35) allows the LED (36) to radiate physiologically perceptible double flashes instead of the individual flashes.

8. danger alarm system, in particular for carrying out the method according to one of claims 1 to 6, with a central (1), which supplies at least one addressable detector (3) with its supply voltage via at least one two-wire signal line (2a, 2b) and bidirectional with it communicates via data telegrams, wherein the detector (3) contains at least one sensor (34) which is sensitive to a physical quantity and a signal processing circuit (33) which generates a control pulse sequence (S1) for a driver circuit (35) upon receipt of a first data telegram from the central a high-luminance LED (36) emits flashes of light corresponding to a flashing rate corresponding to the control pulse sequence (S1), characterized in that the signal processing circuit (33) is a logical AND operation of a flash unit

Alarm state of the detector (3) representing signal decodes with a signal decoded from the first data telegram and that the signal processing circuit (33) generates a second control pulse train (S2) when the AND condition is fulfilled, the driver circuit (35) the LED (36) Instead of the individual flashes, you can radiate physiologically perceptible double flashes.

9. hazard alarm system according to claim 7 or 8, characterized in that the pulse duration of the single flash is about 5 to 80 ms.

10. hazard alarm system according to one of claims 7 to 9, characterized in that the period of the

Flashing rate is about 0.5 to 8.0 s.

11. Alarm system according to one of claims 7 to 10, characterized in that each of the two flashes of a double flash has about half the pulse duration of the single flash and a pulse pause of about 10 to 150 ms, corresponding to a total duration of a double - flash of a minimum of about 15 ms and a maximum of about 225 ms.

12. hazard alarm system according to one of claims 7 to 11, characterized in that the driver circuit (35) generates the individual flashes and the double flashes each of a rapid succession of short flash pulses between 5μs and 50μs with a pulse / pause ratio of about 1:10 self-oscillating.