EP0971328A1 - Device for testing smoke detectors of the light diffusion type - Google Patents

Abstract

The testing device comprises a measurement chamber (5) with a measurement light source (6) that emits a light pulse. There is a measurement light receiver (7) with an adapter (1) that is open on one side. This can be placed on the alarm, and contains a test light source (3) for subjecting the measurement light receiver to test light pulses. The adapter has a detector (2) that responds to the electromagnetic field produced by the current pulse of the measurement light source, and controls the test light source.

Description

The present invention relates to a device for checking the function of Scattered light smoke detectors, which emit a measuring chamber with a light pulse Have measuring light source and a measuring light receiver, with one on one side open and can be placed on the detector to be tested or slid over it Adapter, which can be operated synchronously with the light pulses of the measuring light source Test light source for applying test light pulses to the measuring light receiver contains.

As is known, the measuring chamber of scattered-light smoke detectors is as tight as possible against Light shielded from the outside to make the detector largely immune to extraneous light close. However, this shielding cannot be absolute because the detectors are against the outside atmosphere must be open so that smoke can enter the measuring chamber can. The influence of the interference of those entering the measuring chamber despite the shielding To minimize extraneous light, the detector's evaluation circuit is designed in such a way that the measuring light receiver only reacts to light that is within a defined range Time window after the triggering of the respective light pulse of the measuring light source Will be received.

In a detector tester described in EP-A-0 636 266 (US-A-5,523,744) The type mentioned at the outset is operated by a test light transmitter Detector tester arranged additional light receiver, which receives a light pulse the test light source triggers the test light source. Because of the shielding mentioned the measuring chamber against extraneous light, the additional light receiver receives the light pulses not in every relative position of the detector tester to the detector, but only in certain ones Positions can be received with this detector tester provided to ensure that the detector tester is always in the test position is in the same orientation with respect to the detector.

The measuring light source and the additional light receiver take in this orientation of the detector tester as well as the test light source and the measurement light receiver Relative positions in which it is guaranteed that the light pulses of the measuring light source on the additional light receiver and the flashes of the test light source on the Measuring light receiver arrive. Because the positioning means the presence of appropriate This detector tester is a prerequisite for guiding means on the smoke detectors can only be used for detectors of a certain type and can in principle be used for detectors cannot be used without such guide means.

By the invention, a detector tester is now to be specified in any Alignment position in relation to the detector to be tested works properly and which is therefore universally applicable and easily adapted to different types of detectors can be.

The object is achieved according to the invention in that the adapter is on responsive to the electromagnetic field generated by the current pulses of the measuring light source and the detector controlling the test light source.

In the detector tester according to the invention, the measuring light source is no longer used emitted light pulses detected as such, but by the light pulses triggering current pulses generated electromagnetic field. Because this field is the detector surrounds on all sides and relatively homogeneously, the detector tester can light pulses in any Detect alignment with the detector.

This is a first preferred embodiment of the device according to the invention characterized in that means are provided for reflecting the test light pulses into the measuring chamber are. These means of reflection of the test light pulses, of course, too Means to disperse them can ensure that in any orientation the detector tester has a sufficient proportion of the test light pulses compared to the detector is directed into the measuring chamber and reaches the measuring light receiver.

A second preferred embodiment of the device according to the invention is thereby characterized in that the said detector is formed by an induction coil is.

A third preferred embodiment of the device according to the invention is thereby characterized in that the means mentioned for reflection of the test light pulses a reflective coating arranged on the inside of the adapter is formed.

A fourth preferred embodiment of the device according to the invention is thereby characterized in that the adapter is a rotationally symmetrical, box-like or can-like Has shape, and that the induction coil on the inside of the adapter is arranged. Preferably, the induction coil is near the edge of the open one Side of the adapter or on the bottom opposite the open side.

This is a fifth preferred embodiment of the device according to the invention characterized that the test light source near the edge of the open Arranged side of the adapter and the reflective coating by one of those Edge adjacent strip-shaped area is formed.

Another preferred embodiment is characterized in that the induction coil containing bottom part of the adapter is covered by a film.

The detector tester according to the invention can in principle be used for testing for any type of stray light detectors are used, so that usually for the detector test used relatively expensive test gas can be dispensed with. That doesn't just result a cost saving but also enables a much faster inspection of whole Detector lines because every detector is fully functional immediately after the test and does not have a measuring chamber filled with the test gas as in the test with test gas and blocked by further alarms the further test.

Another preferred embodiment of the device according to the invention is characterized through an electronic circuit to synchronize the release of the test light pulses with the light pulses of the measurement light source, which circuit one Stage for suppressing interference pulses from the signal supplied by the induction coil which has an amplifier, a voltage divider and an electronic contains adjustable resistance, whereby by the adjustable resistance automatically such a shift of the operating point of the amplifier takes place that the interference pulses and the measuring pulses caused by the pulses of the measuring light source differ Sides of the zero line.

Fig. 1

eine schematische Darstellung eines erfindungsgemässen Melderprüfers; und

Fig. 2

ein Blockschema der Schaltung zur Synchronisierung der Mess- und der Prüf-Lichtquelle.

The invention is explained in more detail below with the aid of an exemplary embodiment and the drawings; it shows:

Fig. 1

a schematic representation of a detector tester according to the invention; and

Fig. 2

a block diagram of the circuit for synchronizing the measuring and the test light source.

The detector tester according to the invention is used to check the function of smoke detectors on site, usually with detectors mounted on the ceiling of a room, and is closed trained for this purpose so that it is placed on the detector to be tested from below or can be pushed over this. The detector tester is especially for such detectors suitable, whose housing approximately the shape of a spherical cap or a truncated cone having. Such detectors are, for example, in the international model protection registrations DM / 028 534 and DM / 034 103. This hint is not to be understood as a restriction to the detector types mentioned; Of course is the detector tester according to the invention with possible minor adjustments in practice can be used with all modern stray light smoke detectors.

As shown, the detector tester essentially consists of a rotationally symmetrical, open on one side, sleeve-shaped adapter 1, from one on the inside of the adapter 1 arranged induction coil 2, at a short distance in front of the edge of the adapter 1 on its open side arranged light source 3 and from electronics 4 arranged in the region of the bottom of the adapter. The induction coil 2 can, as shown in the figure, on the bottom of the adapter 1 or also arranged on its upper edge, for example at the level of the light source 3 his.

As is indicated in the figure by a scattered light smoke detector M, the detector tester is placed on the detector to be tested or, if necessary, pushed over it. For a more detailed description of the smoke detector M, reference is made to EP-A-0 636 266, EP-A-0 821 330 and to the scattered light detectors of the AlgoRex series (AlgoRex - registered trademark of Cerberus AG).

The smoke detector M has a measuring chamber 5 shielded from light from the outside a measuring light source 6 and a measuring light receiver 7, whose optical axes are angled with respect to one another and in a central region of the measuring chamber 5 cross. The measuring light source 6 sends short, intense light pulses into the central area the measuring chamber 5, with no light rays due to the selected arrangement get directly from the measuring light source 6 to the measuring light receiver 7 can. Therefore, the latter "sees" the central area of the measuring chamber 5, but not the measuring light source 6. The light from the measuring light source 6 is the measuring chamber 5 scattered smoke and a part of this scattered light is striking the measuring light receiver 7.

Since the measuring chamber 5 must be designed in such a way that smoke can enter it also the light shielding of the measuring chamber should not be complete, so with a albeit a very small proportion of extraneous light can be expected within the measuring chamber 5 got to. To eliminate any interference from this remaining ambient light the evaluation electronics of the detector M are designed such that the measurement light receiver 7 only reacts to scattered light received by it if it is within a certain range Time interval after a light pulse is emitted by the measuring light source 6 arrives at him. The emission of a light pulse by the measuring light source 6 opens So a time window in the evaluation electronics, so that only within this time window generated reception signals of the measuring light receiver 7 are processed.

When performing the functional test of the detector detector shown Smoke detector M illuminates the light pulses of the measuring light source 6 intermittently the light source 3 of the detector tester referred to below as the test light source overlaid. These test light pulses arrive in the measuring chamber 5 of the smoke detector M. and in this on the measuring light receiver 7; after receiving one or more Test light pulses are then triggered in detector M Alarm, which is on the alarm indicator of the Detector or in the assigned signal center. This alarm trigger serves as a criterion that the detector is functional.

To ensure that the detector tester is facing in any orientation the smoke detector M as large as possible of the test light pulses into the measuring chamber 5 is steered and reaches the measuring light receiver 7, can in the level of Test light source 3 with a strip-shaped area of the inner wall of the detector tester be provided with a reflective coating 8.

The induction coil 2 detects that generated by each light pulse of the measuring light source 6 electromagnetic field and controls the test light source 3 so that it is within of the specified time window emits test light pulses. To bundle the above electromagnetic field on the induction coil 2, the latter by one metallic cylinder 9, open at the top, surrounded by the upper end face an electromagnetically permeable film 10 can be covered. The film can can also be arranged above the cylinder 9.

The adapter 1 is installed in a hood-shaped housing 11 which is placed on a sleeve 12. In the latter, a pipe socket 13 is inserted, on which an extension pipe can be pushed. The detector can be checked up to a room height of around 7 m with several of these extension tubes that can be connected to one another by means of pipe clamps. The detector tester is powered either by batteries or by a power cable, with the battery compartment or the power supply unit being located on the lowest extension tube. This box-like device part, which also contains a switch for switching the detector tester on and off, is designated in FIG. 1 by the reference symbol BF. The housing 11 can also be connected to the pipe socket 13 via a fork-shaped adapter (not shown), as is the case with the detector testers for the AlgoRex detectors mentioned.

Figure 2 shows a block diagram of the adapter containing the induction coil 2 1 connected circuit 4, which is used to synchronize the test light source 3 with the Measuring light source 6 is used. As shown, the circuit 4 contains one to the induction coil 2 connected first preamplifier stage 14, one connected to this High / low pass filter 15, a second preamplifier stage connected to the filter 15 16, one connected to the latter and 17 with this bidirectional output stage interacting stage 18 for interference suppression and automatic gain control. An active time filter 19 is connected and connected to the output stage 17 this is a difference evaluation 20. The difference evaluation 20 is a stage 21 for Generation of the electrical pulse downstream for triggering the test light pulse and this a voltage converter 22 connected upstream of the test light source 3. The latter is preferably arranged in the device part BF (Fig. 1).

The test light source 3 is by a flash lamp or flash tube, for example one Xenon tube, formed, and the voltage converter 22 is used to provide for the Ignition of the flash lamp required voltage. Of the voltage converter 22 is one for connection to lightning interference suppression 23 to the output stage 17 is provided.

The measuring light source 6 formed, for example, by an infrared diode (IRED) (FIG. 1) sends a light pulse at regular intervals of 1 to 3 seconds, for example , whereby in the induction coil 2 a voltage pulse referred to below as the measuring pulse MP of about 100 µs duration is induced. This measuring pulse is very small and is a few millivolts.

It goes without saying that the induction coil 2 is not only caused by the pulses of the measuring light source Voltage pulses induced, but also by the different communication currents on the detector lines. Distinguish from these interference pulses denoted by SP the measuring pulses MP essentially by their significantly lower frequency and by their duration. The voltage pulses induced in the induction coil 2 are are amplified in the first preamplifier stage 14 and then in the high / low pass filter 15 filtered out the coarsest interference pulses.

After further amplification in the second preamplifier stage 16, the signal arrives in the final stage 17 and in stage 18 for suppression of interference pulses and automatic gain control. At this stage, which is essentially an amplifier, a voltage divider, contains an electronically adjustable resistor and a capacitor, are shifted (off-set) in the operating point of the amplifier by the adjustable resistance the measuring pulses MP and the interference pulses SP on different sides shifted the zero line, as shown the measuring pulses MP in the negative and Interference pulses SP in the positive range. As a result, the interference pulses SP can simply be hidden become. The voltage divider automatically regulates the gain.

After the suppression of the interference pulses SP in stage 18, one of is in the final stage 17 Interference pulses are largely cleaned and formed by a characteristic double pulse Measuring pulse MP available, which has a steep rising edge, which in consequently used to trigger the flash (test light pulse) of test light source 3 becomes.

Since it cannot be ruled out that the output signal of the output stage 18 always is still contaminated by interference pulses, a further smoothing takes place in the active time window 19 and attenuation of any disturbances that may still be present, thereby reducing the measuring pulse MP receives the sawtooth-like shape shown. The flash then fires when the measuring pulse MP exceeds a certain threshold. To prevent, the threshold value may trigger that the flash is triggered by an interference pulse that is still present not be too small; on the other hand, it must not be too big for it to be too weaker light pulses of the measurement light source correspond to smaller measurement pulses can be triggered. According to the illustration, the one named and designated SW Threshold value in the differential evaluation stage 20 placed in the middle of the rising edge.

When the threshold value SW is exceeded by the rising edge of the measuring pulse MP a pulse for triggering the test light source (flash lamp) 3 is generated in stage 21. This pulse has the rectangular shape shown and it preferably lasts somewhat longer than the measuring pulse MP, for example about 170 µs.

The lightning interference suppression, which suppresses the disturbing influence of the lightning the test light source 3 is used to control the gain because this is for a short time after the flash trigger does not work as desired, it is that the in the Level 18 included amplifier is locked for the duration of the flash.

Claims (11)

Device for checking the function of stray light smoke detectors (M), which a measuring chamber (5) with a measuring light source (6) emitting light pulses and have a measuring light receiver (7), with one open on one side and open the detector (M) to be tested, which can be attached or pushed over this adapter (1), which is a test light source which can be actuated synchronously with the light pulses of the measurement light source (3) for loading the measuring light receiver (7) with test light pulses contains, characterized in that the adapter (1) one to the by the Current pulses of the measuring light source (6) generated electromagnetic field responsive and the detector (2) controlling the test light source (3). Device according to claim 1, characterized in that means (8) for reflection the test light pulses are provided in the measuring chamber (5). Device according to claim 1, characterized in that said detector is formed by an induction coil (2). Apparatus according to claim 2, characterized in that said means for Reflection of the test light pulses by one arranged on the inside of the adapter (1) reflective coating (8) are formed. Device according to claim 3, characterized in that the adapter (1) is a rotationally symmetrical, has a can or can-like shape, and that the induction coil (2) is arranged on the inside of the adapter (1). Apparatus according to claim 5, characterized in that the induction coil (2) near the edge on the open side of the adapter (1) or on the open side Side opposite floor is arranged. Device according to claims 4 and 5, characterized in that the test light source (3) near the edge on the open side of the adapter (1) and the reflective coating (8) through an edge adjacent to said edge, strip-shaped area is formed. Apparatus according to claim 6, characterized in that the induction coil (2) containing the bottom part of the adapter (1) is covered by a film (10). Device according to claim 1, characterized in that the test light source (3) is formed by a flash lamp. Device according to one of claims 3 to 9, characterized by an electronic Circuit (4) for synchronizing the triggering of the test light pulses with the Light pulses from the measuring light source (6), which circuit (4) has a stage (18) for fading out of interference pulses (SP) from the signal supplied by the induction coil (2) which has an amplifier, a voltage divider and an electronic contains adjustable resistance, being by the adjustable resistance such a shift in the operating point of the amplifier takes place automatically, that the interference pulses (SP) and those caused by the pulses of the measuring light source (6) Measuring pulses (MP) lie on different sides of the zero line. Apparatus according to claim 10, characterized in that during the duration each test light pulse blocks the amplifier of stage (18) for masking of interference pulses.

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