EP0019310A1 - Fire indicator with a temperature-sensitive element - Google Patents

Abstract

In the case of a fire detector, a temperature-sensitive element made of a shape memory alloy (8, 15, 24, 39, 40, 52) is provided, which returns to the originally impressed shape after a cold deformation when heated to a critical temperature, for example at about 70 ° C, and maintains this shape even after subsequent cooling. The movement of this element triggers a self-holding alarm signal directly, by closing contacts, or indirectly. The fire detector can be reset by cold mechanical deformation of the element or, if two-way shape memory alloys are used, by cooling to a lower temperature threshold, which can be below room temperature. An expedient further development results from combination with a different type of fire sensor element, for example by attaching a shape memory alloy element in a scattered radiation smoke detector, the element swiveling into the radiation area when the critical temperature is reached, or in an ionization smoke detector, the element shading the radioactive radiation source and reduces the ion current. Suitable shape memory alloys are nickel 55 / titanium 45 or nickel 45 / titanium 45 / copper 10.

Description

The invention relates to a fire detector with a temperature-sensitive element, which triggers an alarm signal if its predetermined critical temperature is exceeded.

Known fire detector which ^{g is} the Exceeding a certain air temperature, which, for example, between 50 ° C and 100 ° C, may be in the vicinity of 70 ° C, preferably, utilize for alarm signaling, contain various temperature-sensitive elements which change their form at a temperature increase. DE-PS 159 519 uses the length or volume expansion of contact thermometers or the deflection of bimetallic elements, which are composed of two layers of different thermal length expansion. From US 3 122 728 it is known to use the deflection of the wall of a chamber, in which a gas or air is enclosed, as a result of the pressure increase when the temperature rises. In these cases, the alarm signal is given either directly by the fact that a contact is closed by the mechanical movement of the temperature-sensitive element or indirectly by electromagnetic or optical transmission. The alarm signal can be generated on or in the fire detector itself and consist of a visual or acoustic signal, or it can be an electrical signal, for example a change in current or voltage, which is forwarded to a signaling center via connecting lines.

Disadvantages of such known fire detectors are that the change in shape of the temperature-sensitive element is reversible, and therefore a triggered alarm signal is not self-sustaining, i.e. that an alarm signal is automatically reset as soon as the temperature falls below the critical value, so that it can no longer be recognized which fire detector has responded. Furthermore, when the critical value is approached, in particular with temperature fluctuations or under vibrations, flutter phenomena occur, i.e. there is no reliable contact. The result is rapid wear and scaling of the contacts, apart from the unsafe signal triggering. The types of fire detectors mentioned therefore do not have the required operational reliability. In addition, the deflection is only relatively slight in the vicinity of the critical temperature and takes place only with little force. For these reasons, exact adjustment of such fire detectors to the desired critical temperature is required. Since the setting in particular does not have good long-term stability, frequent readjustments are necessary to ensure safe operation.

Attempts have already been made to avoid some of these disadvantages by using temperature-sensitive elements which do not show a mechanical change in shape but rather change their electrical properties, for example fire detectors are known which act as sensors elements, temperature sensitive resistors or other temperature-sensitive components integrated included, wherein the _A enderung the electrical properties, for example, is utilized in the resistance with an electronic evaluation circuit for alarm signaling. This circuit can be designed such that it also only uses electrical switching elements to trigger this signal, for example thyristors or electronic switches. In this way, reliable alarm signaling can be achieved at a predetermined temperature, specifically in a manner that the alarm signal is not automatically reset when the temperature drops. However, it is disadvantageous that such fire detectors with exclusively electrical components always have a noticeable quiescent current even below the critical temperature. Such fire detectors are therefore not suitable for extensive fire alarm systems in which a large number of fire detectors are to be connected in parallel to the same lines, since in this case the sum of the quiescent currents can reach the magnitude of the alarm current of a single detector with just a few fire detectors and an alarm signal can no longer be safely distinguished from the quiescent currents of all detectors.

The invention has for its object to eliminate the disadvantages of known thermal fire detectors and in particular to provide a fire detector that can easily trigger a self-holding alarm signal without using a large number of components, which is not automatically reset when the temperature drops. Such a detector should work reliably and trouble-free over long periods of time, show no signs of wear, require no frequent maintenance or adjustment, and maintain a critical temperature once selected.

According to the invention, this object is achieved in that the temperature-sensitive element has a shape memory alloy which returns to its impressed shape when the critical temperature is exceeded.

Shape memory alloys, also as "shape memory alloys", e.g. in US 3 174 851, 3 403 238, DE 1 288 363, 1 588 715, or in the Journal of Applied Physics 36, p.3232 ... (1965), have the property that they are used in the manufacture save selected geometric shape at elevated temperature. After the element has cooled below a critical temperature given by the material, the element can now be mechanically deformed. If the temperature is now raised again to the critical temperature, the material again assumes the original shape, irrespective of the way in which it was previously cold-formed. Up to a certain deformation, the change in shape can be freely selected.

In the publications of WJBuehler, WBCross, "Wire Journal", June 1969, p. 41-49, and by KN Melton, O. Mercier, in the journal "Material und Technik", Volume 6 (1978), No. 2, pages 59-66, the properties of such shape memory alloys are compiled, and the composition of suitable shape memory alloys is given . As a rule, these are metals that show a martensite transformation. Nickel / titanium alloys, also known as nitinol, or alloys of copper, zinc and aluminum have proven to be particularly suitable. Nickel / titanium alloys with addition of other alloy elements have proven to be particularly suitable for use in fire detectors mainly from copper meadows, e.g. for a critical temperature of 70 ° C the alloys Ni55 / Ti45 or Ni45 / Ti45 / CulO.

Shape memory alloys that work according to the one-way principle have proven to be practical for most applications in fire detection technology. The sensor element deforms back into its original shape when the critical temperature is reached. This shape remains intact and triggers a self-holding alarm signal, which can only be canceled by mechanical reshaping of the sensor element. However, shape memory alloys that work according to the two-way principle have also proven to be useful for special applications. These alloys have the property that they do not return to their original shape after cold working when heated to the critical temperature. If the temperature drops again, the shape changes again in the sense of cold deformation when another lower threshold is reached. A fire detector with such a sensor element can therefore be reset by cooling to a lower threshold temperature after it has responded when the upper critical temperature has been reached. Such hysteresis-like behavior is desirable if fire detectors with two different threshold values are desired. It is advisable to choose the lower threshold between the room temperature and the upper critical temperature. However, it can also be advantageous to choose the lower threshold below room temperature. Such a fire detector has the property that it can be reset after cooling once below the lower threshold without mechanical action being required. This resetting can be achieved, for example, by a spray that is used in the De tector is sprayed and due to the evaporative cooling causes a cooling below room temperature.

The invention and further refinements and advantages thereof are described on the basis of the exemplary embodiments illustrated in the figures.

• Figure 1 shows a thermal fire detector with direct contact.
• Figure 2 shows a thermal fire detector with indirect contact.
• Figure 3 shows a thermal fire detector with magnetic contact.
• Figure 4 shows an optical smoke detector with additional thermal triggering.
• Figure 5 shows an ionization smoke detector with additional thermal triggering.
• Figure 6 shows an autonomous thermal fire detector.

In the fire detector shown in section in FIG. 1, a housing 2 is placed on a base plate 1, which has large openings 3 and 4 in the lower part for air to enter the interior of the housing. In the housing 2, a mounting plate 5 is provided, which carries two electrical connections 6 and 7, of which electrical lines, possibly via a base, lead to a signal device, not shown. At the lower end of a connector 6, a strip 8 of a shape memory alloy is attached so that its other end is close to the formed as a counter contact 9 lower end of the other terminal 7. The strip dimensions are not critical and can be, for example, 0.5 x 3 x 35 mm. The strip 8 is made from one of the shape memory alloys mentioned above, preferably from a titanium / nickel alloy with added copper. The alloy composition was chosen so that its critical temperature corresponds to the desired response temperature of the fire detector. This may for example be between 50 ⁰ C and 100 ⁰ C, preferably at 70 C. During the manufacture of the strip 8 at elevated temperature has been so formed that it initially has an elongated shape. When installed in the fire detector, it short-circuits connections 6 and 7 in this form. To operate the detector; to make ready, the strip 8 is deformed in the cold state to such an extent that it lifts off the counter-contact 9. Depending on the alloy composition, the change in shape can be up to 8% g if a one-way shape memory effect is desired, or 2% if the hysteresis or the two-way effect is used. As soon as the room temperature rises due to an outbreak of fire and hot air penetrates into the interior of the fire detector, strip 8 heats up. In contrast to bimetal elements, strip 8 does not bend at first. Only when the predetermined critical temperature is exceeded, for example when 70 ° C. is reached, does a relatively rapid change in shape take place, in which the strip 8 again assumes the original elongated shape and touches the mating contact 9. An alarm signal is then triggered via the lines attached to the connections 6 and 7. As a result of the self-heating of the strip 8 by the current flowing through it, contacting is particularly reliable.

The advantage here is that the contact and alarm signal release takes place relatively quickly in a narrow temperature range. What occurs with previously known fire detectors Flutter caused by unsafe contact is avoided. In addition, the force exerted on the contacts is considerably greater than with detectors with other temperature-sensitive, mechanically movable elements. It is also advantageous that, in the event of a subsequent drop in temperature, the strip 8 retains its shape and does not rise again from the mating contact 9. The alarm signal emitted by the detector is therefore self-holding. The detector can only be reset by deforming the strip 8 again in the cooled state. This reset can be done mechanically by hand when using a shape memory alloy that works according to the one-way shape memory effect. However, it can also be expedient to use an alloy which works according to the two-way shape memory effect, which therefore partially deforms again when the temperature drops below a lower lower threshold, so that the strip 8 lifts again from the contact 9. This lower lower threshold can be selected so that it is above room temperature, so that such a detector automatically resets when the air temperature drops. Instead, the alloy can also be chosen so that the lower temperature threshold is below room temperature. Such a detector does not automatically reset itself, but it can be reset by means of heat-extracting means, for example by cooling with a suitable spray which is sprayed into the interior of the housing.

FIG. 2 shows a further example of a thermal fire detector with a base plate 11 and a housing 12 placed thereon and having air inlet openings, in which in turn a mounting plate 13 is provided. On this in turn, a strip, wire or pin 15 of a suitable shape is on a fastening part 14 memory alloy attached. Whose free end is connected via a coil spring 16 to an opposite Befes- ^g tigun sstift 17 is connected so that the system element 15 and coil spring 16 has only two stable positions, ie, a snap effect shows.

The element 15 is in turn deformed so that it is stretched in the initial state, i.e. in the upper stable position. During cold forming, it is now deformed so far that it assumes the other, lower, stable position. When the temperature rises and the critical temperature is reached, the element suddenly snaps back, a pin 8 attached to the element 15 pressing on a pressure-sensitive switching element 19. This pressure-sensitive element 19 can be, for example, a microswitch, a pressure-sensitive elastomer or an optical fiber, the transmission properties of which change when pressure is applied. An alarm signal can in turn be triggered via the two electrical connections of the pressure-sensitive switching element 19. A particular advantage of this version is the avoidance of open contacts and thus the safer contact with an additional increased switching force.

In the fire detector shown in Figure 3, which in turn has a housing 22 fastened to the base plate 21 with a carrier plate 23, the temperature-sensitive element made of a shape memory alloy is designed as a coil spring 24, one end 25 of which is fastened to the underside of the housing, while the other End 26 is fixedly connected to a movable plunger 27 which extends through a central opening of the mounting plate 23 and the underside of the housing. In one example, a spring with 5th turns was made 1 mm thick Ni55 / Ti45 wire with 16 mm diameter is used. A magnetically actuatable switching element 28 is attached to the base plate 23 in the vicinity of the movable plunger 27. This can be implemented, for example, as a protective gas contact switch, also known as a reed relay, or as a semiconductor magnetic probe, also known as a Hall switch. A permanent magnet 29 is attached to the upper side of the movable plunger 27 and can be designed, for example, as an AlNiCo magnet or as a SmCo magnet. At the lower end of the stamp 27 there is an annular marking 30 made of a signal color, for example red.

The temperature-sensitive coil spring 24 is now designed such that it presses the punch 27 upward after the cold deformation. The permanent magnet 29 is selected and attached in relation to the magnetically actuable switch 28 such that the magnetic field in this position of the plunger 27 is not sufficient to close the contact 28. If the air temperature and thus the temperature of the coil spring 24 now reaches the critical temperature, the coil spring 24 again assumes the original shape before the cold deformation, ie it contracts and pulls the punch 27 downward. As a result, the switch 28 comes under the influence of the permanent magnet 29 and its contacts close, so that an alarm signal is triggered via the lines connected to the connections of the switch 28. A magnetic snap effect can be achieved by soft iron parts attached in parallel. At the same time, the lower end 30 of the stamp 27, identified by a signal color, emerges from the central housing opening and in this way indicates that the fire detector has responded. After cooling, the stamp 27 can be pushed back into the housing by hand, where the coil spring 24 is again cold formed. The _B edge detector is now ready for use again.

The Aasführungbeispiel described has the advantage that there are no openly accessible contacts that can become dirty over time or scale when actuated. A fire detector of this type equipped with a magnetically actuated switch, especially a reed relay, thus operates more reliably than known thermal fire detectors over longer periods even when operated several times. In addition, it has the advantages that, despite the simplest design, it displays a self-holding alarm signal both on the fire detector itself and via cables at a remote location, with no current flowing when not addressed. Such detectors can therefore be connected in large numbers in parallel, also combined with hand alarm buttons or other fire detectors, which also do not cause quiescent current.

In the examples described so far, the alarm signal is given by closing contacts as a result of the movement of the element consisting of a shape memory alloy in a direct or indirect manner. However, it is often necessary to use fire phenomena other than air temperature, such as the occurrence of smoke or fire aerosol, to give an alarm signal. In such cases, it is advisable to combine the temperature-sensitive element consisting of a shape memory alloy with a different type of fire sensor that reacts to another fire phenomenon. It is imperative to use a common switching element both for the temperature-sensitive element and for the other sensor element. One obtains particularly simple and reliable constructions by the fact that the temperature sensitive Ele ment is designed and arranged in such a way that when it deforms back when the critical temperature is reached, it has the same effect as the other fire sensor.

FIG. 4 shows an optical smoke detector of this type. A housing 32, which has air inlet openings 33 and in which a cup-shaped support part 34 is located, is in turn attached to a base plate 31. In the upper central part of the carrier part 34 there is a radiation source 35 which, by means of an associated optical system, generates a cone-shaped radiation region 36, as described, for example, in Swiss Patent No. 592 932. In the lower part of the housing there is a shielding part 37 which shields the interior of the housing against direct light, but allows air to enter in a tortuous way. In the central part of the shielding part 37 there is a photoelectric radiation receiver 38, which is normally outside the conical radiation area 6. However, if smoke-containing air enters the interior of the housing, radiation is scattered on the smoke particles located in the radiation region 36, and the radiation receiver 38 is struck by scattered radiation. As soon as the intensity of this scattered radiation exceeds a certain predetermined value, an alarm signal is triggered by a circuit, not shown. In addition to these features already known in the case of optical scattered radiation smoke detectors, a temperature-sensitive element 39 made of a suitable shape-memory alloy is provided on the cup-shaped support part 34 inside the housing. This temperature-sensitive element 39 is designed and attached with respect to the radiation region 36 in such a way that in the cold-formed state it lies completely outside of this region, that is to say from the direct radiation of the radiation source 35 is not hit. If the temperature now rises above the critical temperature of the shape memory alloy used, the element 39 takes on the originally impressed shape again and moves with its free end into the radiation region 36. The direct radiation from the radiation source 35 thus striking the free end of the element 39 is reflected and scattered, and part of this radiation strikes the radiation receiver 38. This is influenced in a manner similar to that caused by the scattered radiation emitted by smoke particles in the radiation region 36 . If the selected critical temperature is exceeded, the change in shape of the temperature-sensitive element triggers an alarm signal in the same way as if smoke particles producing scattered radiation were present in the radiation area.

Instead of a scattered-light smoke detector, the concept of the invention can also be used in a radiation extinction detector in which the radiation attenuation by smoke in a measuring section is used for alarm signaling. In this case, the element is formed from a shape memory alloy in such a way that it swivels into the measuring section when the critical temperature is reached and likewise causes radiation to be weakened.

FIGS. 5a and 5b show an ionization smoke detector with a base plate 41, on the underside of which an ionization measuring chamber 42 is attached, and the top of which carries a reference ionization chamber 43. In the center of the base plate 41, a center electrode 44 and 45 for the ionization measuring chamber 42 and the reference chamber 43 is attached on both sides. The center electrodes 44 and 45 each carry a radioactive preparation 46 and 47, through which the air in the two chambers is ionized. The grid-shaped housing 48 of the ionization measuring chamber 42 and the air-impermeable housing 49 of the reference chamber 43 serve as counter electrodes of the two chambers 42 and 43. Corresponding designs and evaluation circuits of such ionization smoke detectors are known, for example, from Swiss Patents No. 486 082 and 489 070.

The functors of such ionization smoke detectors are based on the fact that smoke particles or fire aerosol, which has penetrated into the ionization measuring chamber 42, reduce the ion current flowing between the center electrode 44 and the housing wall 48 serving as counter electrode. This current reduction is over. an associated evaluation circuit used in a known manner to trigger an alarm signal.

In addition, the ionization smoke detector shown in FIGS. 5a and 5b contains a temperature-sensitive element 40 made of a shape memory alloy, one end of which is attached to the base plate 41. The temperature-sensitive element 40 is attached in such a way that it does not, or only slightly, influences the radioactive radiation emanating from the radiation source 46 in the cold-deformed state. However, if the critical temperature of the shape memory alloy used is exceeded, the free end of the temperature-sensitive element moves into the originally embossed position. A flag 50 attached to this free end is moved over the radioactive source 46 and largely shields its radioactive radiation. The result is a reduction in the ion current between the center electrode 44 and the one designed as a housing wall Counter electrode 48, in the same way as if smoke or fire aerosol had penetrated into the interior of the ionization measuring chamber 42. If the critical temperature is exceeded, an alarm signal is therefore also triggered via the same evaluation circuit.

A modification which differs only slightly from this embodiment uses the temperature-sensitive element 40 as a carrier of a portable electrode in order to influence the electric field directly, independent of the radiation source 46, in such a way that the desired current change occurs.

In the case of the fire detectors shown in FIGS. 4, 5a and 5b, a fire alarm signal can therefore be triggered in a simple and safe manner without the use of an additional evaluation circuit if different types of fire phenomena occur.

Figure 6 shows an autonomous fire detector with its own power supply, which does not have to be connected to a signaling center via lines. Such fire detectors are used, for example, as home detectors to protect a single object. The fire detector shown works according to the well-known principle of the electric bell with a Wagner hammer. In this case, a rigid account carrier 52 and an elastic, vibratable contact carrier 53 are fastened on one side clamped on a carrier plate 51. The free ends each have a contact 54 and 55. The fixed ends of the two contact carriers 52 and 53 are connected to one another via a battery 56 and an electromagnet coil 57. The elastic contact carrier 53 is arranged so that it is attracted to the electromagnet 57 as soon as a current through it Coil flows. A clapper 58 provided at the free end of the elastic contact carrier 53 strikes a bell 59.

According to the invention, the rigid contact carrier 52 is produced from a suitable shape memory alloy and is attached and cold-worked in such a way that the two contacts 54 and 55 do not touch at room temperature. However, if the temperature rises to the critical temperature when a fire breaks out, the rigid contact carrier 52 deforms until the two contacts 54 and 55 touch and a current flows through the electromagnetic coil 57. As a result, the elastic contact carrier 53 is attracted by the electromagnet 57, the clapper 58 strikes against the bell 59 and the contacts 54 and 55 open again, whereby the current is interrupted, the elastic contact carrier 53 springs back until the contacts 54 and 55 touch again. The process described is then repeated periodically. The bell can only be switched off by reshaping the rigid contact carrier 52 in the cold state. The degree of shape change is in no way critical, i.e. the fire detector works reliably over long periods without the need for precise readjustment.

It should be noted that the invention is not limited to the described embodiments of using a temperature-sensitive element made of a shape memory alloy in a fire detector with a further fire sensor element. The idea of the invention can also be realized in connection with other fire protection devices in which a signal can be triggered indirectly when an element made from a shape memory alloy is deformed. The example is the possible Mention mentioned indirectly trigger an alarm signal by the temperature-sensitive element first actuates a fire control system when the critical temperature is exceeded, for example, opens an emergency exit door or smoke flaps, or closes a fire door, which then closes or opens contacts for alarm signaling.

The use of a temperature-sensitive element made of a shape memory alloy in a fire detector therefore has the advantage that safe, self-locking alarm signaling can be achieved with a minimal effort when a critical temperature is reached, without the need for components with narrow tolerances and precise adjustment. A fire detector designed in this way thus has increased functional reliability over longer operating times and reduced susceptibility to faults.

Claims (15)

1. Fire detector with a temperature-sensitive element which, when a predetermined critical temperature is exceeded, triggers an alarm signal due to its shape change, characterized in that the temperature-sensitive element (8, 18, 24, 39, 40, 52) has a shape memory alloy which, when the critical temperature returns to its embossed shape. 2. Fire detector according to claim l, characterized in that the shape memory alloy contains nickel and titanium. 3. Fire detector according to claim 2, characterized in that the shape memory alloy contains at least one further metal, preferably copper. 4. Fire detector according to claim 1, characterized in that the shape memory alloy has a critical temperature in the range between 50 ° and 100 ° C, preferably in the vicinity of 70 ° C. 5. Fire detector according to claim 1, characterized in that the shape memory alloy has a hysteresis behavior shows and because of the critical temperature at which it moves back in the direction of its embossed shape, it has a lower temperature threshold, whereby when it cools down to this, it in turn deforms in the direction of the change in shape. 6. Fire detector according to one of claims 1-5, characterized in that the temperature-sensitive element (8) is fixed on one side, while the other side is movable and touches a contact (9) in the event of reshaping. 7. Fire detector according to one of claims 1-5, characterized in that the temperature-sensitive element (15) presses upon reshaping on a pressure-sensitive switch (19) and actuates it. 8. Fire detector according to one of claims 1-5, characterized in that the temperature-sensitive element (15) is attached to one side (14), while the free end is held by means of a spring element (16) in such a way that it can assume two stable positions, the temperature-sensitive element (15) snapping over from the one stable position to the other when the critical temperature is exceeded. 9. Fire detector according to one of claims 1-5, characterized in that a magnetically actuated switch (28) is provided and that the temperature-sensitive element (24) is connected to a permanent magnet (29) which, when the critical temperature of the shape memory alloy is reached is moved that the magnetically actuated switch (28) is influenced. 10. Fire detector according to claim 1, characterized in that a radiation source (35) is provided, which emits radiation in a radiation area (36), and a radiation receiver (38), which is struck by scattered radiation in the radiation area (36), the temperature sensitive Element is attached in such a way that when it deforms back when the critical temperature is exceeded, it moves into the radiation region (36) and the radiation reflected and scattered on parts of the temperature-sensitive element hits the radiation receiver (3). 11. Fire detector according to claim 1, characterized in that a radiation source is provided, the radiation of which is fed to a radiation receiver and is weakened in the presence of smoke, the temperature-sensitive element being designed and attached such that it weakens the radiation conducted to the radiation receiver when it is deformed . 12. Fire detector according to claim 1, characterized in that an ionization chamber (42) with a radioactive preparation (46) is provided, which ionizes the space between two electrodes (44, 48), the temperature-sensitive element. 0) is designed and arranged in such a way that when the critical temperature is exceeded, the radiation from the radioactive radiation source (46) is at least partially shaded and the ion current between the electrodes (44, 48) is reduced. 13. Fire detector according to claim 1, characterized in that an ionization chamber with a radioactive preparation and two electrodes, between which an electric field prevails, is provided, the temperature-sensitive element being designed and attached such that an electrode changes its position when it is reshaped of the electric field. 14. _B edge detector according to claim 1, characterized in that the temperature-sensitive element is designed as a rigid contact carrier (52) of a Wagner hammer of an electric bell, the normally open contacts touching each other when the critical temperature is reached and the pressure circuit for actuating the bell periodically shut down. 15. Fire detector according to claim 1, characterized in that the temperature-sensitive element actuates a fire control when the critical temperature is reached, contacts for alarm signaling being closed or opened by this actuation.

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