DE2048817A1 - Method and device for indicating smoke, gas or rapid temperature rise - Google Patents

Description

Eaton YaIe & Towne Inc., 100, Erieview Plaza, öleveland, Ohio / USA

"Method and device for the display of smoke, gas or rapid Temperature rise "

The invention is directed to a method and devices for displaying smoke (yes or rapid temperature rise, basically of the type described in German patent application P 19 52 891.7.

As in this application; discussed, it concerns the known Smoke and fire indicators mostly around beam puff indicators, Plammenanaeiger or devices that respond to high temperatures.

Because of large amounts of dense smoke, flames or high temperatures only when a fire is in full swing is it obvious that these devices are not suited to a Indicate fire at the earliest possible, easily controllable condition and are therefore unsatisfactory.

Another known device type works with an electric one Field that is exposed to the ambient atmosphere and with a

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external ionization energy source in this field, usually by means of of a radioactive element. A flow of ions in this field generates a current that depends on the gas or Smoke fluctuates. However, this type of device has the disadvantage of having a radioactive element or other energy source the dangers involved and, furthermore, that, since the currents obtained are very small, very complicated ■ \ fe * stronger elements and circuits for measurement and comparison of the flowing current are required.

In the invention according to German patent application P 19 52 891.7, on the other hand, an electric field of such intensity and configuration is generated that a Townsend electron avalanche or a breakthrough occurs and, in addition, the field is of sufficient strength to pass a substantial number of ions To generate photo-ionization (corona) as well as photo-emission and supply of enough ions that the basic Townsend breakthrough remains self-sustaining and results in a steady flow of current. For the configuration shown there, this current flow is in the order of magnitude of P microamps and thus by a factor of 1 (K - 10 greater than in the prior art discussed above. The presence of smoke particles or typical gaseous combustion products such as CO and CO ₂ , affects the current flow and changes in the current flow provide an indication of their presence.

In addition, it was found that there was a considerable rise in temperature supports the breakthrough process as a localized waste the atmospheric density occurs, creating a greater

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Mobility of the ions and thereby an increase in the flow of current is made possible which in turn provides an additional indication of the occurrence of a fire.

However, the invention according to patent application P 19 52 8917 suffers, though satisfactory in most relationships, up to one to a certain extent under a build-up of dust on the wire electrode and the resultant reduction in the current and is furthermore wrong solutions due to sensitivity to ambient temperature fluctuations subject.

The object of the invention is therefore to create a solution for elimination electrostatic dust deposit in the above-described breath and gas display device. Furthermore, a wrong Triggering of the device as a result of fluctuations in ambient temperature can be avoided.

According to the invention, this is done by periodically generating the electric field instead of generating a continuous one Maintained electric field achieved. The current flow in this field is compared either with that in a second, field shielded against external influences or with an earlier current flow in the same field, in order to avoid such a false tripping as a result normal ambient temperature fluctuations as little as possible to keep. In addition, there are increases in the current flow compared to that in the comparison field as a result of a rapid increase in temperature used to indicate a fire condition.

Further features and details of the invention are set out below

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For example, explained in more detail with reference to the drawing. This shows in:

Fig. 1 is a block diagram of an embodiment of the invention and in

Figure 2 is a block diagram of another embodiment of the invention.

In the embodiment of FIG. 1, there is a double tube arrangement ■ shown, which has an input voltage source, its output is controlled by a pulse circuit which periodically feeds the voltage source in and out of the remainder of the circuit switches. This circuit, of which numerous types are well known, provides a pulse delivery which is specific to this particular implementation is on the order of 30 milliseconds in duration every 10 seconds. This pulse is regulated by a voltage regulator, to minimize the effects of voltage changes to maintain and to create a constant voltage during the duration of the fc periodic pulses, due to changes in voltage during the pulse to changes in current flow and possible wrong ones Would lead to trips.

This regulated charge is then applied to a high voltage source, which can be of any type to produce a positive polarity output voltage on the order of 3500 volts. This voltage is chosen to cause the Townsend breakdown for the particular geometry of the display tubes.

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This voltage is then applied to the display tubes 12, 14 via center electrodes 16 and 18 applied. In this embodiment, these electrodes consist of a 0.0077 cm (0.003 ") tungsten wire« while the tubes are approximately 14 cm (5 1/2 ") long and 0.77 cm (0.302 ") inside diameter, each tube having slots 20, 22 to allow entry of the Ambient atmosphere is provided in the tubes.

The positive polarity of the center electrodes 16, 18 creates a positive corona since these are the high intensity electrodes. It has been found that this type of arrangement is far superior to that which produces a negative corona, since the ionization process is better supported by the movement of the relatively low mass electrons than by the large ones Positive ions having bulk. As a result, lower voltages are possible around the self-sustaining Townsend breakthrough and the system is much less sensitive to changes in humidity and the like.

The display tube 14 is partially exposed to the surrounding atmosphere sealed by a shield cover 24. This wrapping is designed so that slow temperature changes of the surrounding Atmosphere within the envelope can be perceived, while rapid temperature rises, as well as smoky and gaseous ones Combustion products are at least temporarily prevented from to influence the air located within the tube 14 in order to enable a comparison, as described in more detail below is.

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The display tubes 12 and 14 are so with the control circuit connected that from the breakthrough effect that between the Center electrodes 16, 18 and their associated tubes 12, 14 generated, current pulse originating through a pulse forming Network can be directed to any RC-Sehaltkreis, such as may be indicated to generate pulses that are free from noise interference ("hash") and fleeting effects, so that they are reliable Indication of temperature changes and the presence of Smoke and that will be preserved. In addition, a potentiometer can be switched on to reduce the flow of current through the tubes "Not to equalize fire conditions, as changes result from normal Manufacturing tolerances, surface finish and the like can occur.

Corresponding voltages are then generated for each of the flowing currents applied to a differential amplifier 26 which generates a voltage signal corresponding to the difference between these voltages.

fc The output voltage of this element 26 is then applied to a pair of comparators 28, 30 which generate an output signal when the output voltage of the amplifier ^{indicates a predetermined current flow difference between the tubes 12, I 1} *.

This predetermined difference is determined by applying a comparison voltage on each comparator, one for a voltage difference that allows for a greater flow of current in tube 12 than in the tube corresponds to 1 * »and a higher outside temperature

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of the atmosphere in the tube 12 than in the tube 14, and another for a voltage difference which is a smaller one Current flow in the tube 12 than in the tube 14 corresponds and the Indicates the presence of smoke or gaseous products of combustion in the tube 12.

This predetermined difference should be adjusted to some To enable changes as a result of local effects, but reliably triggers if a condition indicating a fire is present is. For the given tube geometry and the applied voltages, it has been shown that a current flow difference of plus or minus 10 microamps is a satisfactory amount to produce a discharge signal indicative of a fire condition indicates. This would give the voltage levels that are generated by the differential amplifier in accordance with this current flow difference, the displayed signal state.

The output signal can then be fed to a relay drive which amplifies the signal stream before it is applied to a relay. The relay is used to operate an indicator, such as an alarm, or to operate Fire control devices. Alternatively, the signal could of course also be fed to a highly sensitive relay to make an amplification of the signal unnecessary.

During operation, the pulse circuit periodically brings a pulse closer positive voltage on the display tubes 12, 14, which for the given geometry at atmospheric pressure and normal

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temperature is sufficient to produce a Townsend breakthrough, and also sufficient incidence of photo-ionization and photo emission via the positive corona generated, so that this breakthrough remains self-sustaining.

If the smoke and gaseous products of combustion are not present in the tube 12 and the temperatures of the atmosphere in the tubes 12 and Ik are substantially the same, the current flow in both tubes will also be substantially the same and no output signal from the differential amplifier 26 will be given.

On the other hand, if there is smoke or gas in the tube 12 or there is a substantial temperature difference, then there will be a Current difference generated as explained above and an output signal output from the differential amplifier 26, if this is greater than the applied equivalent voltages, the relay is actuated and the fire control or alarm device is in operation puts.

It has been found that the tube geometry and the applied voltage are critical for successful operation of the pulse generation are. Although a full explanation of the exact process of the self-sustaining Townsend breakthrough to date is not available, it is known that when an electric field of sufficient volume and intensity is generated, there may be an occasional delay in the generation of the breakthrough. This delay is considered by the rest of the circuit a current difference read or perceived, which consequently leads to

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false trips.

This occasional delay is believed to be the result the need for a free electron to be present in the field at a point sufficiently far from the collector electrode is to achieve sufficient kinetic energy to ionize molecules against which it collides before it reaches the collector electrode. The number of free electrons created by cosmic rays and background rays and are present in the field at the beginning of a pulse is essentially a function of the volume of the field and the probability that an electron is present at one point at which a breakthrough is produced is a function of the field intensity, from which it can be seen that the length of the Tube and the applied voltage can be adjusted until the likelihood of delaying the onset of the Breakthrough is reduced to an insignificant height, which for the special dimensions and tensions of the above Embodiment is applicable.

Another embodiment of the invention is schematically represented in Fig. 2, in this embodiment, currents generated are applied at different times to a single display tube 12 of Spannungsimpulaen compared and existing differences are previously bescnricoenen for dissolving the display device in a similar manner as in the · k used as a guide. Since the distance between the pulses is of relatively short duration (approximately 20 ίίβκ.), Produce small changes

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the external temperature conditions, such as those caused by normal temperature fluctuations, no significant Stromdiffer.enzen, which eliminates a cause of false triggering, and also the advantage of the electrical pulse field is given to eliminate or avoid electrostatic coatings on the electrodes of the display device.

This arrangement has an input voltage source, a pulse circuit, a voltage regulator and a display tube on similarities _k borrowed as in the previously described embodiment. The pulse circuit, however, switches on a monostable and a bistable multivibrator with the first pulse, which then generate a signal via an AND gate # 1 in order to switch on an analog gate # 1 and match that via the tube 12 and a pulse-generating network similar to that in FIG of the embodiment described above. Impulse to enable a hold circuit to arrive.

The next pulse then switches off the bistable multivibrator, switches on the monostable multivibrator, which causes a signal from the ψ AND gate Afc-2 and thus in turn the switching on of analog gates H 2 and H 3. This enables the pulse to be transmitted from the at the same time Display tube 12 and the pulse from the holding circuit to the differential amplifier 2b which produces an amplified output corresponding to the difference between the pulses.

The output of the amplifier 26 is then compared to the comparisons! 2υ and j> 0 , which generate an output signal to actuate a In Kelais when the voltage difference is that of the comparison

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voltage exceeds which in a manner similar to that of the previous one described embodiment are set to a dispensing · to generate a signal if there is a voltage difference of such magnitude that indicates the presence of a breath or gas, or if there is a rapid rise in ambient temperature indicating a fire entry.

The next impulse then starts the process described above again.

It follows from the description above that a Display for smoky and gaseous combustion products or others rapid temperature rises is proposed, which is simple and reliable and generates a strong output signal and thus Elaborate amplifier components and circuits are unnecessary, no radioactive materials or other external ionization energy sources is required and is relatively unaffected by electrostatic dust deposition and, in particular, is not false trips as a result of normal external temperature fluctuations is subject.

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Claims (1)

Claim ^ 1. / Method of indicating an abnormal condition, such as presence of smoke, gaseous combustion products or a rise in temperature in the surrounding atmosphere, dadurph characterized in that a first electric field is periodically generated in which a self-sustaining Townsend electrode avalanche current flows, and that the magnitude of the current flow is compared with a comparison current, which would occur in the absence of an abnormal condition, wofc by an indication of the presence of such smoke, gas or atmospheric temperature rise. 2. The method according to claim 1, characterized in that the comparison is the periodic generation of an electrical comparison field in which a sustained Townsend electrode avalanche current occurs and that of an abnormal state is free. 3. The method according to claim 2, characterized in that the w Comparison includes the shielding of the electrical comparison field against the entry of smoke, gas or the surrounding atmosphere of high temperature. k. A method according to claim 2, characterized in that the comparing includes generating the comparative electric field at an earlier point in time than the first electric field at the same point in space, whereby the 109819/1129 subsequent occurrence of smoke, gas and temperature rise the ambient atmosphere is displayed. 5. Apparatus for performing the method according to claim 1 or one of the following, characterized by electrical Field means for the periodic generation of a first electric field in the atmosphere, in which a self-sustaining Townsend electrode avalanche current flows, and through comparison means which generate a signal when the current flows from the one deviates which would occur in the absence of the abnormal condition. 6. Apparatus according to claim 5, characterized in that the Comparison means have means for periodically generating a second electrical comparison field and furthermore means, which compare the current flows in the first and second electric fields with one another. 7. Apparatus according to claim 6, characterized in that the comparison means have shielding means which move of the atmosphere in the second electric field in order to produce a comparison current in the second electric field in which gradual changes in the ambient atmosphere are taken into account. ti. Device according to claim 6, characterized in that the means for generating the second electric field at the same point hardly, but at one of the 109819/1129 WDOHQHM. enclose the first electric field at different tent points, causing the ingress of breath, gas or ambient atmosphere high temperature is displayed in the intervening interval. 9. Apparatus according to claim 5 or one of the following, characterized characterized in that the electrical field means comprises a pair of electrodes and means for applying an im essentially the same voltage on these electrodes. 10. Apparatus according to claim 9> characterized in that the Electrodes are shaped such that one electrode in their vicinity has a higher field strength than the other and that the Voltage means apply a voltage of positive polarity to this one electrode in such a way that a positive corona is produced. 11. The device according to claim 5 or one of the following, characterized by means for measuring the temperature at a specific point at time intervals, means for comparing of two such measurements and means for generating an output signal as a function of the occurrence of a predetermined one Measurement difference, whereby an output signal is generated as a function of a predetermined temperature rise. 109819/1129 Blank page