DE2225708A1 - AUTOMATIC FIRE DETECTOR - Google Patents

Description

.26. May 1972

DIETRICH Lr 'm - 8KY Pati? iTAiiV / ALT Mönchen 21-GotthardstF. 81 Telephone 56 17 62

CERBERUS AG Männedorf

Automatic fire alarm

The invention relates to an automatic fire alarm with a device for detecting combustion gases.

209885/0796

Automatic fire alarms use either physical changes in the event of a fire, e.g. the increase in temperature or the radiation emitted by the flames to raise an alarm, or try to detect the products of combustion that arise in the event of a fire. So it is known, the resulting smoke to be detected by optical absorption or scattered light fire alarms or the fire aerosols by means of ionization fire alarms. Other known fire alarms use the changed conductivity of the fire gas (formation of ions) and the increased water vapor content for fire alarm.

However, the facilities mentioned are more or less disruptive, vulnerable or can be triggered by processes that have nothing to do with a fire, e.g. optical fire alarms Stray light, ionization fire alarms due to dust, conductivity detectors due to ionization of the air for other reasons. the

The consequence of this possibility of deception are false alarms from these known ones Devices.

It has now been suggested that this be the case with any unwanted or the intended combustion process to use carbon monoxide (CO) for fire alarms. Such The device would work particularly without any errors, since CO is practically exclusively the result of a combustion process occurs and is therefore an unmistakable sign of a fire. In addition, a warning against CO is due to whose toxicity is desirable anyway.

209885/0796

So far known CO detectors mostly work in a spectrophotometric way or by means of a chemical one Reaction and the detection of the secondary products. However, these methods are relatively cumbersome and the ones operated according to them Devices that cannot be used for long periods of time, as must be required by an automatic fire alarm. Furthermore such devices are relatively complex, expensive and require ongoing maintenance.

The aim of the invention is to eliminate the disadvantages mentioned and the creation of a fire alarm that works without deception over long periods of time with increased sensitivity.

The invention is characterized in that the device for detecting combustion gases is an electrolytic cell with a cathode, an anode accessible to the combustion gases and an electrolyte arranged between anode and cathode having, wherein the anode catalytically releases the carbon monoxide contained in the combustion gases with the release of electrons able to oxidize, as well as by an electrical circuit connected to the anode and the cathode for current detection and alarm.

The invention makes use of the experience known per se, using so-called fuel cells, flammable liquids or gases directly, i.e. without the interposition of heat engines, to convert it into electrical energy. In such fuel cells are generally organic substances such as formalin,

209885/0796. ,

Formic acid or hydrazine catalytically, for example at
a platinum anode, oxidized. Between this anode and one
Cathode creates a potential difference which leads to the
Energy generation can be used. It has already been proposed, conversely, to use the energy supply of such a fuel cell for analyzing the content of flammable substances in liquids and gases. However, the known fuel cells were completely unsuitable as fire alarms because of their complex construction and low selective sensitivity to carbon monoxide. For the further development of the invention it was therefore necessary to find new materials for the individual elements of the cell and the arrangement and structure
to be chosen so that the device has an optimal sensitivity to carbon monoxide with the least possible effort and the longest possible service life.

The invention is explained with the aid of exemplary embodiments. Show it:

Fig. 1 shows the functional diagram of a fire alarm with basic
Electrolytes,

2 shows the functional diagram of a fire alarm with acidic electrolyte,

3 shows the structure of the detection device of a fire alarm.

209885/0796

In the device according to FIG. 1, the surrounding air has access to an anode 1. Oxygen molecules are formed at the cathode 2 the air upon delivery of electrons from the electrical circuit 3 reactive oxygen ions, which reacts with the water of the basic electrolyte 4 to form hydroxyl ions realize. The cathode 2 thus serves as a hydroxyl ion supplier. These hydroxyl ions migrate to the anode 1 and react there in the presence of a catalyst (e.g. palladium) with the carbon monoxide contained in the air to form carbonic acid and water, whereby electrons are released »which in turn are transferred to the electrical circuit 3 are output. As long as there is carbon monoxide in the air, it is in this circuit a current is maintained, which is detected with the detector 5 and can be used in a known manner to trigger an alarm signal.

In the device shown in Fig. 2 with acidic, ie containing hydrogen ions, the electrolyte reacts at the Anode the CO contained in the air catalytically with the water contained in the electrolyte to form carbon dioxide and hydrogen ions giving off electrons, which fHessen in the electrical circuit 3 to the cathode. The hydrogen ions are from Acid electrolyte 4 and react at the cathode 2 with the diffused oxygen, absorbing electrons from the circuit to water.

Fig. 3 shows in section a practical embodiment of the invention. In one consisting of two parts 6 and 7

20988 & / 0796

The plastic housing is gas-permeable on the open side Membrane 8, e.g. a filter made of pressed glass wool or a glass frit or similar attached. On its outside there is a layer 9 made of nickel powder which is coated with a noble metal. As special The metals of the platinum group have proven suitable. Especially palladium shows a special ability to catalytic oxidation of the carbon monoxide reaching the membrane 8. The metal powder is with an ion exchanger and mixed with an additional binder, e.g. polystyrene, if necessary. Ion exchangers have a wide variety of compositions give favorable results. The known anion exchanger has proven to be particularly suitable III, which contains a copolymeric styrene divinylbenzene with quaternary ammonium groups. However that is The invention is in no way restricted to this, since other types of ion exchangers have also proven themselves.

At the bottom of the housing 6 there is an electrode 12, which is coated on the inside with a carbon layer, for example soot is, to which in turn a hydroxyl ion-releasing substance 11 is applied. One has proven to be particularly cheap polymeric phthalocyanine of the transition metals, e.g. of the iron group (Fe, Ni, Co), but also of Cu, Ag, Au and Hg.

A thin layer of felt 10 impregnated with an electrolyte is located between the plate-shaped electrodes. which is soaked with a potassium bicarbonate or cesium carbonate solution. Instead of felt, another one, the electrolyte, can be used

209885/0796

absorbent, but only slightly hindering diffusion Carrier material, as it is known from electrolytic dry elements, can be used. The layer thickness is only a few millimeters, usually less than 5 now. In such a plate-shaped electrode arrangement and such If the electrode spacing is small, the internal resistance of the electrolytic cell is relatively small and the diffusion within the Electrolytes fast enough so that the current yield is large enough to remove even the smallest amounts of combustion gas to be able to prove. In this case, the voltage of the element is usually below 0.1 V.

To reduce the rate of evaporation of the electrolyte, a certain amount of glycerine or something similar can be added Substance can be added. This can significantly improve the service life and usage time of the fire alarm.

Another way to reduce evaporation is to design the anode so that the outer side is one

Contains hydrophobic binder that prevents the electrolyte from escaping prevents, while the inside has a hydrophilic binder, which ensures the necessary wetting.

The sensitivity can be increased by the fact that

the rear wall 6 of the housing resting on the cathode 12 is aired

^ is made permeable. As a result, the oxygen in the air is released to get directly to the cathode without passing through the electrolyte having to diffuse, e.g. the cathode can be very finely divided silver, so-called Raney silver, welc he si is applied to an oxygen-permeable membrane.

A power supply 13 is connected to the anode and a power supply 14 is connected to the cathode for connection to the electrical circuit connected for current detection and alarm signaling.

It was shown that by observing the measures described a fire alarm can be produced, which can already reliably detect a carbon monoxide content below 100 ppm and which do not cause false alarms due to other contaminants normally found in the air was stimulated.

209885/0796

Claims (1)

Claims /1. Automatic fire alarm with a device for the detection of combustion gases characterized by a detection cell with a cathode, an anode accessible to the combustion gases and an electrolyte arranged between the anode and cathode, the anode being able to catalytically oxidize the carbon monoxide contained in the combustion gases by emitting electrons , as well as an electrical circuit connected to the anode and the cathode for current detection and alarm generation. 2. Automatic fire alarm according to claim 1, characterized in that that the electrolyte has basic properties and the cathode is able to give off hydroxyl ions. 3. Automatic fire alarm according to claim I _1, characterized in that the electrolyte has acidic properties and the cathode is able to absorb hydrogen ions. 4. Automatic fire alarm according to claim 1, characterized in that that the cathode has a polymeric phthalocyanine of a transition metal. '. ». Automatic fire alarm according to claim 4, characterized in that 2 0 ί) 8 U b / 0 7 9 6 indicates that the cathode contains soot, which is coated with a phthalocyanine of the iron group. 6. Automatic fire alarm according to claim 1, characterized in that that the anode has a metal of the platinum group as a catalyst. 7. Automatic fire alarm according to claim 6, characterized in that that the anode has palladium as a catalyst. 8. Automatic fire alarm according to claim 6, characterized in that that the anode comprises nickel powder which is coated with a metal of the platinum group. 9. Automatic fire alarm according to claim 8, characterized in that that the nickel powder is applied to a gas-permeable membrane. 10. Automatic fire alarm according to claim 2, characterized in that that the anode has an ion exchanger. 11. Automatic fire alarm according to claim 10, characterized in that that the ion exchanger is a copolymeric styrene-divinylbenzene with quaternary ammonium groups. 20988 ^ / 0 7 96 I- ?. Λιι I oma L i scher fire alarm according to claim 2, characterized in that the electrolyte is potassium bicarbonate
contains. 13. Automatic fire alarm according to claim 2, characterized in that the electrolyte is cesium carbonate
contains. 14. Automatic fire alarm according to claim 3, characterized in that that the electrolyte contains phosphoric acid 15. Automatic fire alarm according to claim 1, characterized in that a porous layer soaked with the electrolyte is attached between the anode and cathode
is. 16. Automatic fire alarm according to claim 1, characterized in that that an evaporation-inhibiting substance, e.g. glycerine, is added to the electrolyte. 17. Automatic fire alarm according to claim 1, characterized in that the anode and cathode are plate-shaped and at a distance of less than 5 mm
are arranged from each other. 209885 / U796 18. Automatic fire alarm according to claim 1, characterized in that that both the anode and the cathode are accessible to the surrounding air. 19. Automatic fire alarm according to claim 18, characterized in that that the cathode consists of very finely divided silver, which is on an oxygen-permeable Membrane is applied. 20. Automatic fire alarm according to claim 1, characterized in that that the anode on the side facing the electrolyte is hydrophilic and on the outside contains a hydrophobic substance. 209885/0796