DE2029485B2 - IONIZATION SMOKE SENSORS - Google Patents

Description

The invention relates to a ionization smoke sequence of the parallel connection to the open ionization

sensor with an open and a closed chamber moves in a direction in which the

Ionization chamber, in each of which there is a radioactive impedance that occurs when smoke penetrates

Ouclle is arranged and its closed by raising the open ionization chamber no longer

an inner electrode, an insulating support part S for guiding the control electrode to

and an intermediate electrode is formed and the point of connection of the two ionization chambers is

open from the intermediate electrode, the support part and lowing transistor could lead. Without the connection

an outer connection, provided with ventilation openings, of the detector electrode with the inner elec-

Electrode is formed. trode, the shunt to the open ionization

In ionization smoke sensors of this type, the ionization chambers are an increase in their resistance

two ionization chambers in series to a chip with the ingress of smoke with regard to an exit

voltage source switched and their connection point is effect on the control electrode of the transistor uri-

led to the control electrode of a transistor, which make effective or in the effect so far

Changes in potential, which reduce the penetration of smoke, that the transistor is no longer able to

occur in the open ionization chamber, determines 15 conductors would come. By the inventive

and generates an alarm signal. However, when adding the detector electrode and its connection changes

If the smoke sensor is used for a long time, the insulation with the inner electrode will, however, reduce the potential

between the electrodes of the ionization chambers, at the point of the detector electrode to the potential

in particular the open ionization chamber, which brought the inner electrode so that the through a

The interior is constantly exposed to the ambient air. ao pollution occurred creep resistance between

Then when smoke in an open ionization chamber see the detector electrode and the connection

penetrates and the flow point of the two ionization chambers between their electrodes parallel to the

changes the current, the resulting closed ionization chamber is sufficient, which is practically

Potential change at the connection point of the two tables results in a reduction in their impedance equal to

Ionization chambers no longer come to the actuation of the as, so that the transistor becomes conductive and one

Alarm device off. If a fire breaks out there is an alarm that triggers on the pollution and the

the smoke sensor will then no longer have an alarm, so that it will pay attention to the necessary cleaning of the smoke detector.

scine function no longer fulfilled. sam makes. In a special embodiment of the invention

In order to prevent such contamination, the detector can be placed in a ring on the

it is known (German patent 10791.51) to be arranged between 30 surfaces of the tragtcil,

the open and the closed ionization chamber The invention is described below on the basis of the

cinc Abdcckschcibc from a highly insulating, positions of an exemplary embodiment explained in more detail,

to provide water-repellent material, which shows an It

Formation of creepage paths between the outer Fig. 1 is a partial section of a. ^T onisationsrauch-

and to prevent the internal electrode. One of the sensors according to an embodiment of the invention,

good protection is only imperfect, since not F i g. 2 is a circuit diagram to illustrate the

in all cases and for the long term, the electrical circuit of the smoke sensor according to FIG. 1 is ensured

can not change over time

deposit dirt on the cover panel, FIG. 3 is an equivalent circuit diagram of the electrical

which are then used to form over 40 connections to explain the operation of the in

lead bridging resistances for leakage currents. F i g. 1 shown smoke sensor.

The object of the invention is to provide the support part 2 made of insulating material

improvement of the known ionization smoke sensor, consists of a flat middle section 4, which is from

in such a way that a tooth which occurs over time is surrounded by a toothed part 6, and from one

dirt does not remain undetected, so that the 45 circumferential section 8, which in turn surrounds part 6

Smoke sensor no longer fulfills its purpose, but exists. On the flat section 4 of the support part 2 is

which is recognizable, so that the smoke sensor is provided with an inner electrode 10, and on the

can be cleaned and its original own part 6, an intermediate electrode 12 is attached. on

shafts again shows in full measure. the outer section 8 of the insulating support part 2

This task is carried out with an ionization smoke 50, for example with the help of screws, a sensor with an open and a closed cup-shaped, outer electrode 14, the ionization chamber, in each of which a radioactive one also serves as a cover. It has several ventilation sources arranged and their closed openings 16, which allow a free passage for an inner electrode, an insulating support part · smoke. An intermediate electrode is formed on the inner electrode 10 and whose s & is a first radioactive source 18 and on an upper surface of the intermediate electrode, the support part and surface of the intermediate electrode 12, which is opposite the outer electrode 14 provided with ventilation openings a second radioac electrode is formed, achieved in that inventive source 20 is arranged. In this way, according to the principle on the surface of the support part between the closed ionization chamber 21, the inner electrode and the outer electrode 10 and the intermediate electrode 12, an electrode connected electrically to the inner electrode and the open ionization chamber 22 consists of the bound, surface impurities of the support part intermediate electrode 12 and the outer electrode 14. Detecting detector electrode is arranged, The arranged in both ionization chambers

This detector electrode prevents that the poles - radioactive sources serve to ionize the air

tial of the intermediate electrode, which simultaneously sets the 6s in the relevant ionization chambers, so that between

electrical connection between the open and the see the relevant pairs of electrodes Ionisa

represents a railed ionization chamber in which ion currents can flow,

Contamination occurring in the course of time in the part 6 of the holding the intermediate electrode

Claims (1)

3. 4th Support part 2 has a plurality of annular grooves for a wlhischte state that even when penetrating Formation of a large surface creep resistance smoke in the open ionization chamber no alarm Standes, and in the outermost groove, which is triggered on the. The reason for this is now at hand Peripheral section 8 is adjacent, a Dctektorelek- of Fig. 3 is explained. trodc 24 to determine a surface violation 5 In F i g. 3 become the closed and the open fitted in dirty. On the rear surface of the ionization chamber 21 or 22 by equivalent insulating support part 2 is a printed switching resistors 21 and 22 shown. It is now processing card 28 attached, on which the circuit nommcn that the surface of the insulating support to determine a change in potential on which part 2 is dirty. Then there are the anti-isolation intermediate electrodes 12 If smoke penetrates, the surface area between the intermediate is formed in the ionization chamber. Schclektrode 12 and the electrode 24 on the one hand Other construction shown in the drawings and between the Dctcktorelektodc 24 and the elements that are not directly related to the outer electrode 14 here, on the other hand, are greatly reduced, Invention described are, are not wetter This has the effect that parallel to the intermediate explains. »5 electrode 12 and the outer electrode 14, d, h. so F i g. 2 shows the internal circuit connections between the two electrodes of the open ionization an ionization smoke sensor, shown in FIG. 1 chamber 22, a relatively small resistance in parallel is built and two are connected in series between the span. This wide edge is shown in FIG. 3 as voltage lines 41 and 42 failed ionization series connection of two resistors SO and 52 vcr- chambers21 and 22. The two ionization ao illustrates. chambers 21, 22 are connected to one another at point 120. Resistor 50 represents the creep resistance shown as bound, although this connection point is between the intermediate electrode 12 and the in the case of the one shown in FIG. 1 represented by the detector electrode 24, while the resistor Intermediate electrode 12 itself is formed. The 52 creep resistance between the detector elec- The connection point 120 is with the control electrode of an as trode24 and the outer electrode 14. Field effect transistor 30 vcrounden, whose collector If the Detcktorclcktrode 24 is not provided would be directly to the line 41 and its emitter, then the potential at the connection Via a resistor 32 to the line 42 angc- point 120 of the two ionization chambers, that is to say is closed. The emitter of the field effect transistor of the intermediate electrode 12, because of this Kricch- 30 is also connected to the control 3 via a Zcncrdiode 34 resistances SO and 52 do not increase enough to Electrode of a controlled silicon rectifier 36, the field effect transistor 30 fully to conduct connected, which bring between the lines 41 and, even if smoke in the open ionization 42 is connected, which penetrates the positive chamber accordingly and whose internal resistance tive and negative connection of a voltage source increases. It would then also in case of occurrence 38 are shielded. 35 of smoke in the open ionization chamber no Is the surface of the insulating support part 2 of the alarm given. According to the invention, however, the upper resistance of the surface areas of the insulating surface contamination ascertaining detector electrode support part 2 is provided between the intermediate electrode 12 and 24, which is connected to the inner electrode 10, ie the 40 ascertaining the surface contamination to the conductor 41 , connected is. Line reduction of the detector electrode 24 on the one hand and the detector electrode creep resistances 50 and 52 as a result of the upper surface 24 and the outer electrode 14 on the other hand, surface contamination of the insulating support part 2 is sufficiently large, then the in FIG. 2 dargestcll- corresponds to a reduction in the inner th ratio. If smoke now gets into the open resistance of the closed ionization chamber 22 through the ventilation opening 45 21, so that the control electrode of the field effect openings 16 of the outer electrode 14, then the voltage supplied to transistor 30 increases the acidifying current in the open ionization chamber as much as in the case that smoke in the open Ionisa-22 and the potential penetrates at the connection point 120 tiopskamrner. In this way, the (that is, in practice, the field effect transistor 30 on the intermediate electrode 20 and itself) of both ionization chambers 21, 22 rises. 50 in turn controls the silicon rectifier 36, so that the field effect between the collector and emitter that an alarm is triggered. The pollution transistor 30 flowing stiom increases with this state can then be remedied immediately. In this Poüntialanstieg and the abfal- the resistor 32 manner, the reliability of the alarm device! Voltage increases with the increase DIE considerably improved because an insulation verse current when the voltage across the resistor 32 55 schhchterung between the electrodes open the Zener voltage of the Zener diode34 exceeds, the ionization chamber is detected in time, then reaches the control electrode of the controlled Silicon rectifier 36 an ignition signal, which the claims: Brings rectifier 36 to conduct, and a smoke The generation signal is sent to the power supply unit 60 1. Ionization smoke sensor with an open 38 supplied. Dk «« s signal activates an alarm device and a closed ionization chamber, in on the side of the power supply units !! for each of which a radioactive source is arranged solving an alarm. and their closed by an internal elec- However, if the surface, especially the trode, an insulating support part and a open ionization chamber 22 exposed upper «a intermediate electrode is formed and its open surface of the insulating support part 2 is dirty from the intermediate electrode, the support part and so that the surface resistance after a long period of an external, provided with vemilaüonsöff- Use is reduced, then the un- nt *. Electrode is formed, thereby records that on the surface of the support part (2) between the inner electrode (10) and the outer electrode (14) has an upper electrode connected electrically to the inner electrode (10) Surface contamination of the support part (2) firmly 'S adjusting Dctektorclcktrode (24) is arranged. 2. ionization smoke sensor according to claim 1, characterized in that the detector electrode (24) is annular on the surface of the Support part (2) is arranged. to 3. ionization smoke sensor according to claim 1 or 2, characterized in that the outer one provided with the ventilation openings (16) Electrode (14) is designed as a cover cap. 4. ionization smoke filter according to claim 1, characterized in that the radioactive source (18) in the closed ionization chamber (21) on a surface of the inner electrode (10) opposite a surface of the Intermediate electrode (12) is arranged and that the radioactive source (20) in the open ionization chamber (22) on the other surface the intermediate electrode (12) is arranged opposite the outer electrode (14). 5. lonisaüons smoke sensor according to claim 1, characterized by a transistor (30) to detect changes in potential at the Intermediate electrode (12} and through one of the output of the T / anslsi direction. Transistor controlled alarm 1 sheet of drawings