DE2036447A1 - Ionization smoke detector - Google Patents

Description

8327-70; Dr.vB / Schä
139-5

JA-PA SHO 44-57979
AiD 24o July 1969

JA-PA SHO 44-66839
AT 26p August 1969

Nittan Company, limited

1-11-6, Hatagaya, Shibuya-ku, Tokyo, Japan

Ionization smoke detector.

The present invention relates to an ionization smoke alarm with at least one containing at least two electrodes and at least one radioactive radiation source closed ionization chamber in series with at least one also at least two electrodes and at least an open ionization chamber containing a radioactive radiation source between two conductors for supplying an operating voltage is connected, at least one field effect transistor, which is caused by voltage changes at the connection the two ionization chambers can be controlled, which occur when smoke penetrates into the open ionization chamber, and a thyristor controlled by the field effect transistor, the controllable current path of which is connected between the two conductors is.

A well-known ionization smoke detector contains a closed ionization chamber in which two electrodes and a radioactive radiation source are arranged, an open ionization chamber that allows the penetration of Raudh or other combustion products, which in a corresponding manner contains two electrodes and a radioactive radiation source and in series with the closed ionization chamber is connected to a voltage source, a field effect transistor that is controlled by voltage changes at the connection of the two ionization chambers, which are based on an increase in the impedance of the open ionization chamber, and a holding element, such as an Ihyrietor or adjustable rectifier, the duroh

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BATH ORiGINAL

the output signal of the field effect transistor !? in the senior State can be brought.

However, these known ionization smoke detectors have the disadvantage that when supplied with a pulsating voltage, as you can by simply calibrating an alternating voltage is obtained without smoothing, the thyristor does not conduct in the range of the zeros of the supply voltage, even if the Field effect transistor supplies an ignition signal to the thyristor. The generation of a smoke alarm signal is then not included Security guaranteed. One therefore had to use the known ionization smoke alarms with a sufficiently smooth DC voltage feed, which requires a correspondingly complex voltage source.

The present invention is accordingly based on the object of providing an ionization smoke detector of the type mentioned at the beginning Kind to the effect that he can also use a simple and cheap voltage source, which is a pulsating Provides voltage, can be operated.

According to the invention, this object is achieved in the case of an ionization smoke detector of the type mentioned at the beginning by means of a hold circuit reached, which supplies a current, which the thyristor, after it has ignited once, even then in the conductive state holds when there is a pulsating voltage on the two conductors.

In the following, exemplary embodiments of the invention are explained in more detail with reference to the drawing, which show:

1 shows a circuit diagram of a first exemplary embodiment of an ionization smoke detector according to the invention;

FIG. 2 shows diagrams which show the time profile of voltages in the circuit arrangement according to FIG. 1 and are used to explain this circuit arrangement; FIG.

Pig. 3 is a graphical representation of characteristic curves to which reference is made in the explanation of the mode of operation of the other according to FIG. 1 and

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Fig. 4 is a circuit diagram of a second embodiment of an ionization smoke detector according to the invention,

The ionization smoke detector according to FIG. 1 contains a closed ionization chamber 10 with two electrodes 11 and 12 { as well as a radioactive radiation source 13 »and an open j Ionization chamber 20, which contains two electrodes 21, 22 and a radioactive radiation source 23 in a corresponding manner and is connected in series with the closed ionization chamber 10 between two conductors 1 and 2, which become one lead voltage source, not shown. The connection

5 between the two ionization chambers 10 and 20 is connected to the control electrode 31 of a field effect transistor 30, whose drain electrode 32 is connected directly to the conductor 1, while its source electrode 33 via a Resistor 4 is connected to conductor 2. The source electrode 33 is also via a Zener diode 34 with the Control electrode 41 of a thyristor 40 connected. A resistor 44 is located between the control electrode 41 and the conductor 2 and a capacitor 45 lying parallel to this is connected. The anode 42 of the thyristor 40 is through a resistor 7 with a relatively small resistance value and a diode 6 connected to the conductor 1, while the cathode 43 of the thyristor is connected directly to conductor 2. The connection 8 between the diode 6 and the resistor 7 is connected to conductor 2 via a capacitor 9. The diode

6 and the capacitor 9 form a hold circuit 60, the Keeps thyristor 40 in the conductive state for a predetermined period of time once the thyristor has been ignited

For the explanation of the operation of the ionization smoke detector described with reference to FIG. 1, it is assumed that on the conductors 1 and 2 have a pulsating direct voltage as can be achieved by simply rectifying an alternating voltage As the ionization chambers 10 and 20 have a certain Have self-capacitance and a very high impedance

1098U9 / 1 3üÖ

they have a certain G-smoothing of the pulsating tension applied to them. If you look at the tension on the ver. If the open ionization chamber 20 is smoke-free, however, if smoke enters the open ionization chamber 20, the ionization current flowing through it is reduced and its impedance increases, so that the voltage rises at the junction 5 and now has the dashed line corresponding in Pig "2 52 course ,, the AC components e. and e ₂ by the curves 51 or" 52 in Pig " 2 ones shown, <presented voltages are relatively independent of the presence or absence of smoke in the open ionization chamber 20c

Since through the closed ionization chamber 10 is always the Sättigungsionisationsstrom flows _9, the current flowing through the open ionization chamber 20 ionisation current by a voltage change at the open ionization chamber, which is caused by an impedance change of the closed ionization chamber 10 is not greatly changed "These ratios are in the diagram according to Pig * 3, in which the voltage at connection 5 is plotted along the abscissa and the ionization current is plotted along the ordinate there is no smoke is in the open ionization chamber 20, and the voltage at the junction 5 is low (solid curve in Pig _e 51 2) j but when smoke enters the open ionization chamber 20, the voltage at the closed ionization chamber 10 is low and it changes accordingly d he dashed curve 62, while the voltage at connection 5 is high (dashed curve 52 in Pig. 2) as from Pig. 3 it can be readily seen, “In both cases, however, there is a large area (O-Vp) in which the saturation ionization current in the closed ionization chamber 10 4 * t does not change appreciably.

1 0 9 8 0 U /; : <t; y

The ionization current in the open ionization chamber 20 normally follows the curve 71 in Pig. However, if smoke enters the open ionization chamber 20, the ionization current in the open ionization chamber 20 tends to change according to the dashed curve 72 (FIG. 3). The ionization current in the open ionization chamber 20 does not change significantly because of the inherently large time constant of the ionization chambers, even if there is a pulsating voltage on the conductors 1 and 2. The voltage at connection 5 of the two ionization chambers is _{changed between the values V 1} and Vp by the penetration of Hauch into the open ionization chamber, and this voltage change controls the field effect transistor 30, which delivers a corresponding output signal at its source electrode 33. When smoke enters the open ionization chamber 20, the voltage at connection 5 rises from V- to Vg (FIG. 3) and the current flowing through the source-drain path of the field effect transistor 30 increases accordingly. When the voltage across the resistor 4 exceeds the Zener voltage of the Zener diode 34, the latter transmits an ignition signal to the control electrode of the thyristor 40, which switches it into the conductive state. However, since there is a pulsating voltage between the conductors 1 and 2, the triggered thyristor would block again if the supply voltage dropped to zero if this undesired effect were not prevented by the holding circuit 60. The capacitor 9 of the oil circuit 60 is discharged through the resistor 7 and the thyristor 40 when the voltage between the conductors 1 and 2 drops to zero and the thyristor 40 is kept in the conductive state by this discharge current. By conducting the thyristor 40, the two conductors 1 and 2 are connected via the resistor 7, which has a relatively low resistance value, and the current flowing through the conductors 1 and 2 increases accordingly. The increase in current is perceived and triggers an alarm.

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Tests have shown that the sensitivity of the ionization smoke detector described hardly changes and that it works properly as long as the effective value the pulsating voltage applied to conductors 1 and 2 is kept essentially constant »Of course the ionization smoke detector described can also be operated with a smoothed direct current.

The ionization smoke detector described above does not require an expensive, stable DC voltage source for power supply, and it works are therefore characterized by very low investment costs and economical operation.

In the second embodiment of an ionization smoke detector according to the invention shown in Fig. 4-, the reliability is increased even further when operated with an unstabilized voltage source that a special protective circuit is assigned to the field effect transistor, which ensures that the field effect transistor, whose breakdown voltage can be low never receives a voltage that exceeds a specified value. In Fig. 1 and 4, identical parts are provided with the same reference numerals, and the description of these parts will be omitted ₀

The drain electrode 32 of the field effect transistor 30 is via the collector-emitter path of a bipolar transistor

15 connected to line 1. The base electrode of the transistor 15 is connected to the connection 18 between a resistor

16 and a Zener diode 17 connected in series between the conductors 1 and 2. The base electrode of the! Transistor 15 is accordingly on one by the tens | diode 17 certain, constant voltage held the transistor 15, the resistor 16 and the Zener diode 17 thus form a constant voltage protection circuit for the field effect transistor 30th

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If in the ionization smoke detector according to FIG. 4 the If the voltage between the conductors 1 and 2 increases, the voltage at the drain electrode 32 of the field effect transistor decreases 30 and thus the voltage at the emitter electrode of the transistor ^ 15 to. However, since the voltage at the base electrode of the transistor 15 is kept constant, the voltage increase has at the emitter electrode of the transistor 15 an increase in the impedance of the emitter-collector path of the transistor 15 and correspondingly an increase in the voltage at its emitter-collector path. The voltage at the drain electrode 32 of the field effect transistor 30 can thereby under a given value can be maintained.

. The ionization smoke detector according to Fig 4 has the advantage over the first-mentioned embodiment also the following '_ advantages: The field effect transistor such as a field effect transistor with insulated gate electrode which has a low breakdown voltage can not be damaged by transient overvoltages, for example, by a Heiais or Bells are generated at the location of the voltage source. The ionization smoke detector can also be fed without the risk of damage to the field effect transistor by a voltage source of moderate quality, which supplies a strongly fluctuating output voltage.

The exemplary embodiments described above can of course be modified in the most varied of ways without going beyond the scope of the invention. The exemplary embodiments described above only contained zw $ r a single closed ionization chamber and a single open ionization chamber each with only a single pair of electrodes and a single radioactive radiation source, of course, an ionization smoke detector according to the Invention in the Baxis any number of closed and open ionization chambers with any number of Electrodes and radioactive sources included, if

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ORIGiNAL INSPECTED

this should prove to be expedient. If so desired can also use more field effect transistors than just thinner ones * to be

1 0980 above / 1 3 8 above

Claims (2)

Claims. 1 ο'ionisation smoke detector with at least one at least two electrodes and at least one closed ionization chamber containing at least one radioactive radiation source, which are in series with at least one at least two electrodes and at least one open ionization chamber containing at least one radioactive radiation source is connected between two conductors for supplying an operating voltage, at least one field effect transistor, the can be controlled by voltage changes at the connection of two ionization chambers, which when smoke penetrates into the open ionization chamber and one through the Field effect transistor controlled thyristor, the controllable current path of which is connected between the two conductors, characterized by a hold circuit (60; b, 9) which supplies a current which the thyristor (40), after it has ignited once, also in the conductive state holds when there is a pulsating voltage on the two conductors (1,2). 2. Ionization smoke detector according to claim 1, characterized in that the holding circuit is a diode (6) which is connected for the current flowing through the thyristor (40) in the flow direction between the anode (42) of the thyristor and one (i) of the two conductors , and a capacitor (9) »connected between the cathode of the diode and the other (2) of the two conductors contains ₀ 3β ionization smoke detector according to claim 1 or 2, characterized by a constant voltage protection circuit - (15,16,17) between the drainage electrode (32) of the field effect transistor and one (H) of the two conductors (1,2) connected and the field effect transistor (30) applied voltage below its breakdown voltage holds 109809/1388 4β ionization smoke detector according to claim 3 »characterized; that the protective circuit has a transistor (15)» its emitter-collector path between the drain electrode (32) of the field effect transistor (30) and one (1) of the two conductors (1 _S 2) is connected, a resistor (16) connected between the base electrode of the transistor (15) and one (1) of the two conductors and a Zener diode (17) connected between the base electrode of the transistor (15) and the other (2) of the two conductors ) contains. 109809/1388