DE2036447B2 - IONIZATION SMOKE ALARM - Google Patents

Description

The invention relates to an ionization smoke detector with an open and a closed ionization chamber, each of which contains two electrodes and a radioactive source and those in series between the two conductors of a voltage source are connected, furthermore with a field effect transistor whose Channel current path in series with a load resistor also connected between the two conductors and its control electrode is connected to the connection point of the two ionization chambers and the one controlled silicon rectifier, the> en anode-cathode stretchc is also connected between the two conductors, controls.

In known smoke alarms of this type, the impedance of the open ionization chamber changes when smoke penetrates, so that the potential at the junction of the two ionization chambers also changes and is used to control a field effect transistor, which in turn a controllable silicon rectifier which triggers when smoke occurs is controlled. If you feed such a smoke alarm with a pulsating voltage, as it is obtained by simply rectifying an alternating voltage without smoothing, so the rectifier returns to its blocking state as soon as the supply voltage is between two halves falls to zero. The generation of a smoke alarm signal is therefore not guaranteed with certainty, and for this reason the known ones had to be used Feed ionization smoke detectors with a sufficiently smooth DC voltage, which causes the Increased effort for the supply voltage source.

Although it is known (German Auslegeschrift 1028 472), measuring pulses that are fed to a measuring device and the frequency of which depends on the measured variable, * n to smooth with the help of 7? in this way to obtain an approximate DC voltage, the level of which depends on the measured value, because thereby the reading of the measuring device

ίο is relieved when his pointer is not in time with the Measurement pulse fluctuates. However, such a smoothing circuit is not suitable for the supply a controlled silicon rectifier, since its on-resistance is so small that the capacitor of a βC-Glicdes would be discharged immediately without a new charge being charged quickly enough through the resistor for the condenser could be brought up. Even then would be the controlled one Silicon rectifier return to the blocking state.

The object of the invention is to provide a circuit for an ionization smoke detector, which can be fed with an unsmoothed voltage, as can be achieved by direct rectification an alternating voltage is present without subsequent sieving. That way you want the effort at the voltage source supplying the supply voltage are reduced. It should continue to do this be ensured that the controlled silicon -

rectifier driving field effect transistor not is damaged as a result of overvoltages, as occur with unsmoothed supply voltages can.

This object is achieved in that inventively

according to the field effect transistor with an overvoltage protection circuit versrben isi, which connected one in series with its channel flow path Has bipolar transistor, the base of which is supplied with a fixed voltage.

Since the diode polarized in the forward direction has a very low forward resistance, it also delivers with the silicon rectifier switched on, enough charge for the capacitor so that the am Silicon rectifier voltage does not drop to zero.

In a particular embodiment of the invention, in the overvoltage protection circuit, the emitter of the bipolar transistor with the drain electrode of the field effect transistor and its collector with the be connected to one conductor, and its base can be connected to and across the one conductor via a resistor a zener diode must be connected to the other conductor. In this way the voltage on the drain electrode of the field effect transistor do not rise above the Zener voltage of the Zener diode, since the bipolar transistor then switched to the blocking state because of the Zener voltage at its base and isolates the field effect transistor from the line.

In the following an embodiment of the invention is explained in more detail with reference to the drawing. It shows

F i g. 1 is a circuit diagram of an exemplary embodiment an ionization smoke neldcr according to the invention, Fig.2 diagrams showing the time course of Voltages in the circuit arrangement according to FIG. 1 represent and can be used to explain this circuit arrangement.

3 4

Fi g. 3 a graphical representation of characteristic curves

on the explanation of the operation of the or absence of smoke in the open loni-

University smoke alarm according to FIG.

is taken. rj _a through the closed ionization chamber 10

The ionization smoke detector according to FIG. 1 contains 5 always de, means saturation ionization current, which is a closed ionization chamber 10 with two electrodes 11 and 12 flowing through the open ionization chamber 20 as well as a radioactive ionization current due to a voltage change at the radiation source 13 and an ollene ionization chamber 20, which is generated by a nier 20. which in a corresponding manner causes two changes in electrical impedance of the closed ionization den 21, 22 and a radioactive radiation source io chamber 10, does not contain very much change and is in series with the closed tone. These relationships are shown in the diagram of the total chamber 10 between two conductors 1 and 1, as measured by F i g. 3, in which the voltage is switched on, which lead to a span connection 5, not shown, along the abscissa and the ionization equation. The connection 5 between the currents are plotted along the ordinate. The voltage at the closed control electrode 31 of a field effect transistor 30, represented by the two ionization chambers 10 and 20, is high and has the bound, the source electrode 33 of which is represented by the curve 61 When resistor 4 is connected to conductor 2 The smoke source electrode 33 in the open ionization chamber 20 is also found via a Zener, and the voltage at connection 5 is low at diode 34 with the control electrode 41 of a thyristor 20 ( solid curve 51 in FIG. 2); if ever-40 connected. Between the control electrode 41 and yet smoke in the open ionization chamber 20 einden conductor 2 is a resistor 44 and when this occurs, the voltage is connected to the closed ionization parallel capacitor 45. The tion chamber 10 is low, and it changes according to the anode42 of the thyristor 40 is above a contradiction of the dashed curve 62, while the chip spacing 7 is high with a relatively small resistance at the connection 5 (dashed curve stand value and a Diode 6 with the conductor 1 ve; - 52 in Fig. 2), as can be easily seen from Fig. 3, while the cathode 43 of the thyristor 40 is borrowed. In both cases, however, there is a large one connected directly to conductor 2. The area (OV.1) in which the saturation ionization link 8 is between the diode 6 and the reverse current in the closed ionization chamber 10 does not change significantly via a capacitor 9 with the conductor 2 30.

tied together. The diode 6 and the capacitor 9 form the ionization current in the open ionization

the one HaHekkreis 60, which runs the thyristor 40 for a chamber 20 normally according to the

holds a predetermined period of time in the conductive state. Curve 71 in FIG. 3, however, if smoke in the open

once the thyristor 40 has been fired. Ionization chamber 20 enters, the ionization

The A flow electrode 32 of the field effect transistor 35 current in the open ionization chamber / 0 to itself

30 is over the collector-emitter path of a bipo corresponding to the dashed curve 72 (FIG. 3)

larcn transistor 15 is connected to line 1. The change. The ionization current in the open ionic

The buM electrode of the transistor 15 is connected to the connection chamber 20 therefore changes because of the

dung ^r 18 between a resistor 16 and a de inherently large time constant Ionisationskam-

Zener diode 17 connected in series between the 40 mcrn 10. 20 not essential even when on

Conductors 1 and 2 are connected. The base electrode of the conductors 1 and 2 has a pulsating voltage.

Transistor 15 is accordingly on a by The voltage at connection 5 of the two ionic

the Zener diode 17 bcs'imm, constant voltage sation chambers 10, 20 is therefore by the penetration

content. The transistor 15, the resistor 16 and smoke in the open ionization chamber 20

the zener diode 17 thus forms a constant 45 between the values F 1 and V, changed and this

Voltage protection circuit for the field effect voltage change controls the field effect transistor

sistor 30. 30. which has a cntsprc-

For the explanation of the operation of the output signal in hand. If smoke enters the ionization chamber 20 described in FIG. 1, it rises, so it is assumed that there is a _{DC voltage pulsing from F 1} to V ₂ across conductors 1 and 2, as indicated by a pulsating DC voltage. is obtained on (Fig. 3), and the source-Atfluß Strcckc the multiple rectifying an AC voltage Fckleffekt ^'r ansistors 30 by flowing current increases. Since the ionization chamber.) 10 and 20 a corresponding to. If the voltage at the unwanted self-capacitance and a very high impedance 4 have over the Zcnerspannang of the Zener diode 34, they cause a certain smoothness of the writes on 55, this transmits an ignition signal to the control circuit pulsating voltage. Considered the electrode of the thyristor 40, which switches this into the glue namely the voltage at the connection 5 of the tcnding state. However, since there is a pulsating voltage between the two ionization chambers with an oscillographic conductor 1 and 2, phen. the result in FIG. 2 pulled out gczcich- the ignited thyristor would when falling ύα nele curve 51, when the open ionization chamber 60 block supply voltage to zero again when this 20 is smoke-free. If, however, smoke does not enter the open undesired effect through the circuit 60 ionization chamber 20, it would be prevented by it. The capacitor 9 of the holding circuit ionization current is reduced and its essence 60 is discharged through the resistor 7 pcdiinz increases. so that the voltage at the connection and the thyristor Λ0 when the voltage between connection 5 increases and now that of the dashed 65 the conductors 1 and 2 drops to zero, and the Thy-Linic 52 in F i g. 2 has a corresponding course. The transistor 40 is held by this discharge current in the alternating voltage component and C ₂ of the state. By routing the Thyrlio curves 51 and 52 in FIG. 2, the two conductors 1 and 2 are connected via the clamping transistor 40 shown

Resistor 7, which has a relatively small resistance value, connected, and through the Current flowing through conductors 1 and 2 increases accordingly. The increase in current is perceived and triggers an alarm

Experiments have shown that the sensitivity of the ionization smoke alarm described is hardly any longer changes and that this works properly as long as the r.m.s. value of the values on conductors 1 and 2 pulsating voltage, is kept essentially constant. Of course, the described Ionization smoke detectors 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 is therefore characterized by very low investment costs and economical operation.

When the voltage between conductors 1 and 2 increases in the ionization smoke detector, the voltage at the drain electrode 32 of the field effect transistor 30 and thus the voltage at the emitter electrode of the transistor 15 increases. However, since the voltage at the base electrode of transistor 15 is kept constant, the increase in voltage at the emitter electrode of transistor 15 has an increase in the impedance of the emitter-collector path of transistor 15 and, accordingly, an increase in the voltage at its emitter-collector path Episode. The voltage at the drain electrode 32 of the field effect transistor 30 can thereby be kept below a predetermined value.
The ionization smoke detector also has the following advantages over the first-mentioned embodiment: The field effect transistor, ζ. Β A field-effect transistor with an isolated control electrode, which has a low breakdown voltage, cannot be damaged by temporary overvoltages. B. can be generated by a relay or a bell 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.

1 sheet of drawings

Claims (2)

Patent claims: 1.Ionization smoke detector with an open and a closed ionization chamber, each of which contains two electrodes and a radioactive source, and those in series between the two Head of a voltage source are connected, also with a field effect transistor whose Channel current path in series with a load resistor also connected between the two conductors and its control electrode at the connection point of the two ionization chambers is connected and the one controlled silicon rectifier, its anode-cathode path is also connected between the two conductors, controls, characterized in that that the field effect transistor (30) is provided with an overvoltage protection circuit, which has a bipolar transistor (15) connected in series with its channel current path, whose base is supplied with a fixed voltage. 2. Ionisaiions-Rauchmeldi_r according to claim 1, characterized in that the emitter of the bipolar transistor (15) is connected to the drainage electrode of the field effect transistor (30) and its collector with one conductor (1) and that its base is connected via a resistor (16 ) with one conductor (1) and Ljer a Zener diode (17) is connected to the other conductor (2 " ¹⁾ .