DE1089193B - Gas analysis and gas warning device and ionization chamber for this device - Google Patents

Description

GERMAN

The changes in the composition of gases are known devices with the help of Ionization chambers monitored. The gas to be monitored is passed through the ionization chamber and ionized by built-in radioactive emitters. There are also at least two with one in the chamber Potential difference provided electrodes housed, between which a result of the ionization of the gas Depending on the composition of this gas, an electric current flows. The current changes are evaluated to monitor the composition of the gas.

Such devices are often used as fire alarms. More distant when monitoring Rooms must have a system of pipes through which the gas to be monitored can flow into a control room installed devices is supplied. Fans are used to generate the necessary gas flow used. If the generated flow is too low, there is a delay in the response of the Device that depends on the time it takes for the gas to move from the tapping point to the display device needed. To avoid this disadvantage, the flow rate of the gas increased, then display errors can occur insofar as the variable strength of the ionization current the Measurement result influenced. With different acceleration of the gas mixture an irregular Entrainment of the ions by the gas flow occur. This is the number of times on the anode hitting ions also differ, so that the conducted over the two electrodes (cathode and anode) electrical measuring current is no longer solely proportional to the composition of the gas mixture, but can also change with the flow rate of the gas.

Further difficulties with such gas warning devices arise with the corresponding evaluation devices of the measurement result. These evaluation devices generally contain vacuum tubes, whose grid is supplied with the potential changes to be measured. The potential fluctuations but are so small that any occurring, albeit slight, grid current falsifies the measurement result.

The invention is based on the described disadvantages of a gas analysis and gas warning device to avoid.

To solve the first task, namely to keep the strength of the ionization current largely constant, according to the invention, a barrier grid is arranged in the interior of the chamber in the direction of the gas flow behind the anode, the potential of which is lower than the potential of the anode with regard to the voltage of the gas analysis and gas warning device
and ionization chamber for this device

Applicant:

S te. ä Responsabilite Limitee dite:

La Detection Electronique Frangaise

"D.E.F.", Paris

Representative: Dipl.-Ing. A. Boshart

and Dipl.-Ing. W. Jackisch, patent attorneys,

Stuttgart N, Am Kräherwald 93

Claimed priority:
France, October 24, 19S7

Robert Guilleux, Chatülon-sous-Bagneux, Seine

(France),
has been named as the inventor

is selected at the cathode. The distance between the anode and the barrier grid can be adjusted from the outside be.

According to another embodiment of the invention, there is an additional radiation source inside the chamber arranged, which generates an ion current opposite to the original ion flow direction. In the first solution, a part of the entrained ions is reflected on the barrier grid, so that their number on the positive electrode (anode) is kept constant.

In the second solution, the gas flowing through also comes from the outlet source too many ions entrained, which can no longer be captured by the anode. On the other hand transported but the same gas flow has a number of ions from the second ionization source, namely in that the same measure as the original ionization current is amplified. In this case, the missing ions are supplemented by further ions generated by the second source.

The radioactive radiation source provided inside the ionization chamber can with the help of a Heating wire can be heated electrically.

To evaluate the measuring current, two ionization chambers are used in known gas warning devices

009 607/184

3 4

Connected in series, one of which is saturated. With the help of the adjustable screw 13, the series circuit is connected in parallel to a direct radiation source 12, more or less concealed voltage source, and the measuring potential, whereby in a manner known per se one is taken from one of the two chambers. To control the radiation intensity is made possible. The one influencing of the evaluation circle of the 5 strength of the radiation is known to be avoided by the actual measuring circle, according to the invention, precipitation of moisture on the emission is influenced by a layer provided with at least two grids. In order to avoid the electron tube thereby provided, the cathode of which is provided with the standing display error, a radiation source 12 negative terminal of an additional battery and electrically heated by a heating wire 14, which generates a temperature of this radiation source parallel to the tap of one of the direct voltage source, which is connected to the somewhat switched voltage part ; the first is higher than the ambient temperature.
The grid of the tube is connected to a milliammeter. The barrier grid 11 receives a negative potential with respect to the positive terminal of the battery for generating the anode 9. A grid current is connected by this grid; The second grid repels the negative ions carried along by the gas flow to the junction of the two ionization ions, and the positive ions of the space are connected to the chambers, the potential of which is intercepted. This way the ionid of the cathode is negative. sation current between electrodes 8 and 9 at different

There is thus a variable velocities of the gas flows flowing over the first grid Grid current is generated, the strength of which is kept constant by the. To achieve optimal operational fluctuations negative potential of the second grid 20 conditions is the potential difference between the is controlled. These fluctuations in potential are essential to the anode 9 and the barrier grid 11. These witness a change in the electrostatic field potential difference is made by choosing a suitable one inside the tube and thus a change in shape for these two electrodes is determined. she can internal resistance of the grid-cathode section. by changing the distance between the anode 9 The evaluation circuit is thus completely set by the measuring circuit 25 and the barrier grid 11. Separated from change. tion of the distance is the barrier grid 11 in one

The cathode can be arranged with the first ionization sliding sleeve 15 and with the help of the pin 16 The electrically conductive jacket surrounding the chamber can be displaced in the longitudinal direction of the chamber. Of the tend to be connected. In this way, a pin 16 is in a spiral groove 17 shielding the chamber in the manner of a Faraday 30 out. The at a given gas together cage obtain. Settlement of any fluctuations in the

In the following, the invention will be based on the ionization current lying between two values, the

the embodiments shown in the drawings sufficiently far from the value of the flow velocity

explained in more detail. They are shown in the distance of the gas, so that an opposing

Fig. 1 the ionization chamber according to the invention 35 side interference cannot occur,

in section (schematic), the second ionization The barrier grid 11 can be through the wire of a

chamber, also in section, as well as the associated light bulb must be replaced.

Evaluation circuit, the battery 18 supplies the for the electrodes of the

2 shows a second embodiment of the ionization voltages required for both ionization chambers,

chamber in section (schematic). 40 The cathode 8 of the ionization chamber 1 is connected to the

The gas warning device shown in Fig. 1 contains a negative pole connected to this battery. The barrier ionization chamber 1, through which the grid 11 to be monitored receives the gas via a conductive connection flows in the direction of the arrow. The fan 3 serves the same potential. The anode 9 of the ionization chamber 1 to amplify or regulate the gas flow; is via the cathode 20 and the anode 21 of the ionin Row to the ionization chamber 1 is another 45 sationskammer 2 and a series resistor with saturated ionization chamber 2 switched. connected to the positive pole of the battery. To the

The fan 3 can also be created in the connection point 19 of the two chambers to be crossed be arranged guarding room and the gas flow as a result of this series connection a reference potential, by a chamber 1 that is further away from the one connected to the changes in the ionization current Feed the sewer system to this chamber. 5 ° pre-called changes of the battery 18 er-Die Chamber 1 fluctuates with a cylindrical, electrically generated measuring current. This potential will conductive sheath 4 surrounded. The jacket 4 is also evaluated for the measurement. Through the series connection Provided earth potential and for this purpose with the influence of the surrounding cathode in a known manner the tube 26; some of the still to be heated and the moisture on that to be overwritten _ The evaluation circuit is connected. 55 guarding gas switched off for the measurement. These The two openings of the ionization chamber 1 are still dependent on the temperature provided with mechanical protective grids 5, 6. Inner resistors 22, 23 supported, the temperature of which is within the cylinder 4 is another, made of insulating material coefficient is negative.

existing cylinder 7 arranged, which is in the The evaluation circuit consists essentially of Electrodes 8 and 9 located in the chamber and 60 of the tube 26, the instrument 31, the transistors to avoid stray electrical 35, 35 ', the relays 37, 37' and alarm and display currents serves as a result of being suspended in the devices 40, 41 or 40 ', 41'. The tube 26 degas any impurities can occur. holds two grids 28, 29. From the battery 30 is a

At the electrode 8 forming the cathode, a grid current is generated via the cathode 27 and the grid 28.

Radiation source 12 arranged, which testifies with a 65, which through the coil of the milliammeter 31

α-particle emitting radium salt is coated. flows. The negative pole of the battery 30 is with the

The electrode 9 serving as anode is connected to an insulating tap of one of the batteries 18 in parallel

lierträger 10 attached. Behind the anode 9 (connected in Rieh voltage part. Between this point

direction of the gas flow) is the barrier grid 11 and the connection point 19 of the two ionization

arranged. 70 chambers are to be measured or evaluated

Potential difference. The point 19 is connected to the grid 29 of the tube 2G. The tube 26 can be im the rest can be carried out in any known manner.

The negative potential at point 19 or grid 29 generates a potential in the event of a fluctuation Change in the electrostatic field inside the tube and thus a change in the internal resistance the grid-cathode line. The strength of the grid current is therefore corresponding to the potential fluctuations controlled on the grid 29. The revaluation circle with the milliammeter 31 and the associated Monitoring and display parts is therefore different from the actual, through the series connection of the two ionization chambers formed measuring circuit completely separated, so that a mutual influence cannot take place.

For an assumed normal state of the gas to be checked, the milliammeter becomes 31 set to the value zero by adjusting the adjustable battery 30. Is now for example the gas flowing through the chamber 1 is permeated by smoke, so the internal resistance increases this chamber. This increases the potential at point 19 and the flow of goods through tube 26 increases. This means that the pointer of the instrument deflects to the right and closes the at a given value Contact 32.

The contact 32 is connected to the base 34 of a transistor 35, which is negative via a resistor is biased. The collector potential is chosen to be more negative than the base potential, during the Emitter 33 is positively biased. The transistor 35 thus normally carries a collector current that the winding 37 of a relay flows through. Now touches the pointer of the, which is provided with a positive voltage Instrument 31 the contact 32, the base 34 of the transistor 35 is positive and the transistor with it locked. As a result, the normally closed contacts 38, 39 close the relay, and there is a current through the alarm device 40 and the display device 41 is generated. In the same way, a transistor 35 ' Alarm and display triggered when the pointer of the instrument touches contact 32 '.

In the event of errors in the evaluation circuit, e.g. B. when the grid current is interrupted or a transistor fails, an alarm and a display are also triggered and thus self-monitoring of the evaluation circuit achieved.

With the help of the push button. 42 the evaluation circuit can be put out of operation. In this case, receives the pointer negative potential and the display is interrupted. A shutdown of the positive The potential of the pointer is therefore not necessary for decommissioning.

In Fig. 2, another embodiment of the ionization chamber 1 is shown. The chamber is constructed symmetrically. On both sides of the anode 9, two radiation sources 24a, 24 & or 25a , 25b are arranged. The emission currents of the two radiation sources of a pair of radiators are directed in opposite directions. If a gas flow is passed through the chamber in the direction of the arrow f ₁ , too many ions can be carried along and are no longer captured by the anode. The same gas flow, however, transports a number of ions from the second ionization source to the same extent as the original ionization current is amplified. The missing ions are therefore supplemented by further ions generated by the second source. The symmetrical structure ensures that gas can flow through the chamber from both sides, with a satisfactory display being made possible in both cases. These chambers can be used in particular in large warehouses where the gas flow can be indifferent.

The device can either be designed to be portable or in a centrally arranged monitoring device installed, which is provided with a rotary distributor. Continuous controls of the Atmosphere of different rooms can be made with a single device. When installing in a central monitoring device can use a single fan to maintain the flow be used.

The electrical evaluation device can be provided in multiple designs, so that a room in which there is an ionization chamber, can be monitored from different points. If different complete devices are installed in different rooms, the signaling forwarded to a central monitoring point. The concentration of the gas components can then each recorded in a diagram. In this way the exhaust gases from Boilers, combustion engines, motors or reactor test stations can be monitored.

The device according to the invention can also be used to monitor contamination of the atmosphere carried out, for example in road tunnels, which may be forced ventilated, mines (hitting weather) and rooms containing various pressurized gas apparatus, etc. contain.

The device can also be used to detect a specific gas in a specific room, for example the air in a hydrogen-cooled alternating current machine.

Claims (9)

Patent claims: 1. Ionization chamber with built-in radioactive emitter for gas analysis and gas warning devices with a device for constant ionization currents, characterized in that im Inside the chamber (1) in the direction of the gas flow behind the anode (9) a barrier (11) is arranged, the potential of which is lower than the potential of the anode (9) with respect to the voltage is selected on the cathode (8). 2. Ionization chamber according to claim 1, characterized in that the distance between the The anode (9) and the barrier grid (11) can be adjusted from the outside. 3. Ionization chamber with built-in radioactive emitter for gas analysis and gas warning devices with a device for constant ionization currents, characterized in that im Inside the chamber (1) an additional radiation source (24 a) is arranged, which is one of the original Ion flow direction opposite ion current generated. 4. ionization chamber according to claim 3, characterized in that in the chamber (1) two further ionization currents generating opposite direction radiation sources (25 b, 25 a) are present and that the anode (9) between these two pairs of radiators (24 a, 24 & or . 25 a, 25 V) is arranged. 5. Ionization chamber according to claim 1 or claims 1 and 2 or according to claim 3 or claims 3 and 4, characterized in that the radioactive radiation source (12) with Is heated electrically with the aid of a heating wire (14). 6. Gas analyzer, in particular gas warning device, using an ionization chamber according to One of the preceding claims, in which a further saturated ionization chamber in addition to the first is connected in series and in which this series connection is connected in parallel to a DC voltage source is connected and forms a voltage divider, at one element of which the measuring voltage is tapped, characterized in that for evaluating the measurement voltage one with at least two grids (28, 29) provided electron tube (26) is provided, the cathode (27) with the negative terminal of an additional battery (30) and the tapping of one of the measuring current generating DC voltage source (18) connected in parallel voltage divider that the first grid (28) of the tube (26) via a milliammeter (31) to the positive terminal of the battery (30) is connected to generate a grid current and that the second grid (29) of the tube (26) is connected to the connection point of the two ionization chambers (1, 2), the one opposite the cathode (27) has a negative potential. 7. Apparatus according to claim 6, characterized in that the milliammeter (31) on the two The ends of the scale are provided with contacts (32, 3 '), which are connected to the negatively biased base (34 or 34') one transistor (35, 35 '), which is normally in the open state, are each connected, and that the pointer of the instrument (31) is placed at positive potential, which is when the Pointer to one of the two contacts (32 or 32 ') to the base (34 or 34') of the corresponding Transistor is placed and this blocks. 8. Apparatus according to claims 6 and 7, characterized in that in the collector circuits of the transistors (34, 34 ') relays (37, 37') are arranged, the contacts (38, 39 or 38 ', 39 ') close a display and / or alarm circuit if the collector current fails. 9. Apparatus according to claim 6 or claims 6 to 8, characterized in that the cathode (27) of the tube (2.6) is electrically conductive with an electrically surrounding the ionization chamber (1) conductive sheath (4) is connected. Considered publications:
British Patent No. 657,548;
Swiss Patent No. 199 517;
"Electronics" (1957), pp. 205 to 207. 1 sheet of drawings © 009 607/18 + 9.60