DE1060017B - Electronic time relay - Google Patents

Description

GERMAN

There are radiation measuring devices and in particular display devices for monitoring existing gamma radiation known, in which a radiation measuring counter tube in series with an ionization chamber is connected to a DC voltage source. The ionization chamber serves as a series resistor. Furthermore, radiation dosimeters and particularly X-ray dosimeters have been proposed in which the radiation to be dosed falls on an ionization chamber, by means of which a capacitor is charged will. The voltage appearing on the capacitor is amplified by means of a high vacuum triode. As soon as the amplified voltage reaches a certain target value, it becomes a gastriode ignited. A relay located in the main discharge circuit of the gastriode then switches the radiation source or the X-ray tube.

In electronic timing relays, which are not tied to a particular purpose, the delay time is determined by the charging or discharging time of a capacitor that is charged or discharged with the aid of a suitable series resistor. In order to make the delay time controllable, the series resistor is usually chosen to be continuously adjustable; However, this results in certain restrictions, since controllable ohmic resistances can hardly be made greater than 10 ⁷ ohms, provided that certain requirements are placed on the accuracy and constancy of the same. In order to obtain delay times of the order of magnitude of only one minute, a capacitor of several microfarads is required accordingly. Attempts have been made to replace the controllable resistor with a hot cathode tube, the anode current of which is made adjustable either by regulating the bias voltage of a control element or by regulating the temperature of the hot cathode. Such arrangements have the advantage that smaller capacitors can be used in order to obtain longer delay times. For this purpose, additional switching elements must be attached, the purpose of which is to keep the operating conditions of the hot cathode tube forming the charging or discharging resistor constant. Such electronic time relays therefore require a larger number of electron tubes and a corresponding expenditure on individual electrical parts.

The present invention relates to an electronic timing relay in which in an i? C circuit (Resistance-Capacitor-Circuit) for the measurement of time as a resistance under the influence of radiation standing ionization chamber is used and the switching process when a specified State of charge of the capacitor with the help of a

Applicant:

ELESTA AG _r

Electronic control apparatus,
Bad Ragaz, St. Gallen (Switzerland)

Representative: Dipl.-Ing. A. Wedde, patent attorney,
Munich 27, Schumannstr. 2

Claimed priority:
Switzerland from June 20, 1955

Dr. Hans L. v. Gugelberg, Maienfeld (Switzerland),
has been named as the inventor

Switching element is triggered, which is provided with a control element in the main discharge circuit Gas discharge tube. The invention consists in that the ionization chamber under the Influence of a radioactive radiation source installed in the timing relay is, and mechanically adjustable Means are present with which the amount of radiation penetrating into the ionization chamber can be controlled is made. The radioactive radiation source preferably contains plutonium, radium or actinium and can either be on a swiveling support or also be arranged in a stationary manner, in the latter case between the ionization chamber and the radiation source an adjustable diaphragm is arranged. A very simple and reliable one Execution of the electronic timing relay according to the invention results when the capacitor between the cold cathode and the starter electrode of a glow tube is switched on and one electrode the ionization chamber on the starter electrode and the other electrode of the ionization chamber on the positive Pole of a DC voltage source lies. Which causes the change in charge of the capacitor The ionization chamber is expediently operated in the range of its saturation current.

Embodiments of the invention are shown schematically in the drawing, namely shows

Fig. 1 shows the circuit diagram of one designed for connection to the mains electronic timing relay and

Fig. 2 shows a particular embodiment of the means for controlling the penetrating into the ionization chamber Amount of radiation.

909 558/349

The electronic time relay according to FIG. 1 is connected directly to the terminals 1 by the AC mains fed, using the dry rectifier elements 2, the required DC voltage of about 200 to 300 volts is generated. A capacitor 3 of a few microfarads serves as usual to filter and calm the generated direct voltage. The switch 4 is used for Activating and deactivating the timing relay. For reasons to be explained later, a glow tube 5 provided which, in addition to its anode 6, has a cold cathode 7 and a starter electrode 8. the Anode 6 is an electromechanical via the field winding 9 serving as a current limiting resistor Relay and connected to the positive pole of the rectifier arrangement 2 via the switch 4. The from each other Well-insulated contact pairs 10 and 11 of the electromechanical relay should be de-energized Excitation winding 9 should be open. The excitation winding 9 can have an ohmic resistance of a few have a thousand ohms, so that when the glow tube 5 is ignited, the desired discharge current flows. At the terminals 12 leading to the contact pairs 11 can be the working circuit, which is not illustrated in any more detail which is to be switched after the desired delay time has elapsed. The other pair of contacts 10 is used to connect the capacitor 13 via an ohmic resistor 14 from to discharge a few hundred ohms as soon as the glow tube 5 has ignited. The decisive for the time measurement Capacitor 13, for example, has a capacity of only 10,000 picofarads and is located directly between the cold cathode 7 and the starter electrode 8.

The change in charge on the capacitor 13 is brought about with an ionization chamber, one of which is an electrode 15 is connected to the switch 4 and the other electrode 16 of which is connected to the starter electrode 8. the Electrodes 15, 16 are fixedly arranged in the free atmosphere within the housing of the time relay Metal plates λόπ a few square centimeters of surface area, both from each other as well are electrically well insulated from the housing of the timing relay. Your average plate spacing can be about be between 1 and 5 centimeters. Around the space between the electrodes 15, 16 of the ionization chamber To make it electrically conductive is a radioactive radiation source 17 on an inside the Housing of the timing relay arranged carrier 18 attached. The carrier 18 can be made of metal or insulating material exist, and the radioactive source is best plutonium, radium, or actinium on. These substances emit α-rays (doubly positively charged helium atoms), which in the air of Atmospheric pressure only have a limited range of a few centimeters. Under these circumstances it is possible with simple means, the outgoing from the radiation source 17 and into the room Amount of radiation reaching between the electrodes 15, 16 and thus controllably the electric current flowing between the electrodes 15, 16 do.

In the embodiment shown in FIG. 1, the carrier 18 is rotatable for this purpose Shaft 19 attached so that the radioactive radiation source 17 from the ionization chamber 16,17 more or can be swiveled less far away. Due to the limited range of the α-rays, with increasing distance from the radioactive radiation source 17, the ionization in the space between the electrodes 15.16 weaker, so that the electric current flowing between the plate electrodes 15.16 flows, correspondingly diminished. In the case of the modification shown in FIG. 2, however, the Carrier 18 fixedly arranged; for this purpose, one made of metal or insulating material sits on the rotatable shaft 19 existing cam 20, which the radiation source 17 optionally more or less from the ionization chamber 15, 16 shields. Since α-rays have only a low penetration capacity compared to solid bodies, the cam disk 20 acts as a adjustable aperture, by means of which the amount of radioactive fed into the ionization chamber Decay products is made controllable. With both versions the shaft 19 can also be provided with a scale which is directly in units of the desired Delay time of the time relay can be calibrated.

The achievable delay time, i. H. the period of time after the switch 4 elapses until the glow tube 5 ignites, is now practically independent of without further aids Voltage changes in the feeding AC network. First is the ignition voltage at which from the starter electrode 8 from which the ignition spark jumps to the cathode 7, in the case of a glow tube 5 with cold cathode 7 independent of the potential between cathode 7 and anode 6. But also the weak electric current flowing through the ionization chamber can be independent of Fluctuations in the supply voltage are made when the ionization chamber is operated in the saturation area of its current-voltage characteristic will. For this purpose it is only necessary that the between the plate-shaped electrodes 15. 16 respectively present DC voltage during the entire charging time of the capacitor 13 is always so high remains that the saturation area is not left. Lies between the plate-shaped electrodes 15, 16 and at an average plate spacing of about 1 to 2 centimeters a voltage exceeding about 150 volts, so essentially only the saturation current flows, the size of which is no longer of the above Voltage, but only from the position of the shaft 19 or from the feed set in each case depends on α-rays. If the position of the shaft 19 remains the same, that is between the electrodes 15, 16 the electric current flowing is then constant over time, and the voltage across the capacitor 13 rises proportionally with time. The proportionality factor of this voltage increase therefore depends on a given Radiation source 17 depends only on the respective position of the shaft 19.

It is also possible, through suitable shaping and arrangement of the electrodes 15, 16, the to make existing electric field between them inhomogeneous in such a way that taking into account the properties of the radiation emanating from the radioactive radiation source 17 between The electrical current flowing to the electrodes 15, 16 also largely within certain limits becomes independent of temperature and pressure fluctuations in the atmosphere. Instead of plane-parallel Electrodes 15,1 & can for this purpose be curved electrodes or electrodes set up at an angle to one another be used.

Depending on the yield of the radioactive radiation source 17 can be in the ionization chamber between its electrodes 15, 16 produce electrical currents flowing from 10- ⁷ to 10 ~ ^u amps. Currents

Claims (6)

of this size are able to charge a capacitor of 10,000 picofarads to around 100 VaIt within a time of 101 to 105 seconds. This results in delay times of the electronic timing relay described from a few seconds to over 1 day, and this using an extremely small and cheap capacitor 13. Achieving shorter delay times presents no difficulties, since only a capacitor 13 of correspondingly lower capacity will be used for this purpose . The switching elements decisive for the delay time, on the other hand, must have a suitably large insulation resistance, which, depending on the desired delay time, should be between 1010 and 1014 ohms. This applies in particular to the insulation resistance of the control element 8 of the electron tube 5. If the further requirement is that the electron tube 5 should deliver an electrical power of at least one hundred milliwatts to the relay winding 9, then the specified high insulation resistances can only be achieved with glow discharge tubes which have a cold cathode 7. Tubes with hot cathodes either have too little output power or too high grid currents. The use of only a single glow tube, which is ignited directly from the capacitor 13 without any pre-amplification, has the further advantage that the total current consumption of the time relay is negligibly small during the entire delay time. Patent claims: 1.Electronic time relay, in which in an i? C circuit (resistor-capacitor circuit) For time measurement, an ionization chamber under the influence of radiation is used as a resistance is used and the switching process when a predetermined state of charge of the Capacitor is triggered with the help of a switching element in the main discharge circuit an electron tube provided with a control element, characterized in that the Ionization chamber under the influence of a radioactive radiation source installed in the timing relay and mechanically adjustable means are available with which the in the ionization chamber penetrating amount of radiation is made controllable. 2. Time relay according to claim 1, characterized in that the radioactive radiation source is on an adjustable carrier is arranged. 3. Time relay according to claim 1 and 2, characterized in that between the radioactive radiation source and an adjustable diaphragm is arranged in the ionization chamber. 4. Time relay according to claim 1 to 3, characterized by a plutonium, radium or actinium containing radioactive radiation source. 5. Time relay according to claim 1 to 4, characterized by such a design that the The ionization chamber causing the charge change in the capacitor during the entire delay time is operated in the range of its saturation current. 6. Time relay according to claim 1 to 5, characterized in that the electron tube is a Is a glow discharge tube which, in addition to the anode, has a cold cathode and a starter electrode has, the main discharge circuit of the glow tube via a current limiting resistor is fed by a DC voltage source, the capacitor between the cold cathode and the starter electrode of the glow tube is switched on, and that furthermore an electrode of the Ionization chamber on the starter electrode of the glow tube and the other electrode of the ionization chamber is at the positive pole of the DC voltage source. Considered publications:
German Patent No. 421,954;
U.S. Patent No. 2,700,110;
"Advances in the field of X-rays ¹ ", 1949, pp. 994 to 1002. 1 sheet of drawings © 909 558/349 6.59