CH647603A5 - Device for measuring an ionising radiation with a connectable measuring probe - Google Patents

Description

The invention is based on a device to set the normalized position determined in the preamble and this type of measurement for measuring a supply curve with a second setting, which is based on the ionizing radiation. Such a measuring device for measuring closed measuring probes in a one-time process, which is independent of the setting of ionizing radiation, is known, for example, from the process of DE-PS 11 98 462, which is independent of the transmission characteristic. This known measuring device is removed to such an extent that the scatter holds a radiation fed from a high-voltage source of the characteristic curve of the radiation detector in the probe, which is compensated for under the action of an ionizing one. In this way, all Messson radiation can generate a radiation dose corresponding to the dose rate of radiation with that of the same transmission pulse rate. In addition, the known radiation characteristic curve can be exchanged with one another, without an lung measuring device, to which a measuring device, which means that significant measuring errors occur in the display of the measuring probe with a further radiation detector.

can be. The dependent claims contain premature detectors of the measuring probe or of the measuring device for the measuring arrangements of the invention. Be selected with the measures of the claim. Both radiation detectors are avoided in ches 2 that the radiation measuring device in a known measuring device at the input of a measuring probe that is not connected as a monostatic sensor indicates a measured value that the pulse flip-flop arrangement designed as a flip-flop circuit is actually not available. Due to the measure of being connected, a smaller number of contacts is required for the different capacitance values in the by means of a range switch in which the time constant of the closing device. The measures of the RC circuit determining the toggle circuit claim 4 allow in particular the setting of a north. The pulse shaper arrangement is followed by a rate-measured transmission characteristic of the radiation measuring device arrangement, which results from an integration even when setting several measuring ranges. Claim 5

3,647,603

indicates an advantageous method for adapting a radiation measuring device 1 shown. The lower

probe to a radiation measuring device to which it is connected the right axis in this diagram is in itself the abscissa and is. contains the pulse rate at input 4 of the radiation measuring device

The invention is described below with the aid of some embodiments 1 in the same representation as the ordinate of the characteristic

tion examples explained in more detail, the diagram in the drawing of FIG. 2a of the measuring probes. The horizontal

represents are. The axis of the drawing in this diagram is the ordinate and contains in

1 shows a radiation measuring device with a connected logarithmic division, the display values on the scale NEN measuring probe for measuring ionizing radiation in 27 of the display device 22 of the radiation measuring device, which is a schematic representation, for example in the dose rate units Roentgen pro

FIG. 2a the diagram of the characteristic curves of measuring probes is calibrated for 10 hours (R / h). The position of the transmission characteristic with radiation detectors of the same type, 26 is, in itself, different from the electrical values of the electrical components used in the radiation FIG. 2b, the diagram of the transmission measuring device shown next to it, the transmission characteristic of a radiation measuring device, the transmission of which can be carried out and by an adjustable resistor 28 , characteristic curve to a radiation detector with an identifier which is fed from a direct voltage source 29, so that the line is matched according to FIG. 2a, 15 are changed so that in the corresponding FIG. 3 a radiation measuring device shown in FIG Diagrams in FIG. 2a and FIG. 2b come into the same circuit as a setting for the normalized position, like nominal characteristic curve 23 in the characteristic curve * characteristic curve, in FIG. 2a. To set this normal position in FIG. 4, another radiation measuring device with a transmission characteristic curve 26 of the radiation measuring device 1 is closed, switchable measuring probe for measuring a 20 to the input of the radiation measuring device between the anionizing radiation in a partially more detailed final contacts 2 and 4, a pulse generator 30 connected. Circuit representation. The radiation measuring device 1 shown in FIG. 1 is connected via a parallel resistor 19/20 to the integration capacitor 17, the contacts 2 to 5 of a plug-in device of a measuring probe, a fixed resistor 31 with a certain radiation detector 7 for all rays 6 . The anode of the 25 measurement device has the same resistance value to the connection radiation detector 7, to which is connected under the action of a contact 2 and 3, as shown in FIG. 3. ionizing radiation on the radiation detector at a rate The pulse generator occurs at a pulse frequency f0 at the time, statistically distributed pulses occur, is above the position, which is an equal-sized pulse rate IR0 on the still loga-resistors 8 and 9 and the connection contact 5 with a rithmically linear part of the nominal characteristic curve 23 is replaced and a high voltage source 10 is connected, while the cathode dose rate x0 corresponds to one of the radiation detector acting on the measuring probe via the connection contact 2 on the ionizing radiation field. Then the reference potential of the radiation measuring device is used to adjust the adjustable resistor 28 to adjust the current-time value. The pulses generated in the radiation detector 7 reach the surface of the output pulse 15 of the pulse shaper arrangement via a capacitor 11 of the measuring probe and connector 13, modified until, for example, the pointer 32 of the contact 4 to a pulse amplifier 12, at the output 35 of which a pointer device 22 detects the dose rate x0 indicate a pulse shaper assembly 13 is connected. This faces the mark 33 on the scale 27. This converts the input pulses 14 into output pulses 15. The same process in the diagram in FIG. 2b is converted by the thick, constant current-time area, the display line 35 drawn into a frequency line 34 drawn out of the pulse shaper and the associated thick-out arrangement of the rate meter arrangement 16 illustrated.

The latter contains an integration capacitor 17 with a resistor 40. The measuring probe 6 also contains an adjustable resistor 36 between the an-nem series resistor 18 and an adjustable resistor 36 formed as a voltage divider with closing contacts 2 and 3, the resistors 19 and 20 in the measuring device 1 connected state of the stand. The output pulses 15 of the pulse shaper arrangement measuring probe 6 (FIG. 1) parallel to the base-side counter-13 form on the integration capacitor 17 a voltage 20 proportional to the pulse rate component of the divided parallel resistor 19/20 to the output pulse 15, which is arranged by an integration capacitor 17 and the like It is amplified by means of a DC voltage amplifier 21 and has a resistance resistance value approximately equal to the resistance value, for example in display power units calibrated in dose rate units. By adjusting the adjustable direction 22 is displayed. Ren resistor 36 can the voltage divider ratio

In the diagram in FIG. 2a, characteristic curves of the same type of rate meter arrangement 16 are changed, as a result of which the position of radiation detectors 7 in different measuring probes 6 50 <of the standardized transmission characteristic curve 26 of the radiation is shown, the characteristic curve 23 changing the mean or nominal measuring device. In an ionizing beam characteristic of the similar radiation detectors 7 and the dose field x0, for example, the setting characteristics 24 and 25, for example characteristics of resistance 36 of the probe, are changed until the display radiation detectors are in each case on the outer edge of the device 22 are in the standardized radiation measuring device 1, at the approved manufacturing stray field. The abscissa ss that the probe 6 is connected, the value x0 of the dose line contains the dose rate DL stung in a logarithmic division. Thus, the resistance value of the adjustable R / h of an ionizing resistor 36 acting on the measuring probe in the probe is unambiguous and unique to radiation, the ordinate the associated pulse rate occurring at pulse output 4, the characteristic curve of the radiation detector contained in the probe and the measuring probe also occurring coordinated in a jogator 7 in such a way that, for example, the rithmic division. From the diagram it can be seen that resistor 36 for a probe with the characteristic curve 24 adjusts the various transmission characteristic curve 26 of the measuring device 1 connected to a radiation measuring device 1 to 37 ne similar measuring probes 6 as a result of the scattering of the characteristic curve or the setting of the resistor 36 another radiation detector 7 used therein in an ionic probe with the characteristic curve 25 sets the transmission field 26 transmitting radiation characteristic 26 with the dose rate X] below the radiation measuring device 1 into position 38. In this way generate different pulse rates yi, y2 or y3, which generate considerably different ways the different pulse rates can be different and thus lead to considerable false readings in the radiation measuring probe in the same radiation field of an ionizing device. The radiation again has approximately the same display value x'j in FIG. 2b is the transmission characteristic curve 26 of the radiation measuring device 1 in FIG

647 603 4

Different pulse rates yl5 y2, y3 in FIGS. 2a and ters 57 can be used to input the monostable multivibrator 60

2b is indicated. via a separating capacitor 79 optionally to the output

FIG. 4 shows a further radiation measuring device 42 with one measuring probe 43 or the output of the pulse amplifier 59 and a measuring probe 43 connected to it, which are connected to the radiation detector built into the radiation measuring device with the working resistors 45 5 detector 53 . At the exit of Mo and 46 contains. The measuring probe is connected to the measuring device via connection contacts 47 nostable flip-flop 60, a ratemeter arrangement up to 51 of a connection device, which consists of an integration capacitor 80, one. The pulse rate generated in the radiation detector 44 under the action of longitudinal resistance 81 and the internal resistance of an indication of ionizing radiation will exist as a parallel resistance. The measuring range of the beam can be reached via the connection contact 48 at the input of the lung measuring device in, for example, three display areas on the radiation measuring device by means of the and a range selection switch 65 amplified in the measuring probe in a pulse amplifier 52. The latter contains shared in its housing, each display area through the built-in radiation detector 53, which also has selectable capacitors 66 to 68 and adjusting resistors, working resistors 54 and 55 and the contacts 56 of a son 72 to 74 have their own current-time area of the output pulses 57 is assigned to a voltage supply arrangement 15 of the monostable multivibrator. Connected to the ones with voltage 58 of the radiation measuring device and the level 71 of the range selector switch 65 selectable ones under the action of ionizing radiation resistances for each area, the normal position can also be generated by a pulse amplifier 59 (for example 26 in FIG. 2b) Transmission characteristic of the beam is amplified. The pulse shaping arrangement of the radiation measuring device can be set. With the beam measuring device 42, a monostable multivibrator 60 with the 20 lungs detector 44 in the measuring probe 43 associated with the setting transistors 61 and 62, the load resistors 63 and 64 resistor 76 and that in the radiation detector 53 in the beam and an RC time switch A setting resistor 77 assigned to a range selector 65, measuring device is the one that can be selected by shifting the transmission characteristic of the radiation capacitor 66 to 68 and a resistor 69 by a level 70 of the range selector. The measuring device also contains three of a second level by a corresponding change in the measuring device 25 current-time area of the output pulses of the monostable 71 of the range selector switch 65 selectable toggle switch to compensate for the deviation of the levels 72 to 74, at their common connection point two characteristic of the radiation detector connected to the measurement, the radiation detectors 44 and 53 assigned to Characteristic curve 23 (FIG. 2a) which can be selected by the nominal detector value by means of the contacts 75 of the probe switch 57 is set on the device or a probe. So that the setting resistors 76 and 77 are connected. The radiation detector assigned to the 30 of the adjusting resistor 76 in the measuring probe 43 is assigned to the radiation detector 44 assigned to the radiation detector 44 in the measuring probe 43, and the measuring variable resistor 76 is arranged in the measuring probe and is connected to the radiation measuring device without an additional connection to the radiation measuring device by means of appropriately designed radiation measuring devices considerable measuring errors can be exchanged. 42 connected. With contacts 78 of the probe selection switch

C.

2 sheets of drawings

Claims (5)

647603 2 PATENT CLAIMS capacitor with a series and a parallel resistor 1. Device for measuring ionizing radiation. By means of the range switch, different time-constant measuring probes can be set in the ratio one of the known device via a connection device to the device, which at least one is constantly set under the influence. A display instrument is arranged in the parallel branch of the integration of ionizing radiation from a capacitor which reduces the dose rate, and contains the output voltage of the generator corresponding to the radiation pulse generating electrical pulse rate which corresponds to the dose rate, furthermore displays and indicates the pulse generator arrangement and its meter Scales in dose rate units according to the pulse rate integrating rate meter arrangement, which are calibrated. The monostable multivibrator of the known RC circuit device, which determines a time constant, contains an adjustable resistor, with which, characterized in that an adjustable resistor (36, 76) in the measuring probe (6, io measurement deviations from the desired value to be displayed is compensated). is arranged, which are caused by characteristic curve spreading of the active component of the RC circuit of the pulse shaper arrangement, electronic components of the pulse shaper arrangement (13, 60) or part of the RC circuit of the ratemeter and, in particular, the radiation detector of the device (16) and through contacts (2,3,49,50) of the matter. is connected to this RC circuit. 15 However, in the known radiation measuring device 2. Device according to claim 1, characterized in that the measurement errors are not compensated for by the scattering of the characteristic curve of the connecting device contained in the measuring probes of the connecting device to which the adjustable between the contacts (2,3,49, 50) Resistance radiation detector occur. These scatterings are considerable- (36.76) connected in the measuring probe (6.43), are fixed and cause deviations of more than 30% from the actual state (20.69). 20 measured values to be displayed. To narrow this down 3. Device according to claim 1 or 2, characterized in scattering width, it is known, parallel to the radiation detector, that one of the contacts (2,50) of the connecting devices to arrange small adjustable capacitors, such as this, to which the adjustable resistance ( 36.76) the measuring probe is also connected to the measuring probe de (6.43) shown in DE-PS 11 98 462, with one pole indicating the measuring probe. This indeed succeeds in reducing the supply voltage source (10, 58) connected. 25 spread in the range of the dead time of the radiation detector; 4. Device according to one of the preceding claims, however, it is characterized by a substantial extension of this by the fact that one of the RC circuits in the dead time area buys what a narrowing of the measuring range advises at least one further adjustable resistor (28, ches This measure is also not sufficient for the 72 ...) to set the compensation of the measurement error of accuracy requirements of such radiation devices without taking into account the spread of characteristic curves 30 measurement devices. which contains radiation detectors (7,44,53). The invention is therefore based on the object 5. A method for operating the device according to one of the pre-radiation measuring device of the claims appended in the preamble of claim 1, characterized in that for the given type with a measuring probe connected thereto, the measuring probe (6, 43) is calibrated in a radiation field in such a way that the scatter of the characteristic curve of the radiation of an ionizing radiation of a known dose or 35 detectors is compensated for in the individual measuring probes, dose rate (Xo) is arranged which can be logarithmically II and thereby the measurement value of a part of the characteristic curve (23, 24.25) of the radiation detector does not send ionizing radiation or lies only slightly (7.44) to the measuring probe, and that the resistance value of the is falsified. adjustable resistance (36, 76) in the measuring probe as long as this object is changed according to the invention by the im until a display device (22) of the device - »o characterizing part of claim 1 produces an output that corresponds to the numerical value of the known technical measures solved. With this measure, the dose or dose rate or with this numerical value the compensation for the scattering of the representative marking (33) of a display field (27) of the characteristic curve of the radiation detectors is advantageously matched by a compensation of the display device. Scattering of the other circuit elements of the radiation «Measuring device separated. This makes it possible to characteristic curve of a radiation measuring device independent of a radiation detector used for measurement in a