SE458313B - Measurement instrument for radioactive radiation - Google Patents

Abstract

This device contains a Geiger-Muller tube and supporting electronics to measure and display radioactivity.

Description

DESCRIPTION OF THE INVENTION The object of the present invention is to provide a measuring instrument for radioactive radiation which does not have the disadvantages associated with hitherto known plants. The object has been achieved with a measuring instrument according to the invention comprising a GM tube by means of which radioactivity of a preparation is measured, a holder, by means of which the preparation is brought into close contact with the GM tube, an electronics unit, which is partly connected - part with the GM tube and by means of which the GM tube is kept under voltage for a predetermined time during which a count is made of the number of radioactive particles which penetrate through the window of the GM tube, and which is partly connected to a display, by means of which the measurement result is shown, and contact means, by means of which the electronics unit is controlled, which are actuated by the holder when it is brought into a position where the specimen is in close contact with the measuring window of the GM tube. The measuring instrument according to the invention is characterized in that the electronic unit comprises a memory circuit, in which at least one measured value can be stored.

The holder preferably consists of a slide, which can be pushed into or pulled out of the instrument. The slide has a seat for the preparation to be measured, the seat being on the outside of the instrument when the slide is extended and located immediately next to the measuring window of the GM tube when the slide is inserted into the instrument. In a particular embodiment of the invention, the slide acts on the contact means as it is pushed into the instrument to its internal position, the first contact means starting a first timer, which keeps the instrument under voltage from a current source for a predetermined time, and wherein the second the contact means starts a second timer; which keeps a heart rate monitor activated for another predetermined time. Preferably, the holder or slide acts on the first contact member even when the slide is pulled out of the instrument to its outer position.

The electronics unit comprises a voltage monitoring unit which is partly connected to a current source in the form of an accumulator battery and partly connected to the first timer. The first timer is in turn connected to a voltage stabilization unit. The stabilization unit is partly connected to a high-voltage unit and partly connected to the other timer. The high voltage unit is in turn connected to the GM pipe, which in turn is connected to the heart rate monitor. The second timer is further connected to the same heart rate monitor which in turn is connected to the display.

When measuring the radioactivity of a preparation, the slide is first pulled out of the instrument so that a depression in it is exposed. This position is determined by a stop device which projects from the slide and supports a detail arranged on the base plate of the instrument in the extended position. The preparation is placed in the depression, after which the slide is pushed into the instrument, which is then activated. If the slide has been extended for more than a predetermined time, the first timer is restarted when the slide is inserted at the same time as the second timer is also started. The particles registered by the GM tube are counted using the pulses that the tube emits to the pulse counter and which in turn shows the number of pulses on the display. The use of the measuring instrument according to the invention is characterized in that background radiation from the environment or from contaminated parts of the measuring instrument is measured by causing the holder to assume the measuring position without preparation, that a first measuring procedure is performed in which a first measured value is stored in a memory circuit in the electronics unit. from a specimen is measured by pulling the holder out of the instrument, whereupon the specimen is placed in the holder which is then brought back to the measuring position, a second measurement process is carried out whereby the second measured value is registered in the electronics unit and the first measured value is retrieved from the memory circuit in the electronics unit. from the second measured value and is shown, for example, on - 458 313 10 15 20 25 30 a display.

The slide is guided in its movement by means of two guide strips which are fixedly arranged along the long sides of the bottom plate of the instrument, and by means of a bridge which extends between the guide strips and abuts against their upper side, in which the GM tube is arranged in a circular opening. The stop device which limits the extraction of the slide in its outer position preferably consists of a stop screw which is mounted on the upper side of the slide and which supports against the bridge of the GM pipe, when the slide is in the extended position. By this design, the slide can be completely pulled out of the instrument by first loosening the stop screw. The slide can then be completely decontaminated and reinserted into the instrument.

The invention has provided a measuring instrument which allows the measurement of radioactivity on specimens which in turn represents radioactivity on objects located within a contaminated area without the specimens having to be collected, marked and moved to a measuring plant outside the contaminated the area.

The measuring instrument according to the invention obviates all the disadvantages associated with the known measuring system. The measuring instrument according to the invention also has a simple construction whereby all its parts can be easily decontaminated in any case. The structure of the measuring instrument is shown in the example described below.

DESCRIPTION OF FIGURES The invention is described below in the form of an exemplary embodiment in connection with the accompanying figures.

Figure 1 shows a vertical longitudinal section through the instrument according to the invention.

Figure 2 shows a horizontal section through the instrument according to figure 1.

Figure 3 shows a view of the instrument along the line A-A in Figure 2- Figure 4 shows a cross section of the instrument along the line B-B in Figure 2. Figure 5 shows a block diagram of the functions of the instrument according to the invention.

The instrument according to the example comprises according to figures 1-4 a rectangular base plate 1 whose short sides each have their own ends 2.1, 2.2 which extend perpendicular to the base plate 1. The instrument is further closed with a lid 3 extending above the base plate 1 gables 2.1, 2.2. At one end of the instrument 2.1, a cylindrical Geiger-Müller tube Ä (GM tube) is arranged with its one, windowed end arranged parallel to the bottom plate 1, at a certain distance from and directed towards it. The H-window of the GM pipe consists of a mica foil that is permeable to alpha and beta radiation. Furthermore, the GM tube H has an ionlane chamber, in which, for example, an penetrating photon or a beta particle causes an ignition of an ion avalanche, which is registered as a voltage drop between the GM electrode of the GM tube U and its housing.

The GM tube U communicates with an electronics unit 5, which is only sohematically represented by a dashed line in Figures 1, 3 and H. The electronics unit 5 is described in more detail below in connection with the block diagram shown in Figure 5. The electronics unit 5 is further connected to a power source 6 consisting of a 9V accumulator battery, and to a first microswitch 7.1 and a second microswitch 7.2. The electronics unit is finally connected to a display 8 which has liquid crystals.

A flat slide 9 is arranged slidably along the upper side of the bottom plate 1, between the bottom plate 1 and the GM tube U. The upper side of the slide 9 is then only at a distance of 2 mm from the window of the GM tube A which is directed down towards the top of the slide 9. The slide 9 is displaceable out through an opening in the first end 2.1 of the instrument and has a seat for a preparation in the form of a circular depression 10, which is located immediately below the window of the GM tube H, when the slide 9 is inserted 458 513 10 15 20 25 30 35 instrument, and which is located on the outside of the first end 2.1 when the slide 9 is extended to its outer position from the instrument. The well 10 is intended to contain a preparation whose radioactivity is to be measured.

The opposite end of the slide 9, which is constantly located inside the instrument, has a tongue 11 with a smaller width than the slide 9 which extends in the longitudinal direction of the slide 9. The tongue 11 is intended to be brought into contact with the two above-mentioned microswitches 7.1, 7.2 when the slide 9 is pushed into the instrument, the tongue 11 passing between the microswitches 7.1, 7.2, which are located at the second end 2.2 of the instrument in contact with the bottom plate 1. The slide 9 is guided in its movement by means of two guide strips 12, which are fixedly arranged along the long sides of the base plate 1, and by means of a bridge 13, which extends between the guide strips 12 and abuts against their upper side. The GM pipe H is arranged in the bridge 13. a circular opening in the electronic unit 5, shown in Figure 5, comprises a voltage monitoring unit 5.1 which is partly connected to a first timer 5.2 and partly to a voltage stabilization unit 5.3. The first timer 5.2 is started when the first microswitch 7.1 is actuated by the wear tongue 11. The first timer 5.2 is connected to the accumulator battery 6 and consists of a capacitor which is charged to battery voltage and which is discharged for 8 minutes when it disconnects the power from the battery 6. The voltage stabilization unit 5.3, at a battery voltage of 9.3 - 6, UV gives an output voltage of 5V to a high voltage unit 5.H which keeps the GM pipe H under voltage.

The stabilization unit 5.3 is connected to the second timer 5-5 which is then also started in connection with a second microswitch * 7.2 is actuated by the wear tongue 11. The second timer 5.5 is connected to a pulse counter 5-6 which is also connected to the GM tube H and keeps the counter 5.6 activated for 50 seconds, during which time the counter 5.6 registers all ion avalanches that occur in the GM tube Ä, ie all incidents of alpha and beta particles through the window on the GM tube U from a specimen located in the recess 10 on the slide 9. The counter shows the pulses accumulated for 50 seconds on the display 8.

The first timer 5.2 is started both when pulling out and when inserting the slide 9 into the instrument, by a contact member 1ü on the first microswitch 7.1 being actuated by a cam 15 on the slide tongue 11. The contact ring 14 is unaffected in both tongue 11 extreme positions, ie pushed in or retracted. This means that the instrument is switched on either when the slide 9 has been pushed in or out for more than U minutes and then moved to an opposite end position. The second timer 5.5 is only started when the slide 9 is in a retracted position, whereby the second microswitch 7.2 is switched on.

When measuring the radioactivity of a preparation, the slide 9 is first pulled out of the instrument so that the recess 10 is exposed. This position is determined by a stop screw 16 which projects from the slide 9 and supports the bridge 13 of the GM pipe U in the extended position. The preparation is placed in the recess 10, after which the slide 9 is pushed into the instrument, which can then be activated. If the slide 9 has been extended for more than M minutes, the first timer 5.2 is restarted when the slide 9 is inserted at the same time as the second timer 5.5 is started. The particles registered by the GM tube H are counted by means of the pulses which the tube emits to the pulse counter 5.6 and which in turn show the number of pulses on the display 8.

Claims (6)

458 313 10 15 20 25 30 35 PATENT REQUIREMENTS A method for measuring radioactive radiation using a measuring instrument comprising a GM tube (Ä), by means of which radioactivity of a preparation is measured, a holder (9), by means of which the preparation is brought into close contact with The GM tube (4), an electronics unit (5), which is partly connected to the GM tube (U) and by means of which the GM tube (H) is kept at voltage for a predetermined time during which a count occurs by the number of radioactive particles which penetrate through the window of the GM tube (N), and which are partly connected to a display (8), by means of which the measurement result is shown, and contact means (7), by means of which the electronics unit (5) ), which are actuated by the holder (9) when it is brought into a measuring position where the specimen is in close contact with the measuring window of the GM tube (H), characterized in that background radiation from the environment or from contaminated parts of the measuring instrument is measured by that the holder (9) is caused to assume the measuring position without preparation , that a first measurement process is carried out in which a first measured value is stored in a memory circuit in the electronics unit (5), that the radiation from a preparation is measured by pulling the holder (9) out of the instrument whereupon the preparation is loaded into the holder (9) which is then brought to resume the measuring mode, that a second measurement process is performed, the second measured value being registered in the electronics unit (5) and that the first measured value is retrieved from the memory circuit in the electronics unit (5) and subtracted from the second measured value. A measuring instrument for radioactive radiation comprising a GM tube (U) by means of which the radioactivity of a specimen is measured, a holder (9), by means of which the specimen is brought into close contact with the GM tube (Ä), a electronic unit (5), which is partly connected to the GM tube (U) and by means of which the GM tube (B) is kept at voltage for a predetermined time during which a count is made of the number of radioactive particles penetrating 10 15 20 25 30 35 458 313 through the window of the GM pipe (U), and which is partly connected to a display (8), by means of which the measurement result is shown, and contact means (7), by means of which the electronics unit (5) are controlled, which are actuated by the holder (9) when this is brought into a measuring position where the preparation is in close contact with the measuring window of the GM tube (Ä), characterized in that the electronics unit (5) comprises a memory circuit in which you can store at least one measured value. Measuring instrument according to claim 2, characterized in that the holder (9) consists of a slide, which can be pushed into or pulled out of the instrument, which has a seat (10) for the preparation to be measured, wherein the seat ( 10) is located on the outside of the instrument when the slide is extended and is immediately adjacent to the measuring pipe (U) window when the slide is inserted into the instrument. U. Measuring instrument according to claims 2-3, characterized in that the slide (9) acts on the contact means (7) when it is pushed into the instrument to its internal position, wherein a first contact means (7.1) starts a first timer ( 5.2), which keeps the instrument under voltage from a current source (6) for a predetermined time, and wherein a second contact means (7.2) starts a second timer (5.5), which keeps a pulse counter (5.6) activated during another pre-set designated time. Measuring instrument according to claim H, characterized in that the holder or slide (9) acts on the first contact member (7.1) when the slide (9) is pulled out of the instrument to its outer position. Measuring instrument according to Claim 5, characterized in that the electronics unit (5) comprises a voltage monitoring unit (S.1), which is connected to the first timer (5.2) and to a voltage stabilization unit (5.3). ), that the first timer (S.2) is connected to an accumulator battery (6), that the voltage stabilization unit (5.3) and 458 313 10 15 20 25 30 35 10 are connected to a high voltage supply (5.U) and partly in connection with the second timer (5.5), that the high-voltage unit (5.Ä) is connected to the GM tube (H), which in turn is connected to the pulse counter (5.6), and that the second timer ( 5.5) is connected to the same heart rate monitor (5.6), which in turn is connected to the display (8).