RU2548048C1 - Scintillation ionising radiation counter - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to counting the number of gamma quanta from different radiation sources in the energy range from hundreds of keV to units of MeV with a load of up to 10⁹ pulses per minute and can be used and can be used for precision detection of intense gamma-ray flux. The scintillation ionising radiation counter comprises a scintillator based on bismuth orthogermanate Bi₄Ge₃O₁₂ (BGO) which is connected through an optical sealant to a silicon photomultiplier, which is connected to a power supply, which is connected to a discriminating amplifier, which is connected to a microcontroller and a frequency divider, which is connected to a microcontroller, which is connected to a personal computer.

EFFECT: designing a miniature device capable of counting gamma quanta of high intensity.

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Description

The invention relates to the field of measuring nuclear radiation, namely, to counting the number of gamma quanta from various radiation sources in the energy range from hundreds of keV to units of MeV with a load of up to 10 ⁹ pulses / min, and can be used for accurate registration of intense gamma radiation flows.

Known scintillation portable counter [Catalog "Radiation monitoring equipment", NLP "Dose", "Progress-G (P)" on the company's website http://www.doza.ru/docs/radiation_control/Progress_G_P.pdf], containing the detection unit , which consists of a scintillator connected to a vacuum photoelectronic multiplier and a power source of up to 3kV. In the detection unit, a detector based on a NaI scintillator (Tl) is used. The control panel consists of a battery pack, a linear amplifier, an amplitude-to-digital converter, a microcontroller and a storage device. The detection unit is connected to a linear amplifier and an amplitude-to-digital converter. The energy ranges of the detected photon radiation are from 2 · 10 ² to 3 · 10 ³ keV. Ranges for measuring the activity of gamma radiation from 8 to 10 ⁶ Bq. Overall dimensions of the components: the length of the detection unit is 230 mm, and 180 mm of the control panel.

The main disadvantages of this counter are: large dimensions; high voltage power supply up to several 1000 V; strong sensitivity to electromagnetic fields.

Known semiconductor counter ["Gamma-ray energy spectrometer semiconductor GAMMA-1P" products of the company "SPC Aspect" http://aspect.dubna.ru/], the main element of which is a germanium-based semiconductor diode. A semiconductor diode with an amplifier in the housing is mounted on the rod and in the working position is installed in the Dewar vessel. The NIM mini-crate control unit consists of a high-voltage power supply, a low-voltage power supply, an amplifier connected to an amplitude-to-digital converter, which is connected to a computer information transfer device. A semiconductor diode is connected to a high-voltage and low-voltage power supply, the signal output of the diode is connected to an NIM mini-rack amplifier.

The semiconductor counter is highly reliable, can operate in magnetic fields, but requires cryogenic cooling to operate, the high-voltage power supply is up to 1000 V and in the working position it is large and weighs up to 600 kg.

Known semiconductor detector ["X-ray and gamma-ray spectrometer X-123CdTe" Amptek product catalog http://www.amptek.com/].

A cadmium-telluride (CdTe) detector was used as a radiation detector.

The detector is mounted on a thermoelectric cooling module together with an input field-effect transistor and connected to a charge-sensitive preamplifier. The NIM minicrate control unit consists of a low-voltage power supply, an amplifier connected to an amplitude-to-digital converter, which is connected to a computer information transfer device. The cadmium-telluride detector is connected to a low-voltage power supply, the signal output of the diode is connected to an NIM mini-rack amplifier. The maximum counting rate is 1 · 10 ⁵ imp / s. Dimensions of the device 7 × 10 × 2.5 cm, weight up to 180 g.

The small thickness of the working area (of the order of hundreds of micrometers) does not allow the use of this semiconductor detector for measuring high-energy particles of more than 150 keV.

Known scintillation detector for detecting ionizing radiation (RU 2088952 C1, IPC6 G01T1 / 20, G01T3 / 06, publ. 08.27.1997), selected as a prototype, which contains a scintillation sensor and an electronic signal processing unit. The scintillation sensor consists of a series-connected scintillation crystal of bismuth orthogermanate Bi ₄ Ge ₃ O ₁₂ sensitive to proton, x-ray, and gamma radiation, and a fiber made of an organic scintillating substance based on stilbene or plastic (CH) n, sensitive to fast neutrons and a photomultiplier. The electronic signal processing unit includes a scheme for temporal selection of scintillation pulses coming into it from both a Bi ₄ Ge ₃ O ₁₂ scintillator (300 ns long) and a fiber scintillating under the influence of fast neutrons (with a scintillation duration of 5-7 ns).

However, this detector contains a vacuum photoelectronic amplifier, requiring a high-voltage power source up to several thousand volts.

This scintillation detector has significant dimensions (length 250 mm, diameter 40 mm) and is sensitive to electromagnetic fields.

The objective of the invention is to develop a miniature device capable of counting gamma quanta of high intensity.

The problem is solved due to the fact that the scintillation counter of ionizing radiation, as in the prototype, contains a scintillator based on bismuth orthogermanate Bi ₄ Ge ₃ O ₁₂ (BGO) and a photoelectronic multiplier.

According to the invention, the scintillator is connected through an optical sealant to a silicon photomultiplier tube, which is connected to a power source connected to an amplifier discriminator, which is connected to a frequency divider and a microcontroller that is connected to a personal computer. The frequency divider is connected to the microcontroller.

Emission of gamma quanta with energies from hundreds of keV to several MeV and intensities of up to 10 ⁹ pulses / min is detected by a scintillator based on bismuth orthogermanate Bi ₄ Ge ₃ O ₁₂ (BGO), the time of emission of a light flash of which at room temperature is 300 ns.

The claimed scintillation counter of ionizing radiation uses a silicon photoelectron multiplier, characterized by a high gain k = 10 ⁶ and quantum efficiency from 15 to 23%, has a compact size of 6 × 6 mm ² , is insensitive to magnetic fields, operates from a low voltage of 30 V has mechanical strength and immunity to external exposure.

The use of a frequency divider in the design of the counter provides a count rate of up to 10 ⁹ pulses / s with an error of no more than 2%.

Compared with the prototype, the proposed device has a miniature size: not more than 5 cm ³ .

In FIG. 1 shows a block diagram of a scintillation counter of ionizing radiation.

In FIG. 2 is a schematic diagram of a power source.

The scintillation counter of ionizing radiation contains a scintillator 1 (C), to which a silicon photoelectron multiplier 3 (PMT) is glued with silicone sealant 2 (SG), which is connected to a power supply 4 (PI), to which the discriminator 5 (UD) is connected. The amplifier discriminator 5 (UD) is connected to the microcontroller 6 (MK) and the frequency divider 7 (DC), which is connected to the microcontroller 6 (MK), which is connected to a personal computer 8 (PC).

The proposed device used a scintillator 1 (C) based on bismuth orthogermanate Bi ₄ Ge ₃ O ₁₂ (BGO) with a radiation length of 1.13 cm and a size of 1 cm ³ .

As a silicon photomultiplier tube 3, you can use a detector supplied by SENSL [Ireland http://www.sensl.com/downloads/ds/DS-MicroFM.pdf], which allows you to receive a signal with a rise time of the pulse front of about 100 ps and time recovery less than 1 ns.

The power supply 4 (PI) contains a generator 9 (G), the output of which through the limiting resistor 10 is connected to the base of the transistor 11, the collector of which is connected to the inductor 12 and the anode of the diode 13. The cathode of the diode 13 is connected to a capacitor 14, the resistance of the divider 15 and limiting the current resistance 16. Resistance 16 is connected to a silicon photomultiplier tube 3 (PMT) and through a capacitor 17 to an amplifier discriminator 5 (UD). A resistance 18 and an inverse input of the comparator 19 are connected to the resistance 15. A divider 20 is connected to a non-inverse input of the comparator 19. The comparator 19 is connected to the generator 9 (G). The inductor 12, the comparator 19, one arm of the divider 20 is connected to a stabilized power supply of +5 V. The emitter of the transistor 11, the capacitor 14, the resistance 18 and the second arm of the divider 20 are grounded.

As the amplifier of discriminator 5 (UD), the classical transistor amplifier circuit is used.

As microcontroller 6 (MK), Atmel controllers can be used [http://www.atmel.com/ru/ru/products/microcontrollers/avr/default.aspx].

As a frequency divider 7 (DF), you can use a decade-long counter assembled on HEF4016BT1 microchips from PHILIPS [http://pdf.datasheetcatalog.com/datasheet/philips/HEF4016BN.pdf].

As the generator 9 (G), the Texas Instrument analog integrated circuit NE555 [http://www.ti.com/lit/ds/symlink/ne555.pdf] can be used.

The device operates as follows.

A scintillation counter of ionizing radiation is placed next to an intense source of gamma quanta or x-rays. Scintillator 1 (C) converts gamma rays into flashes of light lasting less than 300 ns. The flashes of light through a silicone sealant 2 (SG) are supplied to a silicon photomultiplier tube 3 (PMT), which converts them into voltage pulses. Silicon photo-electron multiplier 3 (PMT) is powered by a power source 4 (PI). Rectangular pulses from the generator 9 (G) through the limiting resistor 10 are fed to the base of the transistor 11, the load of which is the inductor 12. When the transistor is suddenly locked in the inductor 12, a large emf of self-induction is induced. The high-voltage pulses thus obtained are fed to a rectifier built on a diode 13 and a capacitor 14. The output voltage is regulated using a comparator 19. Through the resistance of the voltage divider 15 and resistance 18, the output voltage is supplied to the inverting input of the comparator 19 and compared with the reference input, which is input to a non-inverse entrance. By changing the reference voltage with a divider 20, it is possible to adjust the output of the comparator 19 associated with the discharge input of the generator 9 (G). When the output rectified voltage exceeds the threshold value set by the divider 20, a low level is applied to the input of the generator 9 (G) and generation ceases. The rectified voltage decreases, the comparator 19 goes into the state of a logical unit and allows generation. Pulses from a silicon photomultiplier tube 3 (PMT) of 10-20 ns duration through a capacitance 17 are fed to an amplifier discriminator 5 (UD). High amplitude pulses correspond to the detected photons (quanta) of light. Small pulses that arise due to noise in the crystal of a silicon photomultiplier tube 3 (PMT) are cut off by an amplifier discriminator 5 (UD). From the output of the amplifier of discriminator 5 (UD), TTL pulses of 20-30 ns duration are removed and are counted in microcontroller 6 (MK). When the threshold is exceeded 500 thousand imp / s, TTL pulses pass through a frequency divider 7 (DF), are divided by 100, and fed to microcontroller 6 (MK). The counted number of pulses is transmitted to a personal computer 8 (PC).

The proposed device has a miniature size (not more than 5 cm ³ ) and is capable of counting gamma quanta with energies from hundreds of keV to units of MeV with a load of up to 10 ⁹ pulses / min.

Claims (1)

A scintillation counter of ionizing radiation containing a scintillator based on bismuth orthogermanate Bi ₄ Ge ₃ O ₁₂ (BGO) and a photoelectronic multiplier, characterized in that the scintillator is connected via an optical sealant to a silicon photoelectron multiplier, which is connected to a power source connected to an discriminator amplifier, which connected to a microcontroller and a frequency divider, which is connected to a microcontroller that is connected to a personal computer.

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