KR20030093839A - Measuring apparatus for broadband gamma radioactive ray and method thereof - Google Patents

Abstract

PURPOSE: An apparatus and a method for measuring a broadband gamma radioactive ray are provided to properly select a sensor adapted for the measurement according to intensity of radioactive ray. CONSTITUTION: A broadband gamma radioactive ray measuring apparatus includes a microprocessor(1) for inspecting a number of pulses per second by receiving a detecting signal so as to output a sensor selection signal. A first signal processing section(2) controls an output of an input control signal according to the sensor selection signal. A low-band sensor(3) is provided to detect a low-band gamma radioactive ray by receiving the input control signal. A second signal processing section(4) is provided to control an output of the input control signal according to the sensor selection signal. A high-band sensor(5) is provided to detect a high-band gamma radioactive ray by receiving the input control signal. Output signals of the low-band sensor(3) and the high-band sensor(5) are amplified by means of an amplifier(8). A sensor driving section(7) selectively drives the low-band sensor(3) or the high-band sensor(5).

Description

Broadband gamma radiation measuring apparatus and method {MEASURING APPARATUS FOR BROADBAND GAMMA RADIOACTIVE RAY AND METHOD THEREOF}

The present invention relates to a wideband gamma radiation measuring apparatus and method, and more particularly, to a wide range gamma radiation measuring apparatus and method for measuring radiation by automatically selecting a suitable sensor according to the intensity of an external radiation source having a plurality of sensors.

In general, the radiation measuring device measured a narrow range of radioactivity using one sensor. Such a radiation measuring device has a limited measurement range, and in order to measure broadband gamma radiation, radiation is measured using a plurality of devices having different measurement ranges.

This was not only an increase in cost, but also inconvenient to carry and use, and in view of this, a device having a large number of sensors having different measuring ranges and capable of measuring broadband gamma radiation in one device by manually selecting a sensor It is developed and uses.

However, such a conventional broadband gamma radiation measuring apparatus has to manually select the sensor according to the intensity range of the radiation source to be measured.

As described above, when the user selects a sensor of the radiation measuring device to measure the gamma ray of the intensity to be measured, there is a problem in that accurate measurement is not possible when the use is cumbersome and an appropriate sensor is not selected.

It is an object of the present invention to provide a broadband gamma radiation measuring apparatus and method in which a sensor suitable for measuring is selected according to the intensity of a radiation source.

1 is a block diagram of a broadband gamma radiation measuring apparatus of the present invention.

2 is a circuit diagram of a first signal processing section in FIG.

3 is a circuit diagram of a second signal processing section in FIG.

4 is a signal processing flowchart of the microprocessor in FIG.

* Description of the symbols for the main parts of the drawings *

1: micro processor 2: first signal processor

3: low-emission sensor 4: second signal processing unit

5: high-coefficient sensor 6: power supply

7: Sensor drive unit 8: Amplifier

9: TTL signal converter

The above object is a plurality of sensors for detecting gamma radiation of different bands, and an amplifier for amplifying the sensing output signal of the sensors; A voltage adjusting unit for adjusting an output value of the amplifying unit to a specific voltage level; The microprocessor is configured to receive the output of the voltage adjusting unit and to control the display of the detection result, and to count the output of the voltage adjusting unit and control one of the plurality of sensors to measure gamma radiation according to the result. Counting the number of pulses in synchronization with an internal clock signal by receiving a detection signal of a sensor currently operating among a plurality of sensors; Operating a sensor having a detection band higher than that of the operated sensor when the number of counted pulses is greater than a first reference value; When the number of counted pulses is smaller than the second reference value, it is achieved by operating a sensor having a lower detection band than the sensor in operation, and measuring gamma radiation. The present invention will be described in detail with reference to the accompanying drawings. Same as

1 is a block diagram of a broadband gamma radiation measuring apparatus according to the present invention. As shown in FIG. 1, a microcontroller receives a detection signal SI and checks the number of pulses per second and outputs sensor selection signals GM_CTR1 and GM_CTR2 according to the result. A processor 1; A first signal processor (2) for controlling the output of the input control signal (IN_CTR1) in accordance with the sensor selection signal (GM_CTR1); A low luminosity sensor (3) for detecting gamma radiation of a low band by receiving the input control signal (IN_CTR1); A second signal processor (4) for controlling the output of the input control signal (IN_CTR2) in accordance with the sensor selection signal (GM_CTR2); A high melody sensor 5 for detecting gamma radiation of a high band by receiving the input control signal IN_CTR2; An amplifier (8) for amplifying the output signal of the low melody sensor (3) or high melody sensor (5); A TTL signal converter 9 for converting an output signal of the amplifier 8 into a TTL signal and outputting a detection signal SI to the microprocessor 1; The sensor driver 7 selects and drives the low-emission sensor 3 or the high-emission sensor 5 according to the detection signal SI of the microprocessor 1.

Hereinafter, the operation and configuration of the present invention configured as described above in more detail.

First, the microprocessor 1 outputs the power control signal PWR_CTR and outputs the sensor selection signal GM_CTR1 and the sensor selection signal GM_CTR2 at low potential.

The first signal processor 2, which has received the low-potential sensor selection signal GM_CTR1 by the operation of the microprocessor 1, outputs the input control signal IN_CTR1 to the low-emission sensor 3.

FIG. 2 is a circuit diagram of the first signal processing unit 2, and as shown therein, the transistor TR1 receiving the low potential sensor selection signal GM_CTR1 through the resistor R1 has a TTL reference voltage EXTVDD. Is conducted by the power supply voltage EXTVDD, and the input control signal IN_CTR1 is applied to the low-emission sensor 3 as the transistor TR2 is conducted. .

FIG. 3 is a circuit diagram of the second signal processing unit 4, and as shown therein, conduction is controlled as the sensor selection signal GM_CTR2 is input through the resistor R3 to convert the input control signal IN_CTR2 into a high linearity. The transistor TR3 is applied to the sensor 5 and controlled.

In the above example, when the low melody sensor 3 is selected, the sensor selection signal GM_CTR2 is applied at a low potential so that the transistor TR3 is turned off, and the input control signal IN_CTR2 is not applied to the high melody sensor 5. Do not.

As described above, the low-emission sensor 3 applied with the input control signal IN_CTR1 is operated by the detection signal SI of the microprocessor 1.

As such, the low-emission sensor 3 applied with the power supply and the input control signal IN_CTR1 detects the gamma rays of the specified band and outputs the result.

Then, the amplifier 8 receiving the sensing result of the low melody sensor 3 amplifies the sensing result to a predetermined voltage level.

Table 1 below shows the state of the sensor selection signal GM_CTR and the input control signal IN_CTR applied to the first and second signal processing units when the low melody sensor 3 is selected.

Item GM_CTR IN_CTR First signal processor L L Second signal processor L H

Table 2 shows the state of the sensor selection signal GM_CTR and the input control signal IN_CTR when the high melody sensor 5 is selected.

Item GM_CTR IN_CTR First signal processor H H Second signal processor H L

The sensing result amplified by the amplifier 8 is applied to the TTL signal converter 9 to be changed to the TTL voltage level, which is in turn applied to the microprocessor 1.

As described above, the microprocessor 1 that receives the detection signal SI of the TTL signal converter 9 checks the number of pulses per second using an internal counter.

At this time, the number of pulses of the detection result of the low melody sensor 3 is 9500 cps or less. In this case, if the number of pulses is 9500 cps, the melody is about 1 cGy / h. If the number of pulses exceeds this, it is determined that the sensing using the low melody sensor 3 is inappropriate.

When the detected result is 9500 cps or more, the microprocessor 1 recognizes that the measurement is outside the measurement range of the low melody sensor 3, and changes the state of the sensor selection signals GM_CTR1 and GM_GTR2.

As shown in Table 2, the sensor selection signals GM_CTR1 and GM_CTR2 are output at low potential to stop the operation of the low melody sensor 3 and operate the high melody sensor 5.

According to the operation of the high melody sensor 5, the sensing result is amplified by the amplifier 8 and applied to the microprocessor 1 via the TTL signal converter 9.

The microprocessor 1 interprets the detection result and displays it on the display screen so that the user can recognize the detection amount.

As described above, the microprocessor 1 continuously counts the pulses of the detection result by using the internal clock. When the high linearity sensor 5 is in operation, the microprocessor 1 detects whether the number of pulses is reduced to 130 cps or less.

At 130 cps, the melody is about 0.3 cGy / h.

When the number of pulses of the detected signal when the high melody sensor 5 is in operation is 130 cps or less, the low melody sensor 3 is selected again to detect radiation.

The time point when the low melody sensor 3 is converted to the high melody sensor 5 and the time when the high melody sensor 5 is converted to the low melody sensor 3 are different from 9500 cps and 130 cps, respectively. In order to allow the equipment to behave like one sensor when the actual equipment is operating, the user cannot recognize whether the sensor is being replaced even though the measured value is updated every second on the display screen.

This is to maintain the precision of the sensor to be automatically replaced so that the detection result does not appear to be changed or malfunctions when the sensor is replaced.

FIG. 4 is a signal processing flowchart of the microprocessor 1, which detects the number of pulses of the detection result as shown in the figure, and sets different standards according to the type of sensor currently being used. Allow the sensor to measure radiation.

That is, when the current sensor is the low melody sensor 3, when the number of pulses exceeds 1 cGy / h, it is changed to the high melody sensor 5, and when the current sensor is the high melody sensor 5, the number of pulses is If less than 0.3 cGy / h to drive the low melody sensor 3 to measure the radiation.

Thus, by automatically selecting the sensor according to the band of radiation, it is possible to improve the ease of use.

In addition, by setting the criteria of the change point of the sensor selection differently, leave the time of conversion so that the measurement results displayed as if using a single sensor when the actual equipment is operating without error.

As described above, the present invention provides a gamma radiation measuring apparatus having a plurality of sensors having different measuring ranges, by automatically selecting and measuring a sensor having a suitable band among the plurality of sensors according to the source intensity of the gamma radiation to be measured. In this case, radiation can be measured using a sensor suitable for measurement without a user's special operation, thereby increasing convenience of use.

In addition, there is an effect of minimizing an error, such as driving one sensor during operation by setting overlapping without setting the same reference value for changing the sensor.

Claims (5)

A plurality of sensors for detecting gamma radiation of different bands, and an amplifier for amplifying sensing output signals of the sensors; A voltage adjusting unit for adjusting an output value of the amplifying unit to a specific voltage level; The microprocessor is configured to receive the output of the voltage adjusting unit and to control the display of the detection result, and to count the output of the voltage adjusting unit and control one of the plurality of sensors to measure gamma radiation according to the result. Broadband gamma radiation measuring device characterized in that. The broadband gamma radiation measuring apparatus of claim 1, further comprising a plurality of signal processing units configured to drive an sensor by applying an input control signal to each of the plurality of sensors according to the sensor detection signal output from the microprocessor. . The broadband gamma radiation measuring apparatus of claim 1, wherein the voltage adjusting unit converts an output of the amplifying unit to a voltage of a TTL (TRANSISTOR TRANSISTOR LOGIC) level. Counting the number of pulses in synchronization with an internal clock signal by receiving a detection signal of a sensor currently operating among a plurality of sensors; Operating a sensor having a higher detection band than a sensor operated when the number of pulses counted is greater than a first reference value; and a sensor having a lower detection band than the sensor operated when the number of counted pulses is smaller than a second reference value; Broadband gamma radiation measuring method for measuring the gamma radiation by operating. The method of claim 4, wherein the first reference value and the second reference value are different values, and an upper limit value is set to be larger than a lower limit value, so that two values overlap each other.