DE102022104550B3 - Measuring device and method for determining the fracture point within a scintillator - Google Patents

Abstract

The invention relates to a measuring device for a radiometric measuring device with a scintillator for generating radiation-induced light pulses, a photosensitive element for generating electrical signals based on the light pulses and a control and evaluation unit for evaluating the electrical signals and for determining a measured value. Furthermore, the invention relates to a method for registering and/or locating one or more fracture points within a scintillator of a generic measuring device. In order to achieve an improvement in the measurement accuracy, the measuring device according to the invention has a test pulse transmission unit, which is set up for coupling test pulses into the scintillator, and a test pulse reception unit, which is set up for receiving test pulses which are coupled out of the scintillator, the control and evaluation unit is set up to register and/or localize one or more break points within the scintillator from the intensities of the coupled-in and coupled-out test pulses and/or their time intervals. Furthermore, the invention relates to a method for registering and/or locating one or more fracture points within the scintillator.

Description

The present invention relates to a measuring device for a radiometric measuring device with a scintillator for generating radiation-induced light pulses, a photosensitive element for generating electrical signals based on the light pulses, a control and evaluation unit for evaluating the electrical signals and for determining a measured value, a test pulse transmission unit, arranged to couple test pulses into the scintillator, and a test pulse receiving unit arranged to receive test pulses coupled out of the scintillator.

The invention also relates to a method for registering and locating one or more fracture points within a scintillator or an aging of the scintillator of a generic measuring device, wherein the test pulse transmitter unit couples at least one test pulse into the scintillator and the test pulse receiver unit registers the at least one test pulse decoupled from the scintillator.

From the prior art, in particular from DE 10 2020 113 015 B3 , EP 2 916 112 B1 and EP 2 881 716 B1 various radiometric measuring devices are known which are designed in particular to determine density profiles. Such measuring devices are used in order, for example, to determine a layer distribution of different filling goods, characterized by their density, without contact in a container or a tank.

An example application for this is the detection of different layers in oil production. A mixture of sand, water and crude oil is extracted and collected in a tank. As the sand settles, oil and water separate out in different layers. For further processing, it is necessary to separate the layers from one another and to separate sand and water from the crude oil, which can be done, for example, by draining the tank contents in a lower area of the tank. The key to this process is to only dump water and sand, if possible, and not waste petroleum in this way.

Since the available materials differ in their density, appropriate density measuring devices and density measuring methods are used here.

The radiometric density measurement is characterized in particular by the fact that a measurement is possible independently of the process conditions within a tank and independently of the specific chemical composition of the filling material to be measured. Any corrosive properties do not play a role here, because the necessary measuring devices can be arranged outside the tank.

The underlying measuring principle is shown schematically in 1 shown. A tank 1 is shown in which three layers _2a , _2b and _2c with different densities have been deposited. To determine the density profile, the density-dependent absorption of gamma quanta in different media is used. For this purpose, 3 gamma quanta are emitted by one or more radiation sources through the filling material to be measured in the direction of the measuring device 4 for the detection of the radiation intensity arriving there. Depending on the density of the filling material located between the radiation source 3 and the measuring device 4, more or fewer gamma quanta are absorbed by the filling material, so that the radiation intensity at the location of the measuring device 4 represents a measure of the density of the filling material. The radiation intensity is usually detected with the aid of a so-called scintillation counter, which essentially consists of a scintillator 5 for converting the gamma radiation in the light pulse 8 (flashes of light) and a downstream photosensitive element 6 for generating electrical impulses from the light pulses 8 . The electrical pulses are further processed in a downstream evaluation unit 7, in particular amplified and counted. The number of light pulses 8 determined is representative of the radiation intensity and thus also of the density of the filling material. The fewer light pulses 8 that are determined, the higher the density of the filling material.

Depending on the measuring task and/or the geometry of the tank 1 or the container, the measuring device comprises a large number of radiation sources 3 and/or a large number of measuring devices 4, which are arranged in different ways and appropriately on the tank 1 or the container.

Comparable radiometric measuring devices are also in DE 33 28 256 A1 , DE 10 2017 208 723 A1 and JP H06-186 343 A described.

The accuracy of the radiometric density measurement with a generic measuring device depends in particular on whether the scintillator is free of damage or, on the other hand, has one or more fractures. Radiation-induced light pulses can be scattered, reflected or absorbed at such break points within the scintillator and are therefore not affected by the registration by the photosensitive element sighted. However, this reduces the number of light pulses registered per unit of time, which falsifies the measured value as a result.

Proceeding from this, it is the object of the invention to propose a measuring device and a method with which an improvement in the measurement accuracy and measurement reliability can be achieved.

This object is initially achieved by the measuring device according to claim 1. According to the invention, the control and evaluation unit is set up to register and localize one or more break points within the scintillator from the intensities of the coupled-in and coupled-out test pulses and their time intervals.

Furthermore, the object is achieved by the method according to claim 9. According to the invention, the control and evaluation unit registers and localizes one or more fracture points within the scintillator or an aging of the scintillator from the intensities of the at least one injected and extracted test pulse and their time intervals.

Because the intensities of the coupled-in test pulses can be predetermined and are therefore known, it can be determined from the time profile and/or the intensities of the coupled-out test pulses whether and where there is a break point within the scintillator. Taking into account the position and size of the break point, a decision can be made as to whether the measured value registered can be corrected or whether the scintillator needs to be replaced due to damage. This achieves a significant improvement in the measuring accuracy and reliability of the measuring device.

Advantageous developments of the present invention are explained in the dependent claims and below.

A first advantageous embodiment of the invention provides for the scintillator to be designed in one piece. In a one-piece configuration of the scintillator, it is essentially in the form of a rod, with fractures not infrequently occurring along the entire cross section of the rod-shaped scintillator. Alternatively, the scintillator is composed of a bundle of fibers bonded together to form a generally cylindrical scintillator. With such a scintillator, which is composed of a bundle of fibers, individual fibers can break at different points, which must be taken into account when evaluating the test pulses that are coupled out.

Within the scope of an advantageous development of the invention, it is provided that the test pulse transmission unit is set up to generate an optical test pulse which is coupled into the scintillator immediately or after reflection at a semitransparent mirror. Whether the test pulses are coupled into the scintillator immediately or after reflection on a semi-transparent mirror essentially depends on where the test pulse transmission unit is located within the housing of the measuring device.

According to an advantageous development of the invention, it is provided that the photosensitive element is designed as a photomultiplier. A photomultiplier can be used to detect weak light signals by generating and amplifying an electrical signal, which allows the radiation-induced light pulses to be evaluated and a measured value to be determined. It is preferably provided that the photosensitive element not only registers the radiation-induced light pulses, but that the photosensitive element also forms the test pulse receiving unit, which is designed to receive the optical test pulse. Depending on the positioning of the test pulse transmission unit, the photosensitive element alone can form the test pulse reception unit. Alternatively, the photosensitive element forms a first part of the test pulse receiving unit and at least a second part of the test pulse receiving unit is arranged within the housing at a distance therefrom. The second and every further part of the test pulse receiving unit can also be designed as a photomultiplier.

An advantageous embodiment of the invention provides that the test pulse transmission unit is set up to generate a radar signal or a sound signal instead of an optical test pulse, which is coupled into the scintillator and, after being coupled out, is registered by the test pulse receiving unit. The design of the test pulse transmission unit as an emitter of radar signals or sound signals is advantageous compared to a design as an emitter of optical signals in that decoupled radar or sound signals can be distinguished from the radiation-induced light pulses, which is why the measuring method can also be carried out while the measuring device is in operation. An optical signal can also be used to check for fractures during ongoing measurement operations. The optical signal must be sufficiently distinguishable from the measurement signal, e.g. have a significantly different wavelength, or significantly overdrive a regular scintillator signal, e.g. with a significantly larger amplitude.

A measuring device of the present type is not infrequently used in potentially explosive atmospheres, which is why an advantageous development of the invention provides that the housing of the measuring device is at least partially designed as a flameproof enclosure and therefore has at least partially an Ex d housing.

• 1 eine radiometrische Messeinrichtung nach dem Stand der Technik und
• 2-11 unterschiedliche Ausführungsformen eines Messgerätes für eine radiometrische Messeinrichtung.

Further advantageous refinements and specific embodiments of the present invention are explained below with reference to the figures. Show it:

• 1 a state-of-the-art radiometric measuring device and
• 2-11 different embodiments of a measuring device for a radiometric measuring device.

A first specific embodiment of a measuring device 10 of a radiometric measuring device is in 2 shown. The measuring device 10 has a housing 11 which accommodates a scintillator 12 in a first section 111 . In the illustrated embodiment, the scintillator 12 consists of a bundle of fibers 13, the uppermost fiber shown having a break point 14. Radiation-induced light pulses are generated within the scintillator 12 in the manner already described when the radiometric measuring device is used as intended. A photosensitive element 15 in the form of a photomultiplier 151 and a control and evaluation unit 16, which receives the electrical signals 17 from the photosensitive element, are arranged in a second section 112 of the housing 11. The second 112 section of the housing 11 is designed as an Ex d housing in the exemplary embodiment shown, whereas the first section 111 of the housing 11 is not designed as an Ex d housing. The first section 111 of the housing 11, which accommodates the scintillator 12, can optionally be rigid or flexible. An optical beam splitter 18 with a semi-transparent mirror 19 is arranged between the photosensitive element 15 and the scintillator 12 . A test pulse transmission unit 20 and a first reflection element 22 are arranged on opposite sides of the optical beam splitter 18 . In order to register and/or localize any breakage 14 within the scintillator 12, the test pulse transmitter unit 20 - controlled by the control and evaluation unit 16 - emits an optical test pulse 23 which is reflected on the semi-transparent mirror 19 of the optical beam splitter 18 and in the scintillator 12 couples. The optical test pulse 23 runs through the individual fibers 13 of the scintillator 12 and is reflected both at the break point 14 and at the free end 24 of the scintillator 12, where the scintillator 12 has an optional second reflection element 25 in the exemplary embodiment shown. On its way back, the reflected test pulse 23 reaches the semitransparent mirror 19 of the optical beam splitter 18, where the reflected test pulse 23 is let through to the photosensitive element 15, at least for a known proportion. In the exemplary embodiment shown, the photosensitive element 15 also forms the test pulse receiving unit 21 and converts the optical test pulses 23 into electrical signals 26 which can be evaluated and which are evaluated within the control and evaluation unit 16 . The ratio of the intensities between the emitted test pulse 23 and the registered test pulse 23 as well as their progression over time allows conclusions to be drawn about the size and position of the existing fracture point(s) 14 within the scintillator 12.

Another concrete embodiment of a measuring device is in 3 shown. In contrast to 2 there the scintillator 12 is formed in one piece and thus does not have a plurality of interconnected fibers. However, the in 3 The scintillator 12 shown has a fracture point 14 which extends along the complete cross-section of the scintillator 12 . The test pulse 23 coupled into the scintillator 12 is therefore fully reflected at the break point and therefore does not reach the free end 24 of the scintillator 12 in part. The control and evaluation unit 16 therefore detects a comparatively strong reflection in the area of the break point 14 and can, taking into account from the known length of the scintillator 12 conclude that the scintillator 12 is completely broken at the location shown.

4 shows a further concrete embodiment of a measuring device 10, which is analogous to that in the exemplary embodiment shown 2 has a scintillator 12 composed of several fibers 13, the upper fiber having a break point 14 by way of example. In contrast to 2 the test pulse receiving unit 21 is not formed exclusively by the photosensitive element 15, but the test pulse receiving unit 21 has a second part 212 which is arranged next to the test pulse transmitting unit 20 on the optical beam splitter 18. The second part 212 of the test pulse receiving unit 21 also registers the reflected test signals 23, which are not let through to the photosensitive element 15 at the semitransparent mirror 19, but are instead reflected, which significantly increases the measurement accuracy.

5 shows one to 4 Comparable configuration of a measuring device 10, wherein the second part 212 of the test pulse receiving unit 21 is arranged on the side of the optical beam splitter 18 is, which faces the test pulse transmission unit 20 . The intensity of the test pulses 23, which do not couple into the scintillator 12 at the semi-transparent mirror 19, but instead pass through the semi-transparent mirror 19 in a straight line, is immediately determined in this way. This allows a further estimation of what proportion of the optical test pulses 23 was coupled into the scintillator 12, which further increases the measurement accuracy.

6 shows an embodiment that is a mixture of the embodiments according to FIGS 4 and 5 is. Accordingly, the test pulse receiving unit 21 consists of a total of three parts, namely the photosensitive element 15 as a first part 211 of the test pulse receiving unit 21, a second part 212 of the test pulse receiving unit 21, which is arranged next to the test pulse transmitting unit 20 on the optical beam splitter 18, and a third part 213 of the test pulse receiving unit 21, which is arranged opposite the second part 212 of the test pulse receiving unit 21 on the optical beam splitter 18. This registers the portions of test pulse 23 which, after transmission by test pulse transmission unit 20, do not couple into scintillator 12 and/or are reflected by semitransparent mirror 19 after reflection within scintillator 12 and therefore do not couple directly into photosensitive element 15. The intensity measured on the third part of the test pulse receiving unit 213 must therefore be subtracted from the intensity of the test pulse emitted, because this part of the intensity is not coupled into the scintillator 12 . In this way, the intensity of the test pulses 23, which have completely passed through the scintillator 12, and their progress over time can be precisely determined, registered and evaluated.

7 shows another specific embodiment of a measuring device 10, in which, in contrast to the previous embodiments, an optical window 27 is provided, which is directly connected to the scintillator 12 on one side and to the photosensitive element 15, a second part 212 of the test pulse receiving unit 21 and the test pulse transmission unit 20 is connected. In this embodiment, there are no intensity losses at a semi-transparent mirror of a beam splitter because the test pulses 23 couple directly from the test pulse transmission unit 20 into the scintillator 12 via the optical window 27 . In this respect, the reflected test signal 23 allows a clear evaluation with regard to the size and positioning of any fracture point 14.

8th shows one to 7 comparable configuration of a measuring device 10, the test pulse transmission unit 20 being arranged there at the free end 24 of the scintillator 12, so that the test pulses 23 emitted run through the scintillator 12 to the photosensitive element 15 in only one direction. The emitted test pulse 23 is at least partially reflected at the breaking point 14 and thus does not reach the photosensitive element 15, which results in a difference between the emitted intensity and the registered intensity. The ratio of these intensities allows the size of the fracture point 14 to be estimated, with the fracture point 14 not being able to be positioned in an unambiguous manner using this method. The first section 111 of the housing 11, which accommodates the scintillator 12 and the test pulse transmission unit 20, is designed as an Ex d housing in the exemplary embodiment shown. An optical window 27 is optionally provided as a chamber separation between the scintillator 12 and the photosensitive element 15 .

9 shows an alternative embodiment of a measuring device 10 in which, instead of an optical test pulse, a radar signal 28 is emitted by the test pulse transmission unit 20, which propagates within the scintillator 12 and is reflected both at a break point 14 and at the free end 24 of the scintillator 12. The test pulse receiving unit 21 of the measuring device 10 is set up to receive the radar signal 28 so that the position and/or size of a possible break point 14 results from the course over time and from the intensity of the received radar signal 28 . In the same way, the test pulse transmission unit 20 and the test pulse reception unit 21 can be designed to transmit and receive sound waves, in particular ultrasonic waves. The first section 111 of the housing 11, which accommodates the scintillator 12, does not have to be in the form of an Ex d housing in the illustrated exemplary embodiment.

The embodiment of the measuring device 10 according to 10 shows compared to 9 an alternative positioning of the test pulse transmission and test pulse receiving unit (20, 21), which are directly connected to the photosensitive element 12, specifically on the side facing away from the scintillator 12. The test pulses 28 therefore first pass through the photosensitive element 15, where they couple into the scintillator 12 via an (optional) window.

A final embodiment of a measuring device 10 is in 11 shown after in contrast to 10 the test pulse transmission unit 20 is arranged at the free end 24 of the scintillator 12 . The test pulses 28 emitted there in the form of radar signals 28 pass directly through the scintillator 12 and are registered with the test pulse receiving unit 21, which is arranged at the free end of the photosensitive element 15. The first Section 111 of the housing 11, which accommodates the scintillator 12, is in this case designed as an Ex d housing. In the same way, the test pulse transmission unit 20 and the test signal reception unit 21 can also be designed for transmitting and receiving sound waves, in particular ultrasonic waves, in this exemplary embodiment.

In all embodiments according to 2 until 11 For example, the scintillators shown can consist of a rod-shaped scintillator or a scintillator made up of single or multiple fibers.

Reference List

1

tank

2a,b,c

layers

3

radiation source

4

gauge

5

scintillator

6

photosensitive element

7

evaluation unit

8th

light pulse

10

gauge

11

Housing

111

first section (of the case)

112

second section (of the case)

12

scintillator

13

fiber

14

breaking point

15

photosensitive element

151

photomultiplier

16

Control and evaluation unit

17

electrical signal

18

beam splitter

19

semi-transparent mirror

20

Test pulse transmitter unit

21

test pulse receiving unit

211

first part (of the test pulse receiving unit)

212

second part (of the test pulse receiving unit)

213

third part (of the test pulse receiving unit)

22

first reflective element

23

optical test pulse

24

free end (of the scintillator)

25

second reflective element

26

electrical signal

27

optical window

28

radar signal

Claims (9)

Measuring device (10) for a radiometric measuring device with a scintillator (12) for generating radiation-induced light pulses (8), a photosensitive element (15) for generating electrical signals (26) on the basis of the light pulses (8), a control and evaluation unit ( 16) for evaluating the electrical signals (26) and for determining a measured value, a test pulse transmitter unit (20) which is set up to couple test pulses (23) into the scintillator (12), and a test pulse receiver unit (21) which is designed to receive test pulses (23) which are coupled out of the scintillator (12), characterized in that the control and evaluation unit (16) is set up to select one or more from the intensities of the coupled-in and coupled-out test pulses (23) and their time intervals To register and localize break points (14) within the scintillator (12) and/or aging of the scintillator (12). meter (10) after claim 1 , characterized in that the scintillator (12) is designed in one piece, is formed from a bundle of fibers (13), a combination of fiber bundles and one-piece scintillators or by cascading the aforementioned scintillators. Measuring device (10) according to one of Claims 1 or 2 , characterized in that the test pulse transmission unit (20) is set up to generate an optical test pulse (23) which couples into the scintillator (12) immediately or after reflection at a semitransparent mirror (19). Measuring device (10) according to one of Claims 1 until 3 , characterized in that the photosensitive element (15) is designed as a photomultiplier (151). Measuring device (10) according to one of Claims 1 until 4 , characterized in that the photosensitive element (15) forms the test pulse receiving unit (21) which is designed to receive the optical test pulse (23). Measuring device (10) according to one of Claims 1 until 4 , characterized in that the photo sensitive element (15) forms a first part (211) of the test pulse receiving unit (21) and at least a second part (212) of the test pulse receiving unit (21) is spaced therefrom within the housing (11). Measuring device (10) according to one of Claims 1 or 2 , characterized in that the test pulse transmission unit (20) is set up to generate a radar signal (28) or an ultrasonic signal which is coupled into the scintillator (12) and after decoupling from the test pulse receiving unit (21) is registered. Measuring device (10) according to one of Claims 1 until 7 , characterized in that the housing (11) of the measuring device (10) is designed at least in sections as a pressure-resistant encapsulation. Method for registering and locating one or more fracture points (14) within a scintillator (12) or aging of the scintillator (12) of a measuring device (10) according to one of Claims 1 until 8th , wherein the test pulse transmitter unit (20) couples at least one test pulse (23, 28) into the scintillator (12) and the test pulse receiver unit (21) registers the at least one test pulse (23, 28) decoupled from the scintillator (12), characterized in that the control and evaluation unit (16) registers one or more fracture points (14) within the scintillator (12) or an aging of the scintillator (12) from the intensities of the at least one coupled-in and coupled-out test pulse (23, 28) and their time intervals, and localized.

Images