DE2642064C2 - Density measuring device for flowing media based on the radiation principle - Google Patents

Description

The invention relates to cmc density measuring device for flowing media according to the radiation principle, whereby radiation emanating from a radiation source is divided into several parts by means of a collimation device rays, which the media is split into penetrate representative areas and then be detected.

A y density measuring device is already known (ANCRl 181. Ropes 33 to 40. IW). However, this device uses only one, two or three partial beams and for this purpose a detector with complete electronic measurement processing. Due to the space required by the detectors, did is achievable number of Partial beams are limited and the electronic effort is increased considerably. Furthermore, the wall thicknesses are the media-carrying pipelines in the area of the irradiation due to existing pressures within the pipes are relatively strong (up to a few centimeters), which reduces the gamma radiation used is greatly weakened. In some cases it is also provided that the wall thickness through holes in the To prevent spot of irradiation, however, this can lead to the tubes at high pressures (e.g. 150 ata) take damage.

The task that the device according to the invention has to solve is the spatial resolution for the density distribution and / or the flow shape in the

ίο Measurement cross section of a medium, in particular one Steam-water mixture, by using many partial jets, can be increased significantly without reducing the to increase electronic expenditure.

The solution to this problem can be found in the

.5 the features of the first claim described.

Further developments of the density measuring device according to the invention are given in claims 2 to 6 listed.

The particular advantages of the invention are that serial interrogation of the partial beams is possible is. with extremely thin windows in the wall the pipeline for the media can be worked on. Since the number of partial beams used is significant is higher. the measurement accuracy can be increased significantly. In addition, with density measuring devices, where soft emitters can be used, the effort for radiation protection can be reduced is.

The invention is explained in more detail below with the aid of exemplary embodiments by means of FIGS. 1 to 3 explained. the

F i g. 1 shows a schematic overview of the density measuring device with subsequent electronic measuring chain and an additional partial beam through the collimator for calibration purposes

F i g. 2 shows a section through a special density measuring device and the

I i g. 3 is a plan view of this densitometer.

Fig. I shows schematically the source 1 with her Shielding 2. which on the collimator block 3 with Flow channel 4 and embedded thin sleeve 5 is placed. Below the collimator block 3 there is a perforated diaphragm disk 6, which via an axis 7 of an actuator 8 with motor 9 in rotating movements can be offset. Under the perforated diaphragm disk 6 with passage openings 10 or 11 for the partial beams 12 and 1 3 is the

w Window 14 of a shield 15 for the detector 16. which is formed by a scintillator to the a photomultiplier 17 is connected. Below the Shielding 1 * 5 is an electronic electrode connected, which via lines 18 and 19 with a light barrier 20 for the start of the counter and a Light barrier 21 for the channel identification on the perforated diaphragm disk 6 is fed back.

The gamma radiation emitted by the radioactive nuclide of the gamma source 1 penetrates narrowly in five collimated. A bundle of rays or partial rays 12 distributed over the cross section of the flow channel 4 Two-phase flow and the wall 5 of a pressed-in sleeve. A sixth hole 11 in the collimator 3 leads laterally past the flow channel 4 and has the task of generating a reference beam. While the five channels (there is no upper limit to their number) the gamma ray corresponds to the middle one Density of the flowing two-phase mixture according to

the exponential law is weakened (bend / ug Depending on the number of quanta), the sixth ray 11 is subject only to the changes in the nature of the others Join rays in addition. These changes are not dependent on the density and are made by decreasing the Swelling strength. Drifting of the electronics, changes in the background effect etc. caused.

Through the perforated diaphragm 6 with speed variable Drive 8, 9 are the six gamma rays with defiled times on the one after the other Scintillator 16 released and there generate a number of proportional to the number of gamma quanta Flashes of light, the strength of which is a function of the energy of the gamma quanta. Of course, this also applies for similar types of radiation, such as neutron radiation. The photomultiplier 17 converts the flashes of light into a number of voltage pulses proportional to the number around. their amplitude size in turn depends on the light intensity and thus on the gamma energy is determined. Since the amplitude level also depends on the temperature of the scintillator 16 and on the supply voltage of the photomultiplier 17 depends strongly, a regulation of the supply voltage is called Amplitude stabilization. intended.

The spectrum of the electrical impulses after the photomultiplier 17, ie the number of impulses plotted against the energy (impulse height), begins in the low-energy range with a large value, which is formed by the scattered gamma quanta, the so-called Comptonl background, and the electrical noise. This is followed by the knergy peaks of the gamma radiation emitted by the radiator 1 and the x-ray and braking radiation generated by secondary processes. For amplitude stabilization, a two-window discriminator 22 is applied to the gamma peak selected for the measurements. the z. B. is at 84 keV for a Tm-170 source. The impulses / are plotted against the energy £. They pass / window discriminator 22 to 23 via the pulse amplifier For the measurements, a window 25 and 26 respectively below _and above the energy peak nd bit 24 is set a little, so that both in the equilibrium case, the same lmpu! S / AHL / receive. If the equilibrium is detuned, ie if there are different numbers of pulses / both window discriminators 27 and 28 due to the shifting of the energy peak 24, the differential analog signal circuit 30 and the regulator auxiliary voltage generator 31 generate an analog signal which the supply voltage of the multiplier 17 readjusts and brings the energy peak 24 back into the symmetrical position. By means of a corresponding window width and a small distance between the two windows 25, 26 it can be achieved that the sum of the impulses which are allowed through by both windows 25 and 26 corresponds to the measuring rate of monoenergetic gamma quanta. to be used for density measurement is proportional.

An “and or” link 32 is therefore used these pulses to a second branch via a monovibrator 33 and a coaster 34 for digital Processing supplied = after the reduction, they are counted and stored in a scaler * timer 35. The start of the counting time is triggered by the signal from a light barrier 20 of the perforated diaphragm disk 6. It is connected to the scaler timer 35 via the time selector 36. At the same time the timer 35 is started, the The counting process is ended after the preselected time (10 ms to 1 second) has elapsed. The counting time must be

within the opening line of a hole tO or 11 of the Orifice disk 6 lie, which happens by coordinating the molar speed and the counting time setting. The digital value (number of pulses) is transferred to a buffer memory before the start of counting the next channel to be called up from there to tape storage or computer 37. Between the computer 37 and the Scaler timer 35 is a display control device 38 with which the second light barrier 21 for the Channel identification is connected.

The computer 37 can use calibration values and, after correction, the value of the reference radiator (see partial beam 13) from the five gamma pulse values a cross-sectional density determination must be carried out each time. The shortest measuring time for the whole The cross section of the flow channel 4 is approximately 50 ms.

Figures 2 and 3 show an embodiment for the determination of the mean density of a multiphase mixture with the Gamma-Stiahl attenuation method (the reference numerals correspond to those of FIG. I). The device is special. suitable for the Use in the sector security for: jbving. because for them Determination of the mass flow of a water-steam mixture flowing out of a defective reactor circuit knowledge of the local density is required. Because of the harsh conditions with respect to the. Pressure (up to and over 150 ata) that Temperature (from c ;;. 350'C) and the required speed for this task has the gamma Density determination proved to be favorable. However, provisions with other types of radiation are not excluded.

In FIG. 2, the collimator block 3 is shown in section. It consists of arm-resistant steel and is clamped between two flanges 41 and 42 (see also f; g. I) by two clamping devices 39 and 40. A pressed-in thin-walled sleeve 5 of approx. mm wall thickness, which is welded at the ends to the collimator block 3 (the sleeve stands on the plane of the drawing; the welded-in points are not shown), assumes the pressure-resistant sealing of the kilimator bores 12 against the flow medium 4. This results in extremely thin radiation windows 4 } and 44 reached at the points of contact de ^r partial bores 12 before and after the irradiation. The through hole 13 is not available in this embodiment.

A cover disk 45 is screwed onto the Kolhmatorblock 3, on which in turn the shielding 2 for the radiation source 1 is screwed. The shield 2 also consists of a block made of steel or tungsten, which has an inner bore 46, in which the radiation source 1 is inserted in a sleeve with a pinching device 47. The shield 2 itself can be cooled with water via a spiral channel 48 and water inlets and outlets 49 (see F1 g. I).

At the lower end 50 of the bore 46 for the source 1, a slide 51 is conical in the shield 2 executed line bore 52 inserted so as to be transvertable, With it, the strength of the source 1 be calibrated. The conical bore 52 corresponds with a bore 53 in the cover plate 45 and another recess 54 in the collimator block 3, from which the inlet openings 55 of the partial beam bores 12 go out.

The outlet openings 56 of the partial jet bores 12 at the lower end of the collimator block 3 are the

ßlendenscheibe 6 opposite. This window washer 6 has a blciring 57. in which the individual through openings 10 (there is only one through opening drawn in solid lines: the others are drawn in with dashed lines) are inserted. The windshield is via the axis 7 (see also the schematic drawing according to FIG. I) by means of the cable gear 8 and the engine 9 driven. The holder 58 for the axis 7 is flanged directly to the collimator block 3. It is via the inlet and outlet lines 59 and 60 can also be cooled with water.

The window 14 is located below the aperture pane 6 and in particular below the shielding ring 57 the shield 15 for the scintillator 16 with Photomiilliplicr 17 arranged. The scintillator axis 61 is almost perpendicular to the radiation directions 62 of the individual partial beams 12, the common point of intersection of the partial radiation directions 62 lies in the source 1. Between the actual scintillator 16 and the shield 15 is a water cooling 63 or a water cooling jacket, which in the Scintillator 16 dissipates heat penetrating from the outside.

In Fi g. 3 is a plan view of the Dichicmeßvorrichtung shown in Fig.2. The collimator block 3 or the cover plate 45, the flanges 41, 42 with the brackets 39 and 40, the shield 2 with cooling inlets and outlets 49 as well as the holder 47 for the source, the holder 58 for the axis 7 of the aperture plate 6 are visible The actuating gear 8 and the motor 9. In the diaphragm disk 6 or the lead ring 57, the recesses 10 with offset angles are inserted on different radii. The number of ·, recesses 10 depends on the number of partial beams 12 (see Fig. 2), the periphery of the orifice plate 6 and the dimensions of the openings 10. It is quite possible that a plurality of recesses 10 are arranged on a circular circumference

ίο can. On the outer casing 64 of the window pane 6 switching holes 65, 66 are inserted, which are for the Photozcllen Stcucning with the light barriers 20 and 21 (see Fig. I) are used.

With the help of the scintillation detector 16 and connected electronics according to Fig. I can determine the intensity of the respective gamma ray or Tcilstrahls 12 can be measured in the millisecond range. From the intensity of the respective gamma ray can on the density of the mixture 4 (see Fig. I and 2)

getting closed. With a homogeneous distribution of the Phases above the cross-section can be used to deduce the mean cross-sectional density. at hichlhomogeneous distribution, and that is with reactor safety experiments the rule is that several gamma rays are required to achieve a usable level of accuracy 12, distributed over the cross section of the sleeve 5, is required.

For this purpose 3 sheets of drawings

Claims (5)

Patent claims: 1. Density measuring device for flowing media according to the radiation principle, with radiation emanating from a radiation source by means of a Collimator device is divided into several sub-frames, which represent the media in Penetrate areas and are then detected, characterized in that the Collimator device (3, 12) itself as media glue (4, 5) is designed that a single detector (16) is provided for the detection of the partial beams (12) is, and that between the detector (16) and the exit points (56) of the partial beams (12) from the Collimator device (3) a time-controllable shutter arrangement (6, 10, 57) of the exit points (56) is attached. 2. Density measuring device according to claim 1, characterized in that in the collimator device (3) a through hole (4) perpendicular to the plane of the partial beams (12) is inserted is. which a thin-walled, the Durchinttsbohrun gene (12) for the partial radiation sealing sleeve (5) receives. 3. Density measuring device according to claim I and 2. characterized in that the detector (16) transversely to the direction of incidence of the partial beams (J2) in one Shield (15) is located, which has an opening (14) in front of which the closure arrangement (6, 10, 57) is movably arranged. 4. Density measuring device according to claim 1 or one of the "oigenden. Characterized in that the shutter arrangement (6, 10, 57) is a movable diaphragm disk (6) with slits (10). whose Dimensions are determined by the cross-sections of the partial beams (12) and the measuring time. 5. Density measuring device according to claim 4, characterized in that the diaphragm disc (6) can be rolled by means of a motor drive (8, 9) and the slots (10) lie on different radii. b. Density measuring device according to one of claims I to 5, characterized in that the collimator device (3) has an additional. ^A he media line has never penetrating, but directed towards the detector (16) through hole (13).