CS231967B2 - Measuring device for determination of the boron concentration or another neutron absorbing substance disolved in water or other liquids - Google Patents

Abstract

Measuring device for concentration determination boron or other neutron absorbing substances, dissolved in water or other liquids, contains at least two parallel planar ones areas that are part of the measuring surfaces vessel, radioactive neutron source, moderator, neutron reflector and detection thermal neutron sensor. Its essence lies in that the neutron radiation source (Fj is stored inside the moderator (L) at its side walls bordering the measuring vessel (M) a is connected to the neutron detector output Electronic signal processing equipment in which it is connected to the neutron detector (D) input of first pulse counter (Szi) whose output is connected to the first gate input (K) whose second input is connected to the output of a time generator (G) to which the input of the second pulse counter is also connected (Szz) whose output is assigned to the third the gate input (K) whose output is connected with the display counter input (Sz3).

Description

(73)

Patent holder BUDAPEST MUSZAKI EGYET, BUDAPEST (MLR) (54 j Measuring device for the determination of boron concentration or other neutron absorbing substance dissolved in water or other liquids

The measuring device for determining the concentration of boron or other neutron absorbing substance dissolved in water or other liquids comprises at least two parallel planar surfaces which are part of the measuring vessel surfaces, a radioactive neutron source, a moderator, a neutron reflector and a thermal neutron detection sensor. Its essence is that the neutron radiation source (Fj is located inside the moderator (L) at its side wall bordering the measuring vessel (M) and connected to the output of the neutron detector is an electronic signal processing device in which it is connected to the neutron detector (D ) connected the input of the first pulse counter (Szi), the output of which is connected to the first gate input (K), whose second input is connected to the output of the time generator (G), to which the input of the second pulse counter (Szz) is output is assigned to the third gate input (K), the output of which is connected to the input of the pointing counter (Sz3).

R D

2319B7

The invention relates to a measuring device for determining the concentration of boron, another neutron absorbing substance dissolved in water or other liquids, having at least two planar parallel surfaces which are part of the surfaces enclosing the measuring vessel, further comprising a radioactive neutron source, moderator, neutron reflector and thermal neutron detection sensor.

Boron has become for its high neutron absorption ability of the isotope ¹⁰ B, which is found in it, reaktoťově-important physical and technical equipment. Therefore, it has become widely used as a control rod material and is used in the form of boron carbide.

In recent years, the importance of boron in nuclear power plants with built-in reactors with pressurized water has increased sharply due to the spread of so-called chemical regulations. In this control method, boron dissolves in the assigned or ¹⁰ B enriched state, in the form of boric acid in the cooling water of the reactor, and the desired reactivity, i.e. binding ability, is ensured by a corresponding change in concentration. The most important advantages of chemical equipment over control rod designs are that the neutron thermal flux is generated more evenly, thereby increasing the geometry, dimensions, and technical limits of power drawn. If used, control rods, control devices are not necessary and the initial reactivity value is increased. As a result of the above, it can be seen that the degree of reactor burnout and the elapsed time between two fuel reloadings can be increased.

It is common ground that, according to the abovementioned implementation of that system, a substantial economic effect is achieved. At the same time, the regulation with bioriic acid made the necessary construction of new dosing, purging and purification plants as well as continuous measurement of boron concentration in the primary circuit of nuclear power plants. Measurement of boron concentration in a conventional manner, for example by titration, is effective in part, rather complex and lengthy, and therefore methods that better fit the target had to be sought.

Research into the continuous measurement of boron concentration of cooling water was started at various places and thus by various methods. Basically, these methods belong to two groups, the chemical group and the isotopic group.

Using chemical methods, the problem can be solved only partially or with great delays, as stated by K. Schneider: Automatische Boranalyse fur Druckwasser Reaktoren, Nuclex 72 CH-4021, Basel, Switzerland. Literature J. E. Bulkowski, W. D. Fletciheir, Ά. G. Qpitz, V. Bajagopal: The Entwicklung eines Borkonzentrationsmessers, Edgiiltiger Bericht, AEC Contract TJ3O-1J 3960, April 1969 basically deals with a measuring device operating on the principle of conductivity measurement. The Schneider Boron Analyzer contains a titration-pH measuring device that operates in the middle of the period, while F & hrmann and Japel describe in the 11th edition of 1967 Keřhenergie in the "Messanordniing für die Úberwachung der Borfsaarekonzentration bei Reaktoren" patented measuring isotope cell. Authors' report. Bulkowski et al. compiled by Westinghouse Electric Co. labs, not only the boric acid concentration meter, which works on the principle of mannitol conductivity, but also the Bajagopala device based on neutron absorption. Of these two facilities, based on operational experience and cost estimates, the Bajagopal facility was considered to be a much more appropriate one.

The results so far can be summed up as a significant research activity in this field of science. However, no equipment suitable for mass production has been completed. Only a device with linear characteristic of boric acid concentrate was developed, but only up to 5 g. Kg per minus the first.

The measurement and control requirements related to nuclear power reactors are in many relations inferior to those unusual at the site of measurement at the measurement site than are common in laboratory-based nuclear measuring equipment or in normal operating conditions.

This finding is valid 1 for boron concentration measuring devices. In order to address the task and the method used, the device must be integrated into the primary reactor cooling circuit. Due to the existing high pressures and high temperatures in the primary circuit, as well as to the strong radioactive radiation, special requirements must be met in particular regarding the vessel containing the liquid to be measured and the detection system. Measuring equipment meeting these requirements shall be as simple and inexpensive as possible.

The aforementioned drawbacks of the prior art are eliminated and the object is solved by a measuring device for determining the concentration of boron or other neutron absorbing substance dissolved in water or other liquids with at least two parallel planar surfaces forming part of the vessel boundary surfaces with a radioactive neutron source. A moderator, a neutron reflector, and a thermal neutron detection sensor according to the invention, characterized in that the neutron source is arranged inside the moderator at its side wall bordering the measuring vessel, and an electronic signal processing device is provided at the output of the neutron detector. with direct linear indication of concentration of measured material. In this signal processing device, an input of a first pulse counter is connected to a signaling device having a neutron detector, the output of which is connected to a first pulse counter.

With her gate entrance. The second gate input is connected to the output of the time generator, to which the input of the second pulse counter is connected, the output of which is connected to the third gate input, the output of which is connected to the input of the pointing counter.

An essential advantage of the device according to the invention is that low intensity neutron sources can be used, the manufacturing cost of the device is low and the dependence between the time required to collect a given number of hits and the boron concentration is linear. Moreover, the dimensions of the proposed arrangement are substantially smaller than those of the known devices. The temperature coefficient of the device according to the invention is also smaller. The invention thus provides an easy-to-use, relatively inexpensive device of dark dimensions.

One example of a particular embodiment of the device according to the invention is shown in the attached drawing, wherein Fig. 1 is a schematic view of the mechanical part of the device and Fig. 2 an electronic part of the device according to the invention.

The substance, i.e. the water or paraffin filling the moderator vessel L moderated by the neutrons of the radioactive neutron source F is in the configuration shown in Fig. 1. Neutrons flowing from the moderator vessel L in the direction of the proportional radiation sensor, i.e. from the neutron detector D are absorbed by boron or other neutron absorbing substances in at least two mutually parallel surfaces contained in the parts surrounding the measuring vessel M.

By appropriately selecting the material and dimensions of the high-pressure vessel M, the moderator vessel L, the reflector R, and the correct selection of the relative arrangement -measure vessel M, the moderator L, the reflector R, the neutron radiation source F -and the neutron detector D is linear between the boron or other neutron absorbing substance dissolved in water and the measurement time necessary to achieve the number of detection interventions N.

Neutron reflection-or R, such as graphite, reflects the neutrons coming through the neutron detector D, thereby increasing the efficiency of the measurement, which in turn allows the use of lower intensity neutron sources, and reduces the risk and production cost of the equipment.

With the above-mentioned measuring device, it has been achieved that the relationship between the time required to collect a given number of interventions N and the horizon concentration appears linear.

Then the time required to collect N pulses in the case of pure water will be indicated by T _o , or the solution time containing the Ci g concentration. kg ^-1 of boric acid Ti and if the difference between these time periods is ΔΤ ₀ , the following equations can be written:

Ti - T _o - ΔΤ "where

K is a constant characterizing the device. From the last relation we can determine T ° and Ti:

τ - AT _O K - 1 if applicable

The first counter Szi counts the signals coming from the neutron detector D and stops the measurement when the prescribed number of pulses is reached. The second set time counter SZ2 and the indicating counter SZ3 read through the gate K the signals from the time base generator G, but only from the time t = T _o , i.e. when the second set time counter Szz gives a signal. The condition for opening the gate K is given by the joint action of the counters Szi, SZ2. Here the device automatically reads the measurement time pertaining to zero boric acid concentration and therefore immediately lacks the value T = T - T _o = B. C, where B is also a constant characteristic of the device.

By corresponding division, T gives the numerical value directly of the C concentration of boric acid. Both the second set time counter SZ2 and the display counter Szi are set using the first counter Szi.

SUBJECT

Claims (2)

Measuring equipment for determining the concentration of boron or other neutron absorbing substance dissolved in water or other liquids, with at least two parallel planar surfaces forming part of the vessel enclosing surfaces, with a radioactive neutron source, a moderator, a neutron reflector and a sensor for detecting heat neutrons, characterized in that the neutron radiation source (EJ) is arranged within the presenter inside the moderator (Lj at its side wall bordering the measuring vessel (Mj), wherein a linear linear electronic signal processing device (E) is connected to the output of the neutron detector (Dj) by indicating the concentration of the measured material, and in this signal processing device (E), an input is connected to a signaling device equipped with a neutron detector (D) 2 31 * 96 7 of the first pulse counter (Szi) whose output is connected to the first input (JK), whose second input is connected to the output of the time generator (G), to which the input of the second pulse counter (Sz2 :) is also connected, whose output is associated with the third gate input (Kj, whose output is connected to the input of the pointing counter (Sz3). 1 sheet of drawings