FR2493994A1 - DEVICE FOR MEASURING NEUTRONIC FLOW IN A NUCLEAR REACTOR - Google Patents

Abstract

The invention relates to a device for measuring the neutron flux in a nuclear reactor. The device contains an emission electrode (1), a collector electrode (2) and a unit for measuring the electron current between these two electrodes. The emission electrode (1) consists of an arrangement of coaxial tube elements (4) which are permanently connected at one of their ends to a disc (5) which is perpendicular to the common axis of the tube elements (4). The collector electrode (2) consists of an arrangement of coaxial tube elements (8) which are arranged between two consecutive tube elements (4) of the emission electrode (1) and are permanently connected to an outer closed housing (10) which completely surrounds the emission electrode (1). A very long tube (6), which is coaxial with the tube elements (4 and 8), crosses the housing (10) without touching it electrically and includes the centre part of the emission electrode (1). The invention is used, in particular, in measuring the neutron flux in the reactor core of a pressurised water reactor.

Description

 The invention relates to a device for measuring neutron flux in a nuclear reactor.

 There are known neutron flux measuring devices of the self-powered neutron detector type also called "collectrons", comprising an emitting electrode made of neutron absorbing material producing electrons under the effect of neutron bombardment and / or radiation <as well as '' a collecting electrode transparent to neutrons or weakly absorbing neutrons which collects the electrons emitted by the emitting electrode.

 Between these two electrodes, there is a means of measuring the electric current which makes it possible to carry out an indirect measurement of the neutron flux, by measuring the current of electrons flowing between the emitting electrode and the collecting electrode.

 These detectors or collectrons are generally constituted by a metallic outer shell permeable to neutrons serving as a collecting electrode and by a central emitting electrode made of a material capable of emitting 0 radiation (or conversion electrons by absorption of g radiation), by disintegration of the activation products created by the absorption of neutrons.

 The means for measuring the electron current between the two electrodes is generally a micro-ammeter interposed on a measurement circuit arranged between the two electrodes.

 Depending on the nature of the material constituting the emitter, we can deal with instant type collectrons or with delay type collectrons.

 In the case of instant type collectrons, the emitted electrodes are made of a material such as cobalt or cadmium whereas in the case of delay collectors, the electrodes are made of a material such as platinum, vanadium, rhodium or silver.

Instantaneous collectrons have a very short response time (less than a second) and are mainly used for neutron flux measurements carried out as part of security checks. These detectors do not have a high accuracy, so we use collars
Delay type lectrons when we want to make neutron flux plots requiring measurements of good accuracy. The delay type collectrons have a response time of the order of one minute.

 Various improvements have been proposed to extend the possibilities of applying collectrons, in particular instantaneous collectrons.

For example, it has been proposed in French patent 2,236,192 to surround the emitting electrode with a platinum sheath, which makes it possible to eliminate radiation with low energy and consequently increase the accuracy of the measurement.
It has also been proposed, in French patent 2,175,325, to use an elongated tubular emitting electrode associated with several separate elements constituting the collecting electrode and distributed along the length of the emitting electrode.

 Such a device improves the accuracy of the measurement of the axial power distribution in the core of a nuclear reactor.

 These devices do not, however, make it possible to significantly improve the sensitivity and the accuracy of the measurement, unless a large bulk is accepted, which is not possible in the case of neutron flux measurements in the reactor core since the measurement devices are introduced into the instrumentation guide tubes of the assemblies constituting the reactor core.

 The object of the invention is therefore to propose a device for measuring the neutron flux in a nuclear reactor constituted by an emitting electrode made of a material absorbing the neutrons and producing electrons under the effect of the neutron bombardment and / or of the radiation <and a collecting electrode transparent to neutrons collecting the emitted electrons, between which there is a means for measuring the electron current, this device having to allow measurements of a very high precision and with a very good sensitivity while being of a bulk reduced to allow its use in the instrumentation guide tubes of the assemblies constituting the core of the nuclear reactor.

For this purpose, the emitting electrode is constituted by a set of coaxial tubular elements of the same length secured, at one of their ends, to a disc perpendicular to the common axis of the tubular elements, itself secured to '' a tube of greater length than the tubular elements, coaxial with these elements and disposed at the central part of the emitting electrode and the collecting electrode is constituted
by a set of tubular elements of the same length having for axis
the axis of the emitting electrode, each inserted between two elements
tubes of the emitting electrode and connected at one of their ends
disposed outside the emitting electrode, on a flat face of a closed external envelope completely surrounding the emitting electrode and
crossing without electrical contact along the face of the outer casing
on which the tubular elements are fixed and along a parallel face
led by the tube of great length inside which pass cones
electrical conductors connected respectively to the emitting electrode and to
the conductive electrode as well as by means of measurement of the electron current.

In order to clearly understand the invention, we will now describe,
by way of nonlimiting example, with reference to the figures appended in
annex, a measuring device according to the invention and a mode of use
tion of this measuring device in the core of a nuclear reactor.

Figure 1 shows, in a sectional view through a vertical plane
cal de symmetrie, the neutron flux measuring device.

Figure 2 shows the arrangement of a set of devices
in the nuclear reactor core, for the measurement of neutron fluxes
in this heart.

In Figure 1 we see a measuring device consisting of a
emitting electrode 1 and by a collecting electrode 2. Both elec
emitting and collecting trodes are symmetrical of revolution around a
same axis ZZ '.

The emitting electrode 1 is constituted by a set of four
tubular elements of the same length 4 arranged coaxially and connected to
one of their ends to a disc 5 perpendicular to the axis ZZ 'comx
fitted to all tubular elements 4.

The disc 5 is itself made integral with a large lon tube
gueur 6 whose ends are projecting from the disc 5 of a
part and relative to the ends of the tubular elements 4 not connected
to disc 5 by the way.

All the tubular elements 4 and the disc 5 are produced
in a material such as cobalt or cadmium, generally used for
the manufacture of emitter electrodes for collectors of the instan type
tanned.

These elements are connected together by welding and the disc 5 is
itself connected to the tube 6 constituting the support of the emitting electrode
united
which is therefore entirely formed of tubular coaxial elements Aes from each other.

 The tube 6 constituting the central part of the emitting electrode and serving as a support for this electrode is made of a material which is transparent or partially transparent to neutrons such as stainless steel or a nickel alloy.

 The collecting electrode 2 is constituted by a set of tubular elements which are approximately the same length as the tubular elements of the emitting electrode 1, connected at one of their ends to the internal surface of a disc 9 constituting it - the bottom of a closed cylindrical envelope 10 completely surrounding the elements 4 and 5 of the emitting electrode.

 The casing 10 comprises a tubular part with an axis ZZ 'and two parallel flat faces in the form of a disc 9 and 11.

 The tubular elements 4 and 8 are arranged with respect to each other so that each of the elements 8 is arranged between two successive elements 4, the element 8a disposed at the central part of the collecting electrode being however placed between the tube 6 and the first tubular element 4a.

 On the other hand, the casing 10 completely surrounds the tubular element 4d placed outermost on the emitting electrode.

 The disks 9 and 11 of the envelope 10 are other openings 13 and 14 at their central part to allow the passage of the support tube 6 of the emitting electrode.

 Two rings of insulating material 15 and 16 make it possible to electrically isolate the tube 6 with respect to the enclosure 10, that is to say the emitting electrode with respect to the collecting electrode.

 All of the elements 8 and the casing 10 constituting the collecting electrode are made of stainless steel or a nickel alloy.

 The interior volume of the envelope 10, outside the tube 6, is completely filled with a dielectric material such as alumina.

 This insulating material fills in particular the space between each of the cylindrical surfaces of the emitting electrode and each of the cylindrical surfaces of the collecting electrode disposed opposite.

 for the construction of the measuring device shown in FIG. 1, the emitting electrode and the collecting electrode can be assembled separately, the plate 11 constituting the upper part of the envelope 10 being however produced separately and not assembled to the envelope 10 before final assembly.

 This assembly is carried out by introduction of the tubular elements 4 into the corresponding spaces between the tubular elements 8, the ends of these tubular elements connected to the disks 5 and 9 respectively remaining outside the area where the tubular elements are brought into concordance.

 This is achieved by placing the tube 6 in the housing reserved by the seal 15 inside the hole 13 formed in the plate 9.

 The device is then completed by placing the disc 11 provided with the insulating seal 16 around the tube 6 and by welding the plate 11 to the casing 10.

 An electrical conductor 18 is connected to the emitting electrode 1, however an electrical conductor 19 is connected to the collector electrode 2. The two electrical conductors 18 and 19 pass inside the tube 6 to exit from the measuring device at one end of this tube 6.

 The conductors 18 and 19 are connected to an electrical circuit comprising a device for measuring the electric current of high sensitivity which allows an indirect measurement of the neutron flux when the measurement device is subjected to a neutron bombardment reaching the emitting electrode 1 through the envelope transparent to neutrons 10.

 In FIG. 2, we can see the arrangement of a set of detectors 20a, 20b, 20c, ... 20n on a common central tube 21, all of the electrical measurement conductors coming out at the lower end of the tube 21 for be connected to an assembly for measuring the electric currents flowing between the electrodes of each of the detectors.

 These different conductors can be connected to the different conductors of a measurement cable or themselves constitute the different conductors of this measurement cable 23.

 If the assembly represented in FIG. 2 is introduced into a tube for guiding the instrumentation along the height of the core of a reactor, it is possible to determine quickly and precisely, the axial distribution of the neutron flux in the core.

 Instead of a set of detectors arranged on a central mime tube as shown in FIG. 2, one could also use a single detector introduced into a mobile instrumentation guide tube for its movement inside the heart in the direction axial, to carry out the determination of the same axial distribution of the neutron flux.

 The measuring device shown in FIG. 1 functions as a detector comprising four emitters 4 arranged in parallel.

 Its sensitivity is therefore four times greater than that of a detector which would only comprise a single emitting electrode and a cylindrical collecting electrode arranged opposite.

 In general, a measuring device according to the invention comprising n tubular elements constituting the emitting electrode and n + l tubular elements constituting the collecting electrode would have a sensitivity n times greater than a device with a single electrode.

 The main advantages of the measuring device according to the invention are therefore increased sensitivity and precision despite a very small footprint allowing the introduction of this measuring detector into an instrumentation tube in a nuclear reactor.

 The invention is not limited to the embodiment which has just been described; on the contrary, it includes all variants.

 Thus, the emitting electrode can be produced not only from the usual material for the emitting electrodes of collectors of the instantaneous type but also from materials which can be used to constitute the emitting electrodes of collectrons of the delay type.

 On the other hand the number of tubular elements constituting the emitting electrode and the collecting electrode respectively can be variable according to the sensitivity and ltencombrement sought for the device.

 Finally, the device applies to the measurement of neutron flux in a nuclear reactor of any type.

Claims (6)

 1.- Measuring device dr; neutron lux in a nuclear reactor constituted by an emitting electrode made of material absorbing neutrons and producing electrons under the effect of neutron bombardment and / or T radiation and a collecting electrode transparent to neutrons collecting the emitted electrons, between which there is a means for measuring the current of emitted electrons, characterized in that the emitting electrode is constituted by a set of coaxial tubular elements of dreary length integral at one of their ends a disc perpendicular to the common axis of the tubular elements, itself integral with a tube of greater length than the tubular elements, coaxial with these elements and disposed at the central part of the emitting electrode, and that l the collecting electrode is constituted by a set of tubular elements of the same length having as axis the axis of the emitting electrode, each interposed between two tubular elements of the emitting electrode and connected at one of their ends disposed outside the emitting electrode to a flat face of a closed external envelope completely surrounding the emitting electrode and traversed without electrical contact along the face of the outer casing on which the tubular elements are fixed and along a parallel face by the very long tube inside which pass electrical conductors connected respectively to the emitting electrode and to the conductive electrode as well as by means of measuring the electron current.  2.- Measuring device according to claim 1, characterized in that the external envelope constituting a part of the collecting electrode is filled with a dielectric material occupying all the space between the tubular elements constituting the emitting electrode and l conductive electrode and between the outer casing and the emitting electrode which it contains.  3.- Measuring device according to claim 2, characterized in that the dielectric material is alumina.  4.- Measuring device according to any one of claims 1, 2 and 3, characterized in that the tubular elements constituting the emitting electrode are made of a neutron absorbing material such as cobalt or cadmium.  5.- Measuring device according to any one of claims 1, 2, 3 and 4, characterized in that the central tube constituting the support of the emitting electrode is made of a material transparent to neutrons such as a stainless steel or a nickel alloy.  6.- neutron flux measuring device, characterized in that it combines at least two devices according to any one of claims 1, 2, 3, 4 and S arranged around the same central tube and spaced along the axial direction of this tube.