FR2833412A1 - Earth's magnetic field precise measurement having resonator central conductor external conductor connected and connecting coaxial cable having parallel extension central conductor parallel forming extended loop. - Google Patents

Abstract

The nuclear magnetic resonance probe resonator has a resonator with a central conductor (10) around an axis (A) with first and second ends (12,14). The second end is connected to an external conductor (20). The central core (32) of the coaxial connecting cable (30) has an extension (50) which is parallel to the central conductor forming an extended loop.

Description

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magnétique nucléaire (RMN en abrégé). Elle trouve A n une application dans La mesure précise des champs magnétiques, notamment du champ magnétique terrestre. DESCRIPTION
RESONATOR, IN PARTICULAR FOR NMR PROBE
The subject of the present invention is a resonator, especially for a resonance magnetometer probe.

nuclear magnetic (NMR abbreviated). It finds A n an application in the precise measurement of magnetic fields, including the Earth's magnetic field.

 The magnetometer in which the probe of the invention is preferably used is of a known type, as described in particular in the French patent applications FR-A-1 447 226 and FR-A-2 098 624. so it is not useful to describe this device in detail. It is sufficient to recall that it comprises one or more bottles containing a liquid sample, arranged in a coaxial resonator. This resonator consists of a central conductor through the bottle and a conductive outer wall around the bottle. The probe comprises windings for sampling and reinjecting a signal at the LARMOR frequency, which is defined, on the one hand, by the magnetic field in which the probe is immersed and, on the other hand, by the ratio gyromagnetic specific to the liquid sample used. One of the ends of the central conductor is connected to frequency tuning capacitors and the other to a very high frequency generator.

 More specifically, an NMR probe resonator according to the prior art is shown in FIG. 1. It comprises: - a central conductor 10 having a circular cylinder shape with an axis A, this cylinder having a first end 12 and a second end 14;

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an outer conductor 20, of revolution about the axis A, consisting of a metal layer deposited on the outer wall of vials 22 respectively containing a sample which corresponds in the case of an NMR probe to a radical solution;
Laire, The metal layer being generally divided into sectors; tuning capacitors 24, connected between the first end 12 of the central conductor 10 and the outer conductor 20; a coaxial power cable 30, with a central core 32 and an outer conductive sheath 34 such as a braid, this cable leading to the resonator also called variant cavity at the second end 14 of the central conductor; The braid 34 is connected to the outer conductor 20 and the core 32 to the second end 14 of the central conductor by an extension 36; moreover, this end 14 is in turn connected to the braid by a loop 38, generally constituted by a silver thread.

 This resonator operates as follows. The radiofrequency energy is provided by the coaxial cable 30. The resonant frequency is adjusted by the capacitors 24. The central conductor 10 constitutes a "hot" point (from the point of view of the potential) and the outer conductor 20 a "cold" point ". The impedance matching between the coaxial cable (whose impedance is generally 50 ohms) and the resonator is obtained by the loop 38, which behaves like a regulatable inductor arranged

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 shorted to the end of the coaxial cable.

inductance répartie 40, correspondant essentieLLement A au conducteur extérieur 20, un condensateur réglable 42 correspondant aux condensateurs d'accord 24 et à La capacité répartie du résonateur et une inductance d'adaptation 44 correspondant au fiL d'argent 38. The equivalent electrical diagram of the set is shown in FIG. 2. This diagram shows a

Distributed inductor 40, essentially corresponding to the outer conductor 20, an adjustable capacitor 42 corresponding to the tuning capacitors 24 and to the distributed capacitance of the resonator and an matching inductor 44 corresponding to the silver wire 38.

Although satisfactory in some respects, this prior art resonator has disadvantages: firstly, it is the seat of large losses by JouLe effect; As a result, the overvoltage coefficient of the resonator is low (about 130) and the radio frequency power to be supplied is high; - Next, the presence of a loop such as 38 at the input of the resonator generates a radiofrequency radiation around
The apparatus; In addition, the adaptation to the coaxial cable remains poor and does not make it possible to reduce the stationary wave ratio (TOS) below 1, 4; above 300 MHz, it becomes even almost impossible to adapt the resonator; - Finally, the adaptation loop breaks the symmetry of the resonator, which makes the anisotropic probe from the point of view of the radiofrequency field.

 It is possible to add to these disadvantages of an electrical character a disadvantage of a mechanical order: the adaptation loop is fragile and the adjustment difficult; Moreover, it does not lend itself to

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 industrialization and is more a matter of laboratory regulation.

résonateur ; A - permet une meilleure adaptation câble-réso- nateur et autorise un TOS inférieur à

1, 1 ; - ne perturbe pas sensiblement la symétrie de l'ensemble ; - autorise une industrialisation par un montage simplifié. The present invention is intended to remedy all these disadvantages. It offers a simple way of connecting the coaxial cable to the resonator. This means: - reduces the losses by Joule effect and increases the surge of the resonator which passes to a value of the order of 400 to 500, which reduces by
Radiofrequency energy to be injected; - avoids radiation outside the

resonator; A - allows a better cable-resonator adaptation and allows a TOS lower than

1, 1; - does not substantially disturb the symmetry of the whole; - allows industrialization by a simplified assembly.

 All these results are achieved, thanks to the invention, in that the second end of the central conductor is connected to the outer conductor and that the core of the coaxial cable has an extension extending in the resonator parallel to the central conductor to form a narrow and elongated loop along the central conductor.

 According to a first embodiment, the extension of the core of the coaxial cable has its end fixed to the central conductor at a point remote from the second end of said conductor, the loop formed being thus constituted by the extension in question and a part of the conductor. central and the sheath of the coaxial cable is connected to the outer conductor.

 According to a second embodiment,

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 extension of the core of the coaxial cable at its end fixed on the sheath of the coaxial cable, this extension being thus folded on itself and forming a loop along the central conductor.

 In applications other than NMR probes, it may be advantageous to further connect the sheath of the coaxial cable to the outer conductor of the resonator.

 In any case, the features and advantages of the invention will become more apparent in the light of the following description. This description relates to particular embodiments and refers to the accompanying drawings in which: - Figure 1, already described, illustrates a resonator according to the prior art; FIG. 2, already described, is an equivalent electrical diagram of a resonator according to the prior art; FIG. 3 shows a resonator according to the invention in a first embodiment; FIG. 4 shows the equivalent electrical circuit of this resonator; FIG. 5 shows a resonator according to the invention in a second embodiment; - Figure 6 shows the corresponding equivalent electrical circuit; FIG. 7 shows a variant embodiment with a loop support; - Figure 8 shows another embodiment of loop support embodiment; - Figure 9 shows the end of the coaxial power cable.

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FIG. 3 shows a resonator comprising means already shown in FIG. 1, namely, a central conductor 10, an outer conductor 20, tuning capacitors 24, a coaxial supply cable 30 with its core 32 and its braid 34. The resonator shown differs from that of FIG. 1 by the fact, on the one hand, that the end 14 of the central conductor is electrically connected to the outer conductor 20, the braid of the coaxial cable (cold spot) being connected to the outer conductor 20 and on the other hand, that the core 32 of the coaxial cable has an extension 50 extending into the resonator, along the central conductor 10 and coming into contact therewith at a remote point 52 end 74 of the central conductor. The exact point is defined in the laboratory, and corresponds to the best possible adaptation with the power cable.

For a cylindrical resonator with a center conductor of 10 cm, the outer wall diameter is 8 cm. The connection joint 52 is located about half of the center conductor 10 for 50 impedance matching.

 The equivalent diagram of this resonator is shown in FIG. 4. This diagram differs doubly from that of FIG. 2 relating to the prior art: on the one hand, the point of connection between the core of the cable and the resonator is now carried out between two inductors 40/1, 40/2 instead of being at the end of the single equivalent inductance 40; on the other hand, the inductive loop 44 is removed.

 The resonator thus formed has a surge of 37U with a central conductor 8 mm in diameter and an overvoltage of 480 with a diameter of 10 mm, all in a spherical external conductor.

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 than 70 mm in diameter. These values (370 and 480) are to be compared with the value 130 of the prior art.

 By extension, the loop formed by the extension 50 and the return of the central half-conductor, being totally enclosed in the resonator, radiofrequency field radiation outside the probe is nil.

 If the symmetry of revolution of the resonator is destroyed by the presence of the conductor 50, it remains at least one symmetry with respect to the plane passing through the conductor and the axis A of the set.

d'impédance. IL reste qu'une boucle est cependant 1 formée entre L'extrémité de L'âme 32 du câble coaxiaL d'alimentation et sa tresse par Le proLongement 50 et Le retour Le Long de La génératrice du cylindre conducteur central 10. Cette boucle constitue un moyen de couplage inductif entre Le câble coaxiaL et Le résonateur. Dans Le second mode de réalisation prévu par L'invention et illustré sur La figure 5 cette seconde fonction, de couplage inductif, est amplifiée. In the variant of FIG. 3, the extension 50 serves primarily as a means of adaptation

impedance. However, a loop is still formed between the end of the core 32 of the feed coaxial cable and its braid by the extension 50 and the return along the generatrix of the central conductive cylinder 10. This loop constitutes a inductive coupling means between the coaxial cable and the resonator. In the second embodiment provided by the invention and illustrated in FIG. 5, this second function, of inductive coupling, is amplified.

 In Figure 5, there is shown a resonator different from that of Figure 3 by the shape given to the extension of the core of the coaxial cable. This soul still has an extension 50, but it is folded on itself by a strand 51 to connect on the braid 34 at a point 55. In practice, the strands 50 and 51 are constituted for example by a foil d pure silver.

 The equivalent circuit diagram is shown in FIG. 6. It can be seen that the loop formed by the strands 50, 51 is in mutual induction with the distributed inductance 40 of the resonator.

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 Figures 7 to 9 show various embodiments of this loop with means for implementation in the resonator.

 In FIG. 7, the central conductor 10 is surrounded by a sleeve 60 of electrical and magnetic insulating material (for example glass of the "Pyrex" mark or in macor). This sleeve is pierced with a channel 62. It is in this channel that the coupling loop 50, 51 will be introduced and maintained.

 In FIG. 8, the means for holding the coupling loop is again a channel 64, but this time formed in the wall of the bottle 22. In this case, this loop is located within the radical solution.

 In both variants, the coupling loop can be obtained as shown in Figure 9, by folding the two strands 50 and 51 on an insulating finger 53 extending the coaxial cable 30. This finger 53 is inserted, or in the channel 62 of the sleeve 60 of FIG. 7, or in the channel 64 of the bottle of FIG. 8. The material used to constitute the finger 53 may be the same as that of the sleeve 60 (for example in macor).

 This solution has the advantage of a very good mechanical strength and a great simplicity of assembly. Moreover, the adjustment of the coupling can be done very simply by rotation of the support 53, thus rotation of the plane of the loop.

As an explanation, the Applicant has made a resonator having the following dimensions: a-) Support 60:
Material: macor - outer diameter: 18 mm, - inside diameter: 8 mm, - length: 55 mm.

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- diamètre extérieur : 4 mm, - Longueur : 30 mm. c-) Boucle de couplage 50, 51 : matériau : argent pur - épaisseur : 2/10 mm, - Longueur : 27 mm, - largeur : 2, 5 mm. b-) Finger 53: material: macor

- outer diameter: 4 mm, - length: 30 mm. c-) coupling loop 50, 51: material: pure silver - thickness: 2/10 mm, - length: 27 mm, - width: 2, 5 mm.

 While the loop used in the invention may be reminiscent in some respects of the loops used to excite resonant cavities in the microwave range, there are some essential differences in structure and function.

 In a microwave cavity, the loop is obtained by a circular turn placed in an area where the resonant microwave field has a strong magnetic component. Thus, to excite a coaxial cavity, a coil placed in the median plane of the cavity will be used, the coil being oriented in a plane perpendicular to the axis of the cavity.

nement des cavités hyperfréquences (à 60 MHz, La spire devrait avoir une superficie supérieure à 2 cm2 alors que, dans l'invention, La superficie est de L'ordre du cm2), - ensuite parce que la forme de la boucle n'est pas circulaire mais très aLLongée (par exemple, la longueur de la boucle This is not the loop used in the invention for at least three reasons: - first, because the surface area thereof is much smaller than would be appropriate with the mode of operation.

Microwave cavities (at 60 MHz, the coil should have an area greater than 2 cm2 while in the invention, the area is of the order of cm2), - secondly because the shape of the loop is not circular but very elongated (for example, the length of the loop

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can be about 60 mm and Width 2 mm), - finally, the loop extends parallel to the axis of the resonator and the Long of the central conductor, on about half of
The length of it and not in a plane perpendicular to the axis.

et L'adaptation ne serait pas assurée sur toute La gamme de température dans LaqueLLe Les sondes RMN doivent fonctionner (généralement de-40 C à +70 C et même +125 C).This original arrangement allows a better adjustment of impedance matching. With a circular turn like that of microwave cavities, the adjustment of the adaptation is very critical

and the adaptation would not be ensured over the entire temperature range in which the NMR probes should operate (generally from -40 C to +70 C and even +125 C).

Claims (7)

 1. coaxial resonator especially for NMR probe, comprising: - a central conductor (10) having an axis (A), a first end (12) and a second end (14), - an outer conductor (20) revoLution about this axis (A), - at least one tuning capacitor (24) connected between the first end (12) of the central conductor and the outer conductor (20), - a coaxial power cable (30) with a core (32) and an outer conductive sheath (34), which cable terminates at the resonator at the second end (14) of the center conductor (10), which resonator is characterized by the fact that the second end (14) of the conductor central (32) is connected to the outer conductor (20) and the central core (32) of the coaxial cable (30) has an extension (50) extending in the resonator parallel to the center conductor (10) to form a loop. narrow and elongated along the central conductor (10) .  2. Resonator according to claim 1, characterized in that the extension (50) of the core (32) of the coaxial cable (30) has its end fixed to the central conductor (10) at a point (52) remote from the second end of said conductor, the formed loop being thus constituted by the extension (50) and a portion of the central conductor (10) and by the fact that the sheath is connected to the outer conductor (20).  3. Resonator according to claim 1, <Desc / Clms Page number 12>  characterized by the fact that the extension (50) of the core (32) of the coaxial cable (30) has its end (55) fixed to the sheath (34) of the coaxial cable (30), this extension being thus folded over it and forming a loop (50, 51) along the central conductor (10).  4. Resonator according to claim 3, characterized in that the sheath is further connected to the outer conductor.  5. Resonator according to claim 3, characterized in that the central conductor (10) is surrounded by an insulating sleeve (60) pierced with a channel (62) paraLLèLe the central conductor (10) and close to this- ci, The loop (50, 51) being housed in this channel (62).  6. Resonator according to claim 3, characterized in that the outer surface (20) consisting of a metal layer (20) deposited on the wall of a bottle (22), the wall of this bottle has a re-entrant portion in the form of a parallel channel to the central conductor (10) and close thereto, the loop (50, 51) being housed in this channel.  7. Resonator according to any one of claims 5 and 6, characterized in that the coaxial power cable (30) ends with an insulating rod (53) supporting the extension (50, 51) replié on itself this rod (53) being able to engage in the duct (62, 64) provided in the insulating sleeve (60) or in the wall of the flask (22).