EP0382759A1

EP0382759A1 - Bobbin, magnet including such bobbin, imaging device by nmr comprising such a magnet and method for making such a magnet

Info

Publication number: EP0382759A1
Application number: EP19880908705
Authority: EP
Inventors: Guy Aubert
Original assignee: Centre National de la Recherche Scientifique CNRS
Current assignee: Centre National de la Recherche Scientifique CNRS
Priority date: 1987-10-09
Filing date: 1988-09-30
Publication date: 1990-08-22
Also published as: JPH07107884B2; JPH02503048A; WO1989003580A1; FR2621731B1; FR2621731A1

Abstract

L'invention a principalement pour objet une bobine, un aimant comprenant une telle bobine, un dispositif d'imagerie par RMN comportant un tel aimant et procédé de réalisation d'un tel aimant. L'invention concerne les bobines de Bitter sans trous ce qui permet de réaliser lesdites bobines par collage. Une telle bobine est une pièce monolithique usinable. L'usinage permet l'obtention d'une grande précision de réalisation nécessaire à l'obtention de champs magnétiques homogènes. L'invention s'applique principalement à la réalisation des bobines (1) de Bitter, d'aimant (11) de Bitter. L'invention s'applique notamment à l'obtention de champs magnétiques forts et/ou uniformes, pour la recherche scientifique, médicale ou pour l'imagerie par résonance magnétique nucléaire.The main object of the invention is a coil, a magnet comprising such a coil, an NMR imaging device comprising such a magnet and method for producing such a magnet. The invention relates to Bitter coils without holes, which makes it possible to produce said coils by gluing. Such a coil is a machinable monolithic part. The machining makes it possible to obtain a high precision of production necessary for obtaining homogeneous magnetic fields. The invention mainly applies to the production of coils (1) of Bitter, of magnet (11) of Bitter. The invention applies in particular to obtaining strong and / or uniform magnetic fields, for scientific, medical research or for nuclear magnetic resonance imaging.

Description

COIL, MAGNET COMPRISING SUCH A COIL, NMR IMAGING DEVICE COMPRISING SUCH A MAGNET AND METHOD FOR PRODUCING SUCH A MAGNET.

The invention, due to the collaboration of the National Field Service Intense of the CNRS (Director M. AUBERT), relates to a coil of Bitter type, a magnet comprising such coils as well as the nuclear magnetic resonance imaging device comprising a such a magnet. The invention further relates to the method for producing such a magnet. The invention relates more particularly to improvements of these types of magnets in order to increase the homogeneity of the magnetic fields generated and to simplify the manufacture of the magnet.

A Bitter coil was described for the first time by Francis BITTER in an article in "Review of Scientific Instruments" of December 1936. Each coil has metallic annular discs split to form turns and connected to define a substantially helical coil winding flat. Bitters coils of known type include insulating materials inserted between the metal annular discs to avoid short circuits, as well as tie rods allowing the stack to be maintained. Holes parallel to the axis of the coil, arranged in the same configuration, from one disc to another, materialize a set of parallel channels. Fluid circulation in these channels allows efficient cooling of these magnets.

A Bitter magnet has at least one Bitter coil.

Many improvements have been made to Bitter magnets. In French Patent No. 84 19,193 published under No. 2,574,982 is described a Bitter magnet in which the return of the current is ensured by the tie rods ensuring the rigidity of the assembly. Thus the current flow is distributed longitudinally on a cylinder surface coaxial with the coil which makes it possible to reduce the stray fields generated by the current supply conductors.

French Patent No. 84 19191 published under No. 2,574,980 describes a process which makes it possible to obtain a desired magnetic field homogeneity while minimizing the product P. M where: - P is the electrical power to be supplied to the magnet and - M is the winding mass of the magnet. Optimization is obtained by using several Bitter coils arranged along a common longitudinal axis z, symmetrically with respect to a transverse plane. It is possible, by carrying out a development of the fields obtained on the spherical harmonics, to determine the characteristics and the arrangements of the coils allowing corrections of inhomogeneity of magnetic field as thorough as is desired. These corrections can take account of constraints, such as for example gradients of axial and / or radial temperatures inside elements. Indeed, the global or local heating of the coils modifies the magnetic field generated by:

- a geometric modification due to the expansion of the coil; - the variations in resistivity with the temperature of the metal constituting the coil, and consequently the variation of the electric current in the various parts of the coil. A calculation advantageously performed on a computer makes it possible to determine the ideal coils and their relative arrangements taking into account the chosen constraints. For a magnet determined by the proposed method the PM product is given by the formula:

PM = (411 B ₀ / μ _Q ) ² a ⁴ p _p / g≈

where: B ~ is the field expressed in tesla μ _n is a constant a is the internal radius of elements p is the density of the metal constituting the helical coil p is the resistivity of the metal of the coil constituting the helix and g is a geometric factor less than or equal to 1 determining the homogeneity of the field, g is equal to 1 for a single turn of zero section. Depending on the constraints imposed, it is possible to determine with precision the construction thereof. Advantageously, account is taken of the influence of the temperature on the characteristics of the magnet, that is to say that the stresses will be imposed on a magnet having reached its equilibrium temperature in operation.

The constraints imposed will vary with the fields of application of the magnet. For example, under current economic conditions it will, most of the time, be advantageous to use copper to make the coils. In NMR imaging we will need, for example:

- a magnetic field between 0, 1 and 1 tesla,

- an internal radius allowing a patient to enter as well as all the magnetic equipment necessary inside the magnet - a great homogeneity of the magnetic field generated imposing geometries for which the factor g is small compared to 1.

On the other hand, in scientific research, we will need magnets: - generating the strongest possible field, for example greater than 10 teslas,

- a small internal radius sufficient to accommodate the sample to be subjected to the magnetic field, good homogeneity of the magnetic field generated. Optimization makes it possible to determine the exact geometry that the coils must take to obtain the desired magnetic field. However, the precision of production of Bitter type coils is limited. The present invention relates to a method of manufacturing Bitter coils making it possible to increase the manufacturing precision of Bitter coils, in particular to approach the optimal model obtained by calculation. To do this, the holes passing through the turns of the coils have been eliminated. Advantageously, these holes are replaced by a cooling channel external and / or internal to the coil.

The absence of the holes makes it possible to glue the disc using an insulating glue so that each coil forms a monolithic part. The presence of the holes in the disc would not have allowed the use of the glue because it would have flowed inside the holes and would prevent the coil from cooling properly. Indeed, on the one hand the glue limits the heat exchanges between the discs and the cooling fluid and on the other. part limits the flow rates of the fluid by partially plugging the holes. The glue having flowed inside and outside the coil is advantageously removed by machining, for example by lathe. Thus, the coil obtained has the precision of a mechanical part, this precision being much greater than that obtained with Bitter coils having tie rods to ensure rigidity. Machining was made possible by obtaining a coil in the form of a machinable monolithic part. In addition, bonding allows a simpler realization than that of known type devices.

The invention relates to a coil, a magnet comprising such a coil, a nuclear magnetic resonance imaging device comprising such a magnet, a method of producing such a magnet, as described in the claims. The invention will be better understood by means of the description below and the figures given as nonlimiting examples among which: - Figure 1 is a diagram of a first embodiment of a coil according to the present invention;

- Figure 2 is a diagram of a second embodiment of a coil according to the present invention; - Figure 3 is a diagram of a third embodiment of a coil according to the present invention;

- Figure 4 is a fourth embodiment of a coil according to the present invention; Figure 5 is a curve of a temperature profile of the coil illustrated in Figure 1; Figure G is a curve of a temperature profile of the coil illustrated in Figure 2; Figure 7 is a curve of a temperature profile of the coil illustrated in Figure 3; - Figure 8 is a diagram of a weld implemented in the device according to the present invention;

- Figure 9 is a diagram of a device for making the coils according to the present invention; FIG. 10 is a diagram of a detail of embodiment of a coil according to the present invention; FIG. 11 is a diagram of a detail of embodiment of a coil according to the present invention;

- Figure 12 is a diagram of a fifth embodiment of a coil according to the present invention;

- Figure 13 is a diagram of a magnet according to the present invention;

- Figure 14 is a diagram of an exemplary embodiment of a nuclear magnetic resonance imaging device according to the present invention;

- Figure 15 is a diagram of a cooling device used in the device according to the present invention;

- Figure 16 is a diagram of a cooling device used in the device according to the present invention. In FIGS. 1 to 16, the same references have been used to designate the same elements.

In Figure 1, we can see a coil 1 according to the present invention having no cooling holes. The coil 1 is a Bitter type coil comprising a plurality of slotted disks 3. The discontinuity 5 of the discs 3 makes it possible to connect each disc to the next and to produce a substantially helical coil with a succession of discs. The absence of cooling holes makes it possible to use the bonding to assemble with an insulating adhesive 4, the discs 3. However, it is necessary to ensure the cooling of the coil 1. In the embodiment illustrated in the figure 1 a cylindrical external cooling channel 2 has been arranged having the same z axis as the axis of the coil 1.

The use of glue 4 allows the production of a machinable monolithic coil 1. Thus, it is possible by machining to remove the glue that would have flowed inside and outside the coil. Likewise, if it was desired to make holes inside the coil, which is not the case in the example illustrated in FIG. 1, these holes should be machined or remanufactured after gluing to eliminate the flow of glue 4. The use of an external cooling channel 2 located on the periphery of the coil 1 makes it possible to free the center of the coil to have more space there for subjecting a body to the magnetic field. Thus, it is possible either to reduce the size of the coil 1, or to increase the space available. For example, in nuclear magnetic resonance imaging applications it is necessary to house inside the coil 1 the patient, a radiofrequency antenna, coils capable of generating magnetic field gradients, and possible coils correction. It should be remembered that as indicated above top the PM product is proportional to the fourth power of the inner radius of the coil.

In Figure 2, we can see a coil 1 according to the present invention having an internal cooling channel 2. In this arrangement, the cooling channel 2 is closer to the zones where most of the heat is produced by the Joule effect. Indeed, the heat is released mainly on the internal part of the disc 3.

In FIG. 3, one can see a coil 1 according to the present invention comprising an internal cooling channel 2 and an external cooling channel 2. This allows a particularly efficient cooling of the coil.

Various means can be used to increase the cooling efficiency of the coils 1. In FIG. 4, we can see parts 6, for example insulating rods, helically mounted around the coil 1 and defining a channel 7 for the fluid. cooling . Thus the coolant is forced to take a longer path surrounding the coil 1 several times and thus allowing better cooling.

Advantageously, the profile of the channel 7 causes a turbulent flow preventing the formation of boundary layers detrimental to the proper cooling of the coil.

The formation of boundary layers is particularly troublesome for good cooling by fluids having poor thermal conduction.

In FIG. 5, we can see a profile 10 of the temperatures T 9 as a function of the radius r 8 inside metal discs 3. The temperature profile of FIG. 5 corresponds to the external cooling channel 2 as illustrated in Figure 1. The temperature 9 decreases when the radius 8 increases to reach the minimum temperature on the edge of the discs 3.

To obtain a homogeneous field, it is imperative, when optimizing, to take account of the expansions which will produce, in operation, inside the coil 1 according to the present invention as well as variations in resistivity in the various parts of discs of the coil 1. The determination of the temperatures is carried out in a known manner by a calculation using the equation of heat "taking into account the surface conditions of the thermal conduction, mass heat and cooling fluid flow.

In FIG. 6 we can see a profile 10 of temperature T 9 as a function of the radius 8 of disc 3 of coil 1 according to the present invention illustrated in FIG. 2.

In the case of profile 10 of FIG. 6, the minimum temperature is reached on the internal edge of disc 3 and subsequently increases to reach the maximum temperature on the external edge. In FIG. 7, a profile 10 of temperature T 9 can be seen as a function of the radius r 8 of a coil 1 according to the present invention as illustrated in FIG. 3. The coil 1 illustrated in FIG. 3 comprising a channel external cooling device and an internal cooling channel 2. The minimum temperature is reached on the internal and external edge of the disc 3. From these minimums the temperature increases inside the discs 3 passing through a maximum.

The profile 10 of FIGS. 5, 6 and 7 corresponds to a disk 3. It is also possible to take into account a temperature gradient along the axis z which comes from the gradual heating of the cooling fluid as it circulates in the cooling channel 2.

In the first embodiment of Bitter coils, electrical continuity was ensured by mechanical contact between the discs 3. The more sophisticated Bitter magnets were produced by welding discs or parts of metal discs. A welding process with electrolytic indium deposition was described in French Patent No. 85,02971 published under No. 2,578,057. In Figure 8, we can see an embodiment of a direct weld of copper on copper. The direct copper welding of two discs 3 or two disc portions 3 causes the formation of a bead 32 on one of the faces of the disc and craters for initiating and ending the solder 33 on the side. The bead 32 comes from the withdrawal of the heated copper during soldering.

The presence of the bead 32 prevents the production of a regular coil 1. Thus, the bead 32 risks disturbing the homogeneity of the field created by the magnet according to the present invention and damaging the insulation between discs.

In addition, at the weld 31 it is possible to obtain a corner deformation, between the circular axis 34 of the disc if it was perfectly circular and the axis 35 of a disc part.

The device of Figure 9 overcomes the problem posed by the direct soldering of copper on copper. It is not industrially possible to machine, for example file, the bead 32. In fact, this machining should necessarily take place before the adhesive 4 is applied. The machining chips would risk perforating the adhesive 4 and therefore cause short-circuits completely disrupting the operation of the coil 1.

On the other hand, it has proved possible to flatten the bead 32 by applying a pressure roller to it.

The device of FIG. 9 comprises two pressure rollers 36, for example two ball bearings fixed to the ends of two branches 37. A control device for example a threaded steel rod fixed to one of the branches 37 and passing through a thread made in the other branch 37 makes it possible to adjust the distance between the two pressure rollers. Thus, it is possible in addition to the flattening of the bead 32 of the weld 31, by pressing harder on a part of this bead to correct the no-concordance of the axes 34 and 35. In addition, once the weld 31 is flattened refills in part of the craters 33 at the ends of said weld, the remaining defects are eliminated by final machining on a lathe.

In FIG. 10, the particularly advantageous bonding method used for producing coils according to the present invention is illustrated. In the example illustrated in Figure 10 only two discs 3 have been shown. In this example, portions of discs 3 welded and corresponding to 111 ° were used. This value corresponds approximately to a third of a turn but prevents systematic superposition of the welds 31. The adhesive 4 is composed in the example illustrated in FIG. 10 of two layers. Each layer has a length equal to that of a step of 111 °. Each layer is offset by half a step. Between the layers, a space 60 is left which will be filled with the adhesive at the time of the polymerization thereof. Advantageously, Prinom B glue with a thickness of 0.1 mm is used, manufactured by the company ISOVOLTA and distributed by the company DEGLARGES.

The offset of half a step of the interstices 60 certainly provides good insulation after polymerization. This adhesive makes it possible to easily resist the tensions between turns encountered in the magnets used in NMR imaging. Such a magnet has for example 500 turns, the voltage between the first and the last turn being equal to 200 Volts. In addition, this adhesive is in the form of a double-sided adhesive having excellent mechanical strength and allowing the machining of the windings 1 obtained by bonding. It should be noted that the use of this very abrasive adhesive requires frequent change of machining tools, unless using diamond tools. In Figure 11, we can see two embodiments of machining coils 1 according to the present invention. In the circle A the machining obtained is smooth. This machining is easy to obtain and the optimization calculations are facilitated by the adoption of a simple surface. In the circle B we can see grooves 80 facilitating the cooling in preventing the formation of a static boundary layer of fluid on the surface of the coil 1. It is understood that, unlike the illustration in FIG. 11, only one type of machining will be used on the surface of the coil 1. However , 11 it is possible to use grooved machining on the surface delimiting a cooling channel 2 not shown in FIG. 11 and smooth machining on an uncooled surface.

In Figure 12 we can see a coil 1 according to the present invention comprising insulating rods 30. The rod 30 serves as a spacer between the body of the coil 1 and for example the carcass of the magnet.

The rods 30 are for example glued, after machining the coil 1. In the absence of rods 30, the surface of the coil 1 may rub while being scratched when mounted on the carcass of the magnet. This is particularly serious when using fiberglass carcass. These frictions cause streaks of copper which risk short-circuiting the turns making the magnet unfit to generate homogeneous magnetic fields. In Figure 13 is illustrated a method of mounting a magnet according to the present invention. Advantageously, the carcass of the magnet according to the present invention consists of two half carcasses 61 with horizontal opening.

In the lower half-carcass, the first finished coil 1 is first deposited according to the present invention. Then a central guide tube 62 is advanced. Advantageously, the tube 62 is made of fiberglass embedded, for example in an epoxy resin. Then a spacer 64 or a plurality of shims is deposited. Advantageously, in the spacer 64 are provided locations allowing the connection of the following coil 1 without disturbing the homogeneity of the magnetic field created by the coils. Such connections have been described in French Patent No. 85,04050 published under No. 2,579,362 and 85 07,151 published under No. 2,581,760. The central tube 62 is advanced.

The second coil 1 is deposited in the lower half of the carcass 61.

Connections are made between the first and second coil 1.

The tube 62 continues to be advanced, the successive spacers 64 and the coils 1 are removed and the connections are made until a complete magnet is obtained.

Advantageously, the spacers 64 seal the cooling channels 2, not shown in FIG. 13.

In Figure 13 the central tube 62 is shown in its end position.

Once the coils and the spacers are assembled, the current return connections are made, for example by means of the copper cables 119 distributed over the periphery of the magnet so as not to create a disturbing magnetic field. Then - the magnet is closed by means of an upper half-carcass 61 and end plates 63 are assembled.

It is understood that all the necessary metallurgical treatments are carried out, in particular at the level of the connections, for example the deposition of layers against nickel diffusion or the deposition of gold layers preventing any corrosion.

Once assembled, the carcass seals the magnet 1 and advantageously serves as walls for the cooling channels 2.

The use of spacers 64 allows precise positioning of the winding 1 of the material embodiment of the optimized magnet obtained by the calculations.

In Figure 14, we can see a nuclear magnetic resonance imaging device. The installation is provided with a correction winding system (called "shims") known per se and not shown, essentially intended to compensate for the disruptive effects of the magnet's environment. The magnet 11 responsible for developing the basic field is associated with a system of gradient coils 50, known per se, the gradient coils are arranged on a cylindrical tubular mandrel placed inside the internal space 12 of the magnet 11, coaxial to the z axis. The gradient coil system is completed by a set of direct current power supplies (Gx, Gy, Gz) controlled according to a cycle of preprogrammed sequences in a computer 51 to supply the gradient coils so as to superimpose on the base field of the magnetic field gradients of predetermined intensities and orientations during said sequences. We know that these gradients allow, among other things, to select the section plane whose image we want to reconstruct. A system of radiofrequency antennas 55 is also housed inside the useful space 12 of the magnet 11. These antennas are part of radio frequency transmission / reception means, further comprising a radio frequency generator 56 controlled by the computer 51 to generate calibrated pulses of radio frequency signal during said sequences. The NMR signals re-emitted by the subject under examination are picked up by the same antenna system and exploited by a computing unit of the computer 51, applying known algorithms to reconstruct an image. This image is for example displayed on a cathode ray tube of a monitor 58. The device also comprises a cooling circuit comprising tubes 14, a pump 17, a heat exchanger 16. Reference 16a was used for the primary circuit of the exchanger and 16b for the secondary circuit of the heat exchanger 16. Advantageously, the nuclear magnetic resonance imaging device comprises a regulation device as described in French Patent No. 84 19190 published under the No. 2,574,982. Such a device comprises an auxiliary magnet 1-3 of small dimensions, a cooling fluid circulation circuit 14 in thermal contact with the magnets 11 and 13 and a direct current source 15, controlled, connected in series with the coils of the two magnets.

In all cases, the magnet has a structure allowing efficient heat exchange between the windings of the resistive coil or coils constituting it and the cooling fluid. It is the same for the magnet 13 which is arranged to receive the same cooling fluid so as to be always substantially at the same temperature as the main magnet. It should be noted in this connection that the internal resistance of the auxiliary magnet is very low compared to that of the main magnet so that its contribution to the heating of the fluid flowing in the circuit 14 is practically negligible. In addition, the coils of the two magnets 11 and 13 are made of the same conductive material, in particular copper or aluminum.

The circuit 14 further includes a circulation pump 17 and a heat exchanger 16 of which. the secondary circuit 16b is crossed by said cooling fluid and the primary circuit 16a of which is supplied, for example, by circulating cold water. In the example shown, the circuit 14 is designed so that all of the cooling fluid passes through the auxiliary magnet 13, but it is possible, by an appropriate bypass, to circulate only a part of this fluid in the magnet 13 provided that the temperature of the latter is always substantially equal to that of the magnet 11, at all times. With this in mind, it is particularly important that the circuit 14 is arranged so that the fluid entering the magnet 13 comes directly from the main magnet 11, without passing through the exchanger 16. Furthermore, as mentioned previously, the coils of the magnets 11 and 13 are, at all times, crossed by the same current delivered by the current source 15. The magnet 13 has the function of creating a witness magnetic field representative of the field of the main magnet in at least a limited volume of its internal space where are placed means for measuring said control field, for controlling a control chain 19 for the current delivered by the direct current source 15. According to a preferred embodiment, these field measurement means comprise an NMR probe 20, for controlling the chain control 19, said probe being placed in said restricted volume. To obtain an exploitable NMR signal, the auxiliary magnet 13 is constructed so that the control field is of sufficient homogeneity in the restricted volume where the probe is placed. In practice, the homogeneity of the control field in the surrounding volume of the probe must be from 1 to 10 ppm, that is to say of the same order of magnitude as the homogeneity of the basic field in the useful volume of l main magnet.

The magnets 11 and 13 each have a longitudinal axis of symmetry, respectively Oz and O'z ', O and O' being the centers of symmetry of these magnets. According to an advantageous characteristic of the invention, the axis O'z 'of the auxiliary magnet 13 is substantially placed in a median transverse plane (containing the point O) of the main magnet 11 so as to cut the axis Oz at point O, the magnet 13 of course remaining outside the magnet 11. This arrangement is that which offers the weakest parasitic coupling between the two magnets and which therefore disturbs the homogeneity of the two fields the least. In Figures 15 and 16, one can see two embodiments of the magnet 11 cooling device according to the present invention.

In FIG. 15, a magnet 11 can be seen comprising a primary coolant circuit, a secondary circuit, the primary circuit yielding thermal energy to the secondary circuit by means of an exchanger 16. Advantageously, a pump 17 circulates the primary coolant.

The magnet 11 according to the present invention has a very wide field of application. Depending on the application, technical characteristics of the magnet, the economic constraints will be totally different. It is important to adapt the cooling to the type of magnet, to the economic constraints encountered. In scientific research, we use magnets capable of generating very strong magnetic fields, often greater than 10 teslas. Such magnets support very strong electric currents and their lifespan is often limited to, for example, 1000 hours of operation. For such applications, it is often advantageous to use deionized water as the cooling fluid. This fluid has the advantage of having a very high specific heat, a low viscosity and a high resistivity. However, deionized water has drawbacks, such as the difficulty of preparing deionized water, and its aggressiveness with respect to copper. However, corrosion of copper by deionized water will not be sensitive during life, in any case limited to 1000 hours of the magnet 11. In scientific research, it is frequent to increase the flow rate of the cooling fluid in using relatively high pressures, for example 30 bars.

In NMR medical imaging, kerosene or oil will advantageously be used as cooling fluid. These fluids are neutral vis-à-vis the copper advantageously constituting the coils, of a long conservation and an easy implementation. They have the disadvantage of low specific heat and high viscosity. These drawbacks are acceptable in NMR imaging, insofar as the magnetic fields liable to generate are weaker than in scientific research, typically 0.1 tesla, and large fluid flows or devices, such as those, have been provided. illustrated in Figure 4 to increase the cooling efficiency.

In French Patent No. 87 09817 ^• filed July 10, 1987 and not yet published, the use of the latent phase transition heat for cooling magnets. The latent heat of phase transition corresponds for example to the transition from the liquid state to the gaseous state of the cooling fluid. The use of a fluid comprising the two phases, for example liquid and gaseous, throughout the cooling circuits makes it possible to avoid the appearance of temperature gradients along the axis z of the magnet 11. In addition, the energy absorbed by the mass unit is much higher, which makes it possible to limit the flow rate of the cooling fluid. Many insulating fluids are suitable for this type of cooling. Advantageously, a cooling fluid is used, the boiling temperature of which, at the pressure of use of the primary cooling circuit, is capable of being supported without drawback by a patient placed inside the magnet 11. For example , the freon 11 which is composed of CC F has a boiling temperature of the order of 30 ° C at a pressure of 1, 3 bar.

In FIG. 16, an exemplary embodiment of the magnet 11 cooling device can be seen using a heat pump for extracting the calories from the magnet. The heat pump comprises, in the primary circuit a compressor 170, a regulator 171. The use of heat pumps makes it possible to reduce the amount of water circulating in the exchanger 16. Advantageously, the cooling circuit ^ magnet 11 constitutes, at least part of the regulator 171.

The invention mainly applies to the production of coils 1 of Bitter, of magnet 11 of Bitter. The invention is particularly applicable to obtaining strong and / or uniform magnetic fields, for scientific, medical research or for nuclear magnetic resonance imaging.

Claims

1. Bitter coil (1) comprising a plurality of annular metal discs (3) split to form the turns and connected to constitute a substantially helical winding of axis z with flat turns comprising at least one cooling channel capable of guiding a fluid , characterized in that it comprises at least one cylindrical cooling channel (2) of the same z axis as the helical winding.

2. Coil (1) according to claim 1, characterized in that the discs (3) or parts of discs are assembled end to end by welding of copper.

3. Coil (1) according to claim 1 or 2, "characterized in that the outer surface of the turns forms the inner wall of the cooling channel (2), a wall parallel to the outer surface of the turns, of greater diameter forming the outer wall of the cooling channel (2).

4. Coil according to claim 1, 2 or 3, characterized in that the internal surface of the turns forms the internal wall of the cooling channel (2), a wall parallel to the internal surface of the turns of smaller diameter forming the internal wall of the cooling channel (2).

5. Coil (1) according to claim 1, 2, 3 or 4, characterized in that the metal discs (3) are bonded using an insulating adhesive (4).

^ 5 6. Coil (1) according to claim 5, characterized in that the glue (4) is a polymerizable glue.

7. Coil (1) according to claim 6, characterized in that before the polymerization the adhesive (4) forms two non-contiguous discs with a zone of overlap by each disc of the interval (60) * of the associated disc.

8. Coil (1) according to claim 5, 6 or 7, characterized by the fact that the glue (4) is Prinom B.

9. Coil (1) according to claim 1, 2, 3, 4, 5, 6, 7 or

8, characterized in that it has an almost perfect cylindrical shape obtained by machining.

10. Coil (1) according to claim 1, 2, 3, 4, 5, 6, 7 or

8, characterized in that the surfaces intended to receive the coolant comprises grooves (80) capable of preventing the formation of a boundary layer of coolant.

11. Magnet characterized in that it comprises at least one coil according to any one of the preceding claims.

12. Magnet according to claim 11, characterized in that all the coils (13a-13b, 14a-14b, 15a-15b) have substantially the same inside and outside diameter and are connected to be crossed by the same current and in this that the lengths of the coils, the distances which separate them axially and their outside diameter are determined to give said field homogeneity in said area of interest with an optimized Power-Mass product.

13. Magnet according to claim 11 or 12, characterized in that it comprises a central tube (62) on which the coils (1) are threaded.

14. Magnet according to claim 13, characterized in that between two coils (l) ^ is threaded on the central tube

(62) a cylindrical spacer (64) or a plurality of shims allowing the precise positioning of the coils (1) relative to each other.

15. Magnet according to claim 14, characterized in that the spacers (64) have a passage for passing an electrical conductor for the series connection of the coils (1).

16. Magnet according to claim 11, 12, 13 or 14, characterized in that it comprises a carcass composed of two elements (61) capable of being assembled along a plane containing the z axis.

17. Magnet according to claim 11,12,13,14 or 15, characterized in that the wall of the carcass constitutes the external wall of the coil cooling channel (2).

18. Magnet according to claim 10,11,12,13,14,15,16 or 17, characterized in that the geometry of the cooling channel (2) imposes on the cooling fluid a turbulent flow.

19. Magnet according to claim 10,11,12,13,14,15,16,17 or 18, characterized in that it comprises in the cooling channel (2) a part (6) in the form of a helix forcing the coolant to increase the path traveled in the coolant channel (2).

20. Magnet according to claim

10,11,12,13,14,15,16,17,18 or 19, characterized in that the carcass and the central be (62) are made of plastic materials comprising fibers.

21. Magnet according to claim 11,12,13,14,15,16,17,18,19 or 20, characterized in that it comprises at least one conductor (119) ensuring the return of the current to one axial ends of the magnet, configured (s) and / or arranged (s) to distribute the flow of current longitudinally over a cylindrical surface coaxial with the coils (1) of the magnet.

22. Magnet according to claim 21, characterized in that the conductors (119) ensuring the return of the current are made of copper or aluminum.

23. A nuclear magnetic resonance imaging device, characterized in that it comprises a magnet according to claim 10,11,12,13,14,15,16,17,18 or 19.

24. An imaging device according to claim 23, characterized in that it further comprises an auxiliary magnet (13) thermally coupled to said coolant circulation circuit and electrically powered by said power supply means, said auxiliary magnet being of small dimensions compared to said main magnet to create a control field representative of the main field in a restricted volume, the auxiliary magnet (13) comprising at least one coil according to claim

1, 2, 3, 4, 5, 6, 7, 8, 9 or 10, in that it further comprises means (20) for measuring the control field placed in said restricted volume and a control chain for said supply means, controlled by said means for measuring the control field.

25. A method of manufacturing a magnet, characterized in that it comprises a step of bonding with an adhesive (4) insulating discs (3) or part of discs constituting a coil (1) in a helix.

26. The method of claim 25, characterized in that it comprises a step of butt welding of discs (3) or part of discs (3) constituting a coil (1) in a helix.

27. The method of claim 26, characterized in that the solder is a solder of copper on copper.

28. The method of claim 26, characterized in that the weld is an indum weld.

29. Method according to claim 25, 26, 27 or 28, characterized in that it comprises a step of machining the windings (1) on their internal and / or external surface.

30. Method according to claim 29, characterized in that the machining makes it possible to obtain a smooth cylindrical surface.

31. Method according to claim 29 or 3, characterized in that the machining makes it possible to obtain a grooved surface capable of preventing the formation of an immobile boundary layer of cooling fluid.

32. Method according to claim 25, 26, 27, 28, 30 or 31, characterized in that it alternately comprises the steps of:

- mounting of windings (1) on a central tube (62), - mounting spacers (64) on the central tube.

33. Method according to claim 32, characterized in that the dimensions of the tubes and spacers (64) make it possible to optimize the product P. M where P is the electric power to be supplied to the magnet (11), M is the conductor mass of the magnet (11), for required homogeneity of the magnetic field.