DE3444388A1 - Gradient coil assembly for use in an imaging system operating with nuclear spin resonance - Google Patents

Abstract

In general, the invention relates to an imaging system operating with nuclear spin resonance for medical diagnostic purposes. In such a system, a current pulsed at a low frequency is applied to the gradient coils used for establishing the respective image section plane in the object examined (patient), as a result of which mechanical forces are exerted on the coils and the supporting body carrying them, with a frequency which is within the audible range and which become noticeable as a disturbing noise. This noise generation is to be reduced as much as possible by the invention. <??>A construction of the support or carrying body for the gradient coils is described in the form of an essentially cylindrical part in which annular parts and connecting parts connecting these annular parts to one another in the axial direction are machined out by means of suitable recesses, the annular parts being used for supporting and holding the legs of the gradient coils which are mainly active. Due to this configuration, in connection with the manufacture of the support body of a noise-absorbing material, an extensive reduction in the interferring noise generated is achieved.

Description

Patent Attorneys Dipl.-J .-. G. Curt Wallach

European patent representative -3- Dipl.-Ing. Günther Koch

European Patent Attorney _S 3 444388 Dipl.-Phys. Dr Tino Haibach

Dipl.-Ing. Rainer Feldkamp

D-8000 Munich 2 Kaufingerstraße 8 Telephone (0 89) 2 60 80 78 Telex 5 29 513 wakai d

Date: Dec 5, 1984

Our reference: 18072 H / Bu

Oxford Magnet Technology, London, England

Gradient coil unit for use in a nuclear magnetic resonance system Imaging system

The invention relates to imaging systems using atomic nuclear resonance for use in diagnostic medicine. The principles of resonance excitation of atomic nuclei using magnetic fields are known. Atomic nuclei that placed in a strong magnetic field and stimulated with a certain high frequency emit measurable RF signals. This phenomenon distinguishes all stable atomic nuclei, which have an odd number of protons or neutrons or both. These particles have two important properties, a spin moment and a magnetic moment and they can be compared to a rotating magnetic top.

Almost two thirds of all stable atomic nuclei have spin and magnetic moments. The hydrogen nucleus, or that Proton, is the simplest nucleus of this type. It is also the most common element in the human body, since approximately two thirds of the human body is made up of water.

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When imaging (fluoroscopy) using magnetically induced nuclear resonance, the patient is exposed to three different energy sources at the same time:

1. A high strength static magnetic field

2. a time-varying or gradient magnetic field of significantly lower strength as well

3. the high-frequency magnetic field

1) The magnetic field of high field strength affects the protons in the patient's body. Without this field the protons would be oriented randomly randomly; When introduced into the magnetic field, the protons are either aligned with the magnetic field or opposite to it (there is no intermediate state) _r and more protons are in alignment with the magnetic field than opposite, as their energy state favors this. Since there are more protons in alignment with the field than oppositely, there is magnetization in the general direction of the magnetic field, and in a state of equilibrium the magnetization is in alignment with the magnetic field in a manner similar to that of a compass needle in the earth's magnetic field. If the protons are deflected from the direction of the magnetic field, they do not return directly to the state of equilibrium, but rather they rotate in constantly decreasing circles around the direction of the magnetic field, just like gyroscopes under the action of a force pulse perform a precession movement. The behavior of the protons during the decay of the precession provides information about the type of material in the section being examined,

and this information is reproduced in the form of an image for medical examination.

The high strength magnetic field is generated by a super-conductivity magnet generated. This consists of a hollow cylindrical container containing the magnet, the Is hermetically sealed and in which the superconducting magnet is in liquid helium at about 4 K. is operated.

2) The time-varying or gradient magnetic field is

generated by windings, by means of which the gradient field can be superimposed on the main field, creating flat image sections can be placed through parts of the patient's body. These windings typically include X, Y and Z-gradient coils and the relevant required windings can have a field gradient perpendicular to them create the desired image section plane.

As soon as the RF signal is applied, the necessary resonance conditions for the excitation of the nuclei are only in the fulfills a plane that is to be examined, while the remaining part of the patient's body has the magnetic field and the frequency required for resonance is either too large or too small.

3) The high-frequency magnetic field ("radio frequency magnetic field") is generated by further windings. The frequency is chosen in the sense of a resonance excitation of the nuclei; As described above, this field deflects the nuclei from the direction of the main magnetic field, whereby a Precession is caused.

The high-frequency coils are arranged on a cylindrical form or template body, and this The unit fits into the cylinder shape of the X, Y and Z coils.

The gradient coils are subjected to a pulsed direct current of approximately rectangular pulse shape, with the Current flow duration (pulse duration) is different from the time during which the current is zero (pulse pauses). Of the Current is pulsed with a frequency in the range from 1 Hz to 20 Hz, with the respective actual frequency going through the overall control and regulation system of the imaging device is adjusted to match the operating requirements of the system will.

When a pulsed current passes through a conductor that is transverse to a magnetic field, a pulsating force exerted; and it may be necessary to mechanically hold and support the conductor against this force. In the case of the gradient coils, the forces generated by the pulsating current are large enough to Vibration of the coils and a deflection or deformation of the mold or template body to cause an oscillation.

This phenomenon works in the sense of generating a noise with the frequency of the pulsating current, which is therefore in the audible area, albeit at the lower end, and is often intrusive and annoying for patients and operating staff. The object and purpose of the present invention is to provide a gradient coil unit in which the from this source resulting noise is significantly reduced.

The invention thus relates to a gradient coil unit

for use in a nuclear magnetic resonance imaging system.

According to the invention is a support or support body for the Gradient coils serving shaped or template body provided, which several ring parts, each at least support one of the mainly effective legs of a gradient coil, and several generally extend in the axial direction of the magnet extending, the ring parts having interconnecting connecting parts.

According to one embodiment of the invention, they are flexible Hdterungen for the gradient coil carrier or support body provided, whereby the noise transmission is reduced.

According to a further embodiment of the invention, the gradient coil support or carrier body is made of a sound-absorbing one Material made.

In the following, exemplary embodiments of the invention are based on the drawing described; in this show

1 shows a front view of a magnet arrangement for use in diagnostic medicine,

Fig. 2,

3 and 4 in front view, front view and top view, a gradient coil unit for the Magnet arrangement from Fig. 1,

5 in a schematic, perspective view the windings of the gradient coils of the unit from FIGS. 2 to 4.

According to FIG. 1, the magnet arrangement has a cylindrical hollow body 10, which is in liquid helium contains about 4 K powered superconductivity magnets. After starting up the magnet and as soon as current is circulating in it, - depending on the construction, design and operating conditions the magnet arrangement - a magnetic field between 0.2 T and 2.5 T is generated. In the container 10 is a gradient coil unit 11 is arranged concentrically, and in turn concentrically in this gradient coil unit 11 an HF coil unit 12.

As can be seen from FIGS. 2 to 4, the unit has a cylindrical shaped or template body 15, on which a set of X coils 16, a set of Y coils 17 as well a set of Z-coils 18 are wound. The X-coils and the Y-coils each comprise two diametrically opposite one another arranged winding sets; the X and Y coils are essentially similar in shape and magnetic strength

and differ only in that they are circumferential are arranged offset from one another by 90.

Fig. 3 shows a side view of the X coils, with the Y coils are removed for the sake of clarity. It is a winding 20 of the two diametrically opposite one another Sets of windings of the X coils visible. The winding 20 consists of a single piece of conductor of rectangular shape Cross section wound into two substantially rectangular sets of turns 21 and 22, which are arranged along the mold or template body at an axial distance from one another. The conductor turns are adapted to the cylindrical shape of the template body 15. .

The rectangular turns 21 each have opposite rectilinear side pieces 23 and 24, where the individual Turns of the conductor are adjacent to each other. The turns 22 also have such side parts 25 and 26. These conductor side sections 23 to 26 form the main effective legs of the coil and provide in Combination with the main effective legs of the other, diametrically opposed sets of X-windings the gradient field of the X-coil.

In the other opposite sections 27 and 28 and 2 9 and 30, the windings run parallel to the axis of the magnet and are at a mutual distance. They only make a contribution to the magnetic field parallel to the axis of the Magnets, however, do not add to the transverse gradient field.

The ends of the conductor are led out at 31; the ends

the other, diametrically opposed X-windings also visible at 32. Furthermore, the ends 33, 34 of the two winding sets of the Y-coil and the ends 35, 36 of the two sets of windings of the Z-coil (which are described below). In Fig. 3, only one is the X coils shown; the other, diametrically opposite coil is a mirror image of the coil shown, and the two Y-coils are of the same type as the X-coils, the only difference being that they are opposite to these are offset by 90.

In Fig. 5, the current path is shown schematically through one of the windings of the X coils. The successive Sections of the conductor are labeled 40 to 51. The inlet feed line is formed by section 40; the Sections 41 through 44 represent six turns of the conductor on the actual spool; section 45 is used for power supply to the second part of the coil, where the sections 4 6 to 50 turn another six turns of the Reproduce conductor in actual coil; section 51 forms the return line.

The mold or template body 15 is essentially cylindrical. However, the mold or template body four axially spaced annular areas 55 to 58, each of which has the required mechanical holder for two diametrically opposite, mainly effective legs of the X-coil and two diametrically opposite, mainly effective legs of the Y-coils form. The rings are integral with each other by means of Longitudinal spacers 59 connected so that the mold or template body 15 in a simple manner from a

one-piece cylindrical tube can be produced, from which approximately rectangular recesses are cut out, whereby the rings 55 and 58 and the spacers 59 are formed. The mold or template body is off a rigid, non-magnetic material such as fiberglass with resin impregnation, spiral paper wrap with Har impregnation or as a textile resin matrix body. The material for the mold or template body must have high flexural strength and a high modulus of elasticity exhibit. The mechanical storage for the windings is effected by non-magnetic brackets, which the Attach the windings to the mold or template body.

As a result of the inventive design of the form or In the template body, the oscillating magnetic forces generated in the windings of the X and Y coils do not cause any appreciable Propagation of noise. In addition, the mold or template body is made of a sound-absorbing material, whereby any operating noise is muffled. In addition, the entire gradient coil assembly is in the main magnet Mounted on flexible brackets, which also helps to dampen any operating noise.

The Z-coils each include a row of circumferentially wound turns, which are each arranged centrally with respect to one of the X and Y coil centers. The Z coils are each wound from a single conductor, and the supply and return connections are brought out at 60,61. These windings generate a magnetic field in the axial direction; they do not practice any! mechanical ones running in the direction of the diameter Force on the mold or template body, nor do they contribute to any mechanical noise generation.

Claims (7)

Claims 1. Gradient coil unit for use in one with Nuclear resonance working imaging system, characterized by a support or carrier body (15, Fig. 2), which several ring parts (55,56,57,58, Fig. 3), each of which has at least one of the mainly effective legs (23,24,25,26) support a gradient coil, as well as several generally extending in the axial direction of the magnet extending, the ring parts (55-58) interconnecting connecting parts (59). 2. Gradient coil unit according to claim 1, characterized in that that the ring parts (55-58) are flexible holders for the mainly effective legs of the gradient coil form. 3. Gradient coil unit according to claim 1 or 2, characterized in that that the ring parts (55-58) and connecting parts (59) are made in one piece from a single cylindrical part are worked out. 4. gradient coil unit according to one or more of claims 1 to 3, characterized in that the support body has four ring parts (55 - 58) having. 5. Gradient coil unit according to one or more of the preceding claims 1 to 4, characterized in that that the ring parts (55-58) and connecting parts (59) form substantially rectangular openings with one another. 6. gradient coil unit according to one or more of the preceding claims, characterized in that the ring parts (55-58) consist of a sound-absorbing Material are made. 7. gradient coil unit according to one or more of the preceding claims, characterized in that the mainly effective legs (23,24,25,26) the gradient coils are flexibly mounted on the ring parts (55 to 58).