DE3445724A1 - MAGNETIC FIELD COIL FOR AN NMR COMPUTER TOMOGRAPH - Google Patents

Description

HOFFMANN. EITtIE "PARTNER" · '3445724

PATENT AND LAWYERS

PATENTANWÄLTE DIPL.-ΙΝΘ. W. EITLE DR. RER. NAT. K. HOFFMANN DIPL.-ING. W. LEHN DIPL.-ING. K. FDCHSLE DR. RER. NAT. B. HANSEN. DR. RER. NAT. HA. BRAUNS ■ DIPL.-ING. K. QORG

. K. KOHLMANN ■ LAWYER A. NETTE

- 3 - 41 235 q / gt

MITSUBISHI DENKI KABUSHIKI KAISHA Tokyo / JAPAN

Magnetic field coil for an NMR computer tomograph

The present invention relates to a magnetic one Field coil arrangement of a nuclear magnetic resonance device for a computer tornograph (im hereinafter referred to as NMR-CT) and in particular to an NMR-CT with improved reliability.

1 to 3 show an example of a conventional device of this type, FIG. 1 being a perspective view of a conventional gradient field coil structure, FIG. 2 is a perspective view of an RF coil structure, and FIG. 3 shows the construction of a magnetic Coil for NMR-CT shows, the latter consisting of the gradient field winding structure and the RF coil structure is composed. In these figures, the gradient field winding 10 is provided with a gradient field G ^ coil 1, which consists of four coils, which are carried by a coil support frame 4, the magnetic Create a field with the gradient in the X direction. Furthermore, a gradient field G coil 2 is provided, which consists of four coils that generate the magnetic field with the gradient in the direction perpendicular to the X-direction.

ARABELLA STREET 4. D-8OOO MUNICH 81 TELEPHONE CO89} 911O87. TELEX 5-29619 Cf ³ ATHEJ ■ TELECOPIER 91 S £

In addition, a gradient field G _z coil 3 is provided, which consists of two coils in order to generate the magnetic field with the gradient in the Z direction (perpendicular to the X and Y directions). The magnetic field with the gradient in an arbitrary direction can be generated by appropriately controlling the currents flowing through the G coil 1, G _v coil 2, and G coil 3.

As shown in Fig. 2, within the coil structure-10- -toor 10 an RF coil 20 is provided. With reference to FIG. 3 It can be seen that the RF coil 20 is composed of a cylindrical support frame 40 on which a so-called saddle coil 5 is arranged. A uniform field coil structure 6 is also special for generating one uniform magnetic field provided in the Z direction. Although the uniform field coil structure 6 in 3, arranged outside the gradient field coil structure 10, can, if so desired is, the coil structures 6 and 10 in their position be exchanged with each other.

In operation, the part of the body, ' which is to be tested, arranged within the RF coil structure 20 in order to receive an NMR signal therefrom Fig. 4 shows the determination of a tomographic plane by a human head. Fig. 4 shows a continuous line, the relationship of the position of the head to a magnetic field with the intensity B "in the Z-direction, which is the sum of a gradient field and a particularly uniform field.

Assume a disk of the head with a center line at Z and a thickness of J [Z] . the

34A5724

Intensity of the magnetic field in which the disk is arranged is between {B " _n - --4B ₁₇ ) and (B" q + 2 "4B-). Therefore, the resonance frequency of a substance (protons) in the disk is from which the NMR signal is obtained, within a range between O ~ I ^4B z ^{) to} ^ ^(B Z0 ⁺ Ί ^ΔΒ Ζ * ' ^{where is the} gyromagnetic ratio. Coil structure 20 is generated and whose frequency components are within the above-mentioned range is additionally applied to the disk, only protons in the disk are excited and absorb energy As already mentioned, it is necessary to determine a specific slice plane of the head to apply an RF field with a frequency in the constant range and a gradient field to the head or other body parts to be tested place.

In order to generate an RF field whose frequency range extends from V (B ₂₀ - 1 Δ B ₂ ) to Y (B ₂₀ + ^ · ΔΒ _Ζ ), a current is applied to the RF coil, which is generated by modulating a sinusoidal current with a frequency T (B ₂₀ ) is obtained. The modulation to be applied is selected so that a frequency spectrum is obtained by Fourier transforming a current waveform modulated thereby within the

1 1

Frequency range from Y (B ^ _n - 0-AB ₁₇ ) to Y (B _17n + 0-AB ₁₇ ) falls.

Fig. 5 shows the RF field and an example of the current waveform, which flows through the G coil to create the gradient field in the Z direction. The abscissa shows the time. In Fig. 5, the G “coil current is

put the RF field inverted, so that the phase of the excited Protons is made uniform or uniform. ·

The gradient field coil structure 10 shown in FIG. 1 and the RF coil structure 20 shown in FIG. 2 is shown, are arranged coaxially as shown in FIG. 3 can be seen. If the coil structures 10 and 20 are ideal are established and arranged, there is no electromagnetic coupling between them, which is necessary for the in 5 is the case. However, from a practical point of view, it is impossible to make them ideal and to arrange, with the result that electromagnetic coupling between them is inevitable.

The sequence of such electromagnetic coupling is shown in Fig. 6, which shows the actual waveforms obtained by a conventional magnetic field coil structure for an NMR-CT. This means that if the RF coil is energized in a pulsed manner while the G "coil is energized, an RF pulse voltage is induced in the G-coil, as a result of which the G ₇ coil current changes. Due to the change of the G "-Spulenstromes a gradient field, which is within the range (B ₂₀ - B 2 Δ ₂₎ to (B _zo + 2" is ZLB _2), and to the body

2- Δ B ₂ ) to (B _zo

parts are created that are not the disk with the thickness at the center Ζ ,,. That means that protons are outside of the disk are also applied and that the obtained NMR signal information is not only of the desired Disc but also from areas around the disc contains. This leads to disturbances and blurring in the Tomogram.

3U5724

It is therefore the object of the present invention to create a magnetic field coil structure for an NMR-CT, which has an RF coil and a gradient field coil, between which there is no high-frequency electromagnetic coupling and consequently an exact determination of the plane of the slice supplies.

Therefore, according to the present invention, this object is achieved by providing a magnetic field coil structure for an NMR-CT which has a shielding layer made of an electrically conductive material is in the form of a cylinder, which is at least ■ inside or outside the gradient field coil is arranged.

.

The drawings are described below. Show it

1 is a perspective view of a conventional gradient field generating coil, 20th

2 is a perspective view of an RF field generating coil;

3 is a cross-sectional view of a magnetic field coil structure for an NMR-CT.

4 shows the basic features for determining a slice plane for NMR tomography,

Fig. 5 ideal waveforms of an RF field and the

Current flowing through the gradient coil,

FIG. 6 shows similar waveforms compared to those of FIG. 5 for a current case,

9 <Φ <t ww «u

3Α4572Λ

7 shows a perspective view of a gradient coil which is designed as a preferred embodiment of the present invention, and FIG
5

Figures 8, 9 and 10 are perspective views of gradient coils for other embodiments of the invention.

According to Fig. 7, which is a perspective view represents a coil structure 10 for generating a gradient field to illustrate a preferred one Embodiment of the invention, is a cylindrical shielding layer 7, which is made of electrically conductive Material consists around a cylindrical Spulenträ- ■ frame 4 arranged. Gradient field generating coils 1, 2 and 3 are on the outer surface of the shield layer 7 provided.

The thickness t of the shielding and protective layer 7 is selected so that it satisfies the following conditions

δ (fRp) <t «6 (f _G ),

where f _R "is the frequency of the RF magnetic field, f_, a control frequency for the coil structure 10 for generating the gradient magnetic field and δ (f) is the depth of penetration given by the expression

2p
.

is shown, where p is the resistivity of the shielding layer, f is the frequency and μ is the permeability of the shielding layer.

b W Λ »A« 4

That is, when the thickness of the shielding layer is made equal to or greater than the penetration depth which is determined by the RF field frequency and the resistivity of the shielding layer, but smaller than the penetration depth which is determined by the gradient field control frequency and the resistivity of the shielding layers The RF field, which is generated by an RF coil 20 and penetrates the ramp field coil 10, is shielded by eddy currents that are generated in the shielding layer 7. In this way, the change in the gradient field coil current due to the RF field is eliminated. ■ This makes it possible to precisely determine the pane boundaries. Since, on the other hand, the thickness t of the shielding layer 7 is sufficiently smaller than the penetration depth o ″ ( _fr ), which is linked to the gradient field coil control frequency, the gradient field is not electromagnetically shielded by the layer 7.

For the values:

f _RF

f_ = 1 KHz

f _RF = 10 MKz,

P = 2.7 x 10 Ω in

P - 4 * χ 10 H / m

δ (f _RF ) = 27 µm and δ (f _G ) = 2.6 x mmr

S [f) results as:
30th

"RF '

= 27 µm <t << 6 (f ") = 2.6 mm.

B V * * ti *

- ₁₀ - 3 4 A b 7 2

Thus, a suitable value for <f (f _RF ) is, for example, 30 μm.

Although in the previous embodiment the shielding layer 7 is arranged inside the gradient field coil structure 10, it is possible to place it outside the gradient field coil structure 10 to be arranged, as can be seen from Fig. 8 or within the coil support frame 4, as can be seen in FIG. In addition, when shield layers on both sides of the gradient field coil structure are arranged, the shielding effect can be further improved.

10 shows a perspective view of a ramp field coil structure according to another exemplary embodiment of the invention. In FIG. 10, a shielding layer 7 is applied to the gradient field coil structure, namely by wrapping a thin conductive tape of the desired thickness around it. Adjacent edges of the turns of the tape overlap. It is possible to use a conductive tape · ■ 'with a thickness smaller than the penetration depth ε (f _R p), which tape can be wound in an overlapping manner on the gradient field coil structure to form a multilayered shielding layer whose thickness is the same or greater than the penetration depth o "(f _RF ). A metal grid can be used to form a shielding layer 7.

As mentioned earlier, is a cylindrical shielding layer on at least one side of the gradient field coil structure provided so that a high frequency electromagnetic coupling between the RF coil and the gradient coil is eliminated with the consequence that. the plane of the slice can be precisely determined.

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Claims (5)

PATENT AND LAWYERS PATENTANWÄLTE DIPL.-ΙΝβ. W. EITLE. DR. RER. NAT. K. HOFFMANN DIPL.-INQ. W. LEHN DIPL.-INa. K. FDOHSLE DR. RER. NAT. B. HANSEN ■ DR. RER. NAT. HA. BRAUNS DIPL.-ING. K. GOR6 DIPU-INe. K. KOHLMANN · LAWYER A. NETTE 41 235 g / gt MITSUBISHI DENKI KABUSHIKI KAISHA
Tokyo / JAPAN Magnetic field coil for one NMR computed tomography PATENT CLAIMS: Coil arrangement for generating a magnetic field for use in a: nuclear magnetic
Resonance device for computed tomography (NMR-CT), characterized by a coil arrangement for generating a gradient field, composed of a field-generating coil device for generating a magnetic field with the gradient in the X direction, a coil device for generating a gradient field for generating a magnetic field with the gradient in the Y direction perpendicular to the X direction, and a coil device for generating a gradient field for supplying the magnetic field with the gradient in the Z direction perpendicular to the X and Y directions, an arrangement for Creation of a uniform field in the Z-direction, • an RF coil arrangement, which is inside the coil structure for supplying the uniform or uniform field and the coil structure for generation of the gradient field is arranged, and a cylindrical shielding layer (7), which consists of a ARABELLA STREET 4. D-8OOO MUNICH 81 TELEPHONE (Ό893 911O87 TELEX 5-29619 CPATHEJ TELECOPIER 918S electrically conductive material is made, which on at least on the inside or the Outside "of the coil arrangement for generating the gradient field is arranged. 2. Magnetic coil arrangement according to claim 1, thereby g.ekenn2; shows that the shielding layer (7) has a circular cross-section. 3. Magnetic 'coil arrangement according to claim 1, characterized in that the shielding layer (7) is formed by winding a conductive tape, with the edge areas of adjacent turns overlap. 4. Magnetic coil arrangement: according to Claim 1, characterized in that the shielding layer (7) has a metal grid. 5. · Magnetic coil arrangement .according to claim '! 1 , characterized in that the thickness of the shielding layer (7) is equal to or greater than that The penetration depth is determined by the RF field frequency and the resistivity of the shielding layer and is smaller than a penetration depth determined by the gradient field control frequency and the specific resistance of the shielding layer is determined.