DE10138712A1 - Magnetic resonance device with a movable gradient coil unit - Google Patents

Abstract

A magnetic resonance device includes the following features: DOLLAR A - an examination room (40) for storing at least one area of an examination object therein, DOLLAR A - a gradient coil unit (60) that can be moved into the examination room (40) in a direction of travel (65), DOLLAR A - one Component of the magnetic resonance device surrounding the examination room (40) and means arranged between the examination room (40) and the component, with which the gradient coil unit (60) can be supported against the component in at least one position in the magnetic resonance device, or DOLLAR A means with which the gradient coil unit (60) can be fixed at least in one position in the magnetic resonance device and the means and the gradient coil unit (60) are designed in such a way that the means can be actuated by moving the gradient coil unit (60).

Description

The invention relates to a magnetic resonance device.

Magnetic resonance technology is a known technique for ge obtaining images of the inside of an examination object jekts. In this case, a stati basic magnetic field, which is generated by a basic field magnet is generated, quickly switched gradient fields are superimposed, generated by a gradient system. Also includes the magnetic resonance device is a radio frequency system that is switched off solve magnetic resonance signals high frequency signals in the Examination object shines, and the triggered magnetre records sound signals, based on which magnetic resonance images to be created.

The magnetic resonance device has an imaging volume in which is an area of the object to be mapped to Creation of magnetic resonance images of the image to be imaged is to be positioned empire. This includes magnetic resonance gets a position that can be moved at least in one direction tion device on which the examination object is stored can be. Here is a process of moving Storage device including the Untersu stored thereon the positioning of the area to be imaged in the Imaging volume possible.

For example from US 5,185,576 is a so-called loka le gradient coil unit known with a local High frequency antenna is combined. The local gra serving coil unit with integrated local high frequency tenne for a special area of the object to be examined, for example, the head of a patient. Thereby is the local gradient coil unit compared to the fixed  built-in gradient coil system with smaller dimensions executable, which among other things regarding achievable Gra strengths of service and performance requirements for a Gra Serving coil unit feeding gradient amplifier advantages brings. The local gradient coil unit with integrated Local radio frequency antenna is able to do this Fixing device attachable that the local gradients tens coil unit even when operating the magnetic resonance device and the forces acting on them not against the situation Moving device moves.

In some embodiments of local gradient coils units to prevent them from moving securely the local gradient coil unit in the magnetic resonance device and vice versa the subsequent releasing of the local gradient coil unit up to hours. there is a full body antenna of the in some embodiments Removing and reinstalling the magnetic resonance device. Among other things The long set-up times described above require one low user friendliness, so far local gradients tensile coil units almost exclusively in research and not be used in clinical routine.

An object of the invention is to provide a magnetic resonance device create where the use of a locally deployable Gradient coil unit, among other things, a high degree of loading has ease of use.

The object is achieved by the subjects of Claims 1 and 8 solved. Advantageous configurations are described in the subclaims.

By arrangements according to claims 1 and 8 a high degree of user friendliness combined with a lot short set-up times, to make the gradient track ready for use unit achieved. Installation and removal of a whole body  for preparing the gradient coil unit completely eliminated.

In an advantageous embodiment, the magnetic reso comprises a permanently installed gradient coil system and the Means are designed such that the movable gradients tens coil unit for fixing against the gradient coil system system is supported. This removes the from the movable Gradient coil unit outgoing forces directly on the built-in gradient coil system transmitted by From home is better suited to absorb the aforementioned forces take as for example a full body antenna leading to the should be additionally stiffened for this purpose. Furthermore the whole-body antenna is not affected by possible movement conditions of the movable gradient coil unit.

In an advantageous embodiment, the magnetic reso comprises Nanzgerät a movable storage device based on egg ner guide device of the magnetic resonance device movable is, and the movable gradient coil unit is on the same guide device designed to be movable. there In one embodiment, the examination room has little at least two opposite openings so that the location Rungsvorrichtung from one opening and the movable right gradient coil unit from the other opening into the Exam room can be moved. Thereby he opens up a time-efficient use of the magnetic resonance device with the gradient coils during the process the object to be examined, for example a patient the storage device is stored. After storing the The patient and the positioning device will then be presented entered the examination room on stored patients where the gradient coil unit is already correctly positioned waited and fixed.

Further advantages, features and details of the invention he result from the implementation described below play with the drawing. Show:

Netresonanzgeräts standardized Fig. 1 is a longitudinal section through an upper half of Mag with a movable Gradientenspulenein,

Fig. 2 shows an enlarged detail shown in FIG. 1,

Fig. 3 shows a cross section through a whole-body antenna shown in Fig. 1 including a movable Lagerungsvor direction and

Fig. 4 shows an enlarged detail shown in FIG. 3.

Fig. 1 shows as an embodiment of the invention, a longitudinal section through an upper half of Magnetreso nanzgeräts with a movable gradient coil 60th To generate a static basic magnetic field, the magnetic resonance device comprises an essentially hollow cylindrical superconducting basic field magnet 10 . In the cavity of the basic field magnet 10 , a likewise essentially cylindrical gradient coil system 20 for generating gradient fields is permanently installed. The built-in gradient coil system 20 comprises three gradient coils, shielding coils belonging to the gradient coils, cooling and shim devices. In the cavity of the gradient coil system 20 , in turn, a substantially hollow cylindrical whole-body antenna 30 for transmitting high-frequency signals and for receiving magnetic resonance signals is permanently installed, where, in the case of a hollow of the whole-body antenna 30 , essentially an examination space 40 for storing at least a region of an examination object therein, for example of a patient. The movable gradient coil unit 60 can be moved at least into a part of the examination room 40 . The gradient coil unit 60 for generating gradient fields comprises at least one up to three gradient coils and, depending on the application requirements, shield coils, cooling and shim devices associated with the gradient coils and / or is combined with a local high-frequency antenna.

The whole-body antenna 30 is formed as a carrier for means with which the movable gradient coil unit 60 can be fixed at least in one position in the radial direction. The means comprise at least six thereby Fixiervor devices 70 a, 70 b, 70 c and 70 x, each about an axis arranged in the whole body antenna 30 axis of rotation 75 a and 75 c are mounted. Here, three of the fixing devices 70 a, 70 b and 70 c are arranged on a first and the other three fixing devices 70 x on a second circumferential line of the whole-body antenna 30 evenly distributed over the circumference.

The fixing devices 70 a, 70 b, 70 c and 70 x and the ver movable gradient coil unit 60 are designed such that in a method of the gradient coil unit 60 according to the direction of travel 65 marked with a double arrow from the right into the examination space 40, the fixing devices 70 a , 70 b, 70 c and 70 x are automatically actuated by the movement process of the gradient coil unit 60 and at the same time define an end position of the movable gradient coil unit 60 shown with broken lines. For this purpose, the gradient coil unit 60 has on its outer side at locations which correspond to an arrangement the fixing devices 70 a, 70 b, 70 c and 70 x are arranged, each because a nose-like elevation 61 a and 61 x in connection with a recess 62 a and 62 x. Thus, the fully extended out of the examination space 40 gradient coil unit 60 can be retracted from the right properly in the examination room 40 to the end position, which is arranged on the left side of the gradient coil unit 60 elevations 61 a and depressions 62 a, for example, centerless formed closer than in the area of Elevations 61 x and depressions 62 x arranged in the middle of the gradient coil unit 60 . As a result, when moving in from the right, the fi xing devices 70 x are not immediately actuated by the elevations 61 a and depressions 62 a, but can be moved in front of them. Of course, this also requires a corresponding arrangement or design of the Fixiervorrichtun conditions 70 a, 70 b, 70 c and 70 x.

A more detailed description of the structure of one of the Fixiervor devices 70 a, 70 b, 70 c and 70 x and their effect in conjunction with the movable gradient coil unit 60 he follows with reference to FIG. 2, which is an enlarged view of the in Fig. 1 with A designated section shows. The fixing device 70 a is pivotally mounted about an axis of rotation 75 a in the whole-body antenna 30 . The fixing device 70 a has a symmetrical shape with respect to the axis of rotation 75 a, a first and a second cam 71 and 72 , the first cam 71 , for example by training from a high density material, a greater weight than the second cam 72 has, so that the position of the fixing device 70 a shown with solid lines automatically adjusts when the gradient rinsing unit 60 is not or not completely retracted. In a retraction of the movable gradient coil unit 60 from the right in the Un tersuchungsraum 40 receives the elevation 61 a of Gradientenspu leneinheit 60 the second cam 72 and causes the Fi xiervorrichtung 70 a around its rotation axis 75 a in a Drehbewe supply until the first cam 71 in the position indicated by dashed lines presses against the permanently installed gradient coil system 20 . Then the movable gradient coil unit 60 is locked in the radial direction against the built-in gradient coil system 20 .

The permanently installed gradient coil system 20 is due to its cast resin potting, its design as a hollow cylinder with a large wall thickness and its attachment in the basic field magnet 10 well suited to absorb the pressure loads by the fixing devices 70 a, 70 b, 70 c and 70 x. To remove the movable gradient coil unit 60 from the examination space 40 , the gradient coil unit 60 is to be moved to the right in the direction of travel 65 . The gradient coil unit 60 can be moved both manually and with the aid of a motor drive. The not agile for a supply of the gradient coil 60 power cables and possibly cooling supply lines are the gradient coil 60 thereby supplied from the right.

Fig. 3 shows a cross section through the whole body antenna 30 of FIG. 1 in the area of the fixing devices 70 a, 70 b and 70 c including a movable bearing device 50 . In FIG. 3, the uniform distribution of the three fixing devices 70 a, 70 b and 70 c already described in FIG. 1 is illustrated over the circumference with 120 ° curved arrows. With the movable storage device 50 , it is possible to introduce the examination object, for example the patient, stored on the storage device 50 with respect to the longitudinal section shown in FIG. 1 from the left into the examination room 40 . The bearing device 50 is movably mounted on a guide system 55 . In one embodiment, the movable Gradientenspu leneinheit 60 is designed to be movable on the same guide system 55 , which is particularly problematic with a weight of the Gradien tenspuleneinheit 60 , which is approximately less than a permissible load weight of the bearing device 50 . Special measures must be taken only when the gradient coil unit 60 has a weight of greater than approximately 200 kg.

FIGS. 4, finally, shows the detail marked in Fig. 3 with B in an enlargement. With the Fig. 4, the construction and arrangement will be of about the rotational axis 75 c 70 c pivotally mounted fixing device in the operative Ganzkör antenna 30 again illustrates.

Finally, existing magnetic resonance devices can also be converted into a magnetic resonance device with a movable gradient coil unit 60 according to FIG. 1 in a simple and cost-effective manner. All that is required is to exchange a whole-body antenna of the existing magnetic resonance device for a previously described whole-body antenna 30 with fixing devices 70 a, 70 b, 70 c and 70 x, and to add the movable grain coil unit 60 .

Claims (19)

1. Magnetic resonance device, comprising the following features:

• - an examination room ( 40 ) for storing at least one area of an examination object therein,
• - a gradient coil unit ( 60 ) which can be moved into the examination space ( 40 ) in a direction of travel ( 65 ),
• - A component of the magnetic resonance device surrounding the examination room ( 40 ), and
• - Between the examination room ( 40 ) and the component to ordered means with which the gradient coil unit ( 60 ) can be supported for fixing in at least one position in the magnetic resonance device against the component.

2. Magnetic resonance apparatus according to claim 1, wherein the component is designed such that the gradient coil unit ( 60 ) can be supported against it. 3. Magnetic resonance device according to one of claims 1 or 2, wherein the component comprises a built-in Gradientenspu lensystem ( 20 ) of the magnetic resonance device. 4. A magnetic resonance apparatus according to one of claims 1 to 3, wherein the magnetic resonance apparatus a between the investi monitoring space (40) and the component arranged Ganzkörperan antenna (30), which is designed such that with support tel by the whole-body antenna (30) through can. 5. The magnetic resonance apparatus according to claim 4, wherein the whole body antenna ( 30 ) for supporting the gradient coil unit ( 60 ) against the component has at least one opening. 6. Magnetic resonance device according to one of claims 4 or 5, wherein the whole-body antenna ( 30 ) is designed as a carrier for the means. 7. A magnetic resonance apparatus according to one of claims 1 to 6, wherein the means and the gradient coil unit (60) are formed of the art that tenspuleneinheit by a method of Gradien (60) the means are actuated. 8. Magnetic resonance device, comprising the following features:

• - an examination room ( 40 ) for storing at least one area of an examination object therein,
• - a gradient coil unit ( 60 ) which can be moved into the examination space ( 40 ) in a direction of travel ( 65 ),
• - Means with which the gradient coil unit ( 60 ) can be fixed at least in one position in the magnetic resonance device, and
• - the means and the gradient coil unit (60) are formed such that by a method of gradient coils unit (60) which means are actuated.

9. A magnetic resonance device according to claim 8, wherein the magnetic resonance device comprises a whole-body antenna ( 30 ) and the whole-body antenna ( 30 ) is designed as a carrier for the means. 10. Magnetic resonance device according to one of claims 8 or 9, wherein the magnetic resonance device comprises a permanently installed Gra serving coil system ( 20 ) and the means are formed such that the gradient coil unit ( 60 ) is supported for fixation against the gradient coil system ( 20 ). 11. A magnetic resonance device according to one of claims 1 to 10, wherein the means and the gradient coil unit ( 60 ) are designed such that the means for the direction of travel ( 65 ) effect an end position of the gradient coil unit ( 60 ). 12. A magnetic resonance apparatus according to one of claims 1 to 11, wherein the means comprise at least one fixing device ( 70 a, 70 b, 70 c, 70 x) which can be pivoted about an axis of rotation ( 75 a, 75 c). 13. A magnetic resonance apparatus according to claim 12, wherein the fi xing device ( 70 a, 70 b, 70 c, 70 x) is symmetrical with respect to the axis of rotation ( 75 a, 75 c). 14. Magnetic resonance device according to one of claims 12 or 13, wherein the fixing device ( 70 a, 70 b, 70 c, 70 x) on both sides of the axis of rotation ( 75 a, 75 c) each has a cam ( 71 , 72 ). 15. The magnetic resonance apparatus according to claim 14, wherein one of the cams ( 71 ) has a greater weight than the other of the cams ( 72 ). 16. Magnetic resonance apparatus according to one of claims 12 to 15, wherein at least three fixing devices ( 70 a, 70 b, 70 c) are arranged approximately uniformly distributed along a circumference of the examination room ( 40 ). 17. A magnetic resonance apparatus according to one of claims 1 to 16, wherein the magnetic resonance apparatus device comprises a movable storage (50) and a guide device (55) on which the storage device (50) is movable comprises, and the gradient coil unit (60) on the guide device (55 ) is designed to be movable. 18. Magnetic resonance apparatus according to one of claims 1 to 17, wherein the examination room ( 40 ) has at least two opposing openings and a movable position device ( 50 ) from one opening and the serving coil unit ( 60 ) from the other opening into the Examination room ( 40 ) can be moved into it. 19. Magnetic resonance apparatus according to one of claims 7 to 18, wherein a surface of the gradient coil unit ( 60 ) for actuating the means has at least one nose-like elevation ( 61 a, 61 x) in connection with a recess ( 62 a, 62 x).