DE3809323C2 - - Google Patents

Description

The invention relates to a shielding cabin for high frequency magnetic fields, especially for Magnetic resonance imaging in medical technology, with at least one metallic screen surface load-bearing wall panels, the butt joints of Joint covers are overlapped with the wall panels are screwed so that on the wall panels attached screen surface pressed against the joint cover becomes.

Such shielding cabins are used to one against Shielded from the emergence of high-frequency magnetic fields To create space, especially for accommodating devices, that generate such high frequency magnetic fields in order to avoid disturbing influences on the environment. A are important areas of application for such shielding cabins Spaces for MRI scanners in the medical technology.

In magnetic resonance imaging, hydrogen atom nuclei become a precession movement, and that by a external high-frequency magnetic field. The one for this The required excitation frequency is a few to around 100 MHz. Because on the one hand with excitation pulses of high amplitude  is worked and on the other hand very sensitive Measuring devices for receiving the weak induced Signal are necessary, the shielding must be high Damping requirements are sufficient.

In addition, such shielding cabins are needed to a room against the ingress of magnetic Shield interference fields, e.g. for implementation of measurements with measuring devices that are opposite are very susceptible to electromagnetic interference, or to shield against magnetic data storage external influences. In principle, these are shielding cabins Faraday cages.

Because such screening cabins have high requirements with regard to the tightness against the passage of electromagnetic interference fields are made like this for example, is the case with magnetic resonance imaging the shielding can be carried out largely without gaps. It is known for this (R. Schaller, G. Siemers "MRI scanners need shielding", magazine "Siemens Components" 22 [1984], H. 4, pp. 160-165), the walls to manufacture shielding cabins from sheet metal parts, for example made of stainless steel or copper, the die individual sheets forming wall panels at their edges welded or soldered for a fixed installation will. The assembly times required for this are relatively long; the completion of the Shielding cabin is labor intensive and therefore expensive. Disassembly for the purpose of later assembly on a another place is difficult.

For a removable construction known in practice are metal sheets at their edges with essentially L- shaped special profiles welded or soldered, whereby those lying together with their angled legs Profiles of adjacent wall elements screwed together  will. This design is also very complex and expensive, especially since there are no standard profiles for the profiles used can be used. Because the parting line is more adjacent Profiles running perpendicular to the wall plane are at high Tightness requirements against leakage of electromagnetic fields additional covers required, which further increase the construction effort.

In other known, removable, but in practice non-self-supporting constructions of shielding cabins the butt joints of adjacent wall panels on both Sides covered by tread strips that are together be screwed and between them the edges of the Clamp wall panels. The resulting conductive Connecting adjacent wall panels is not always sufficient because essentially only a line contact given is. When using high clamping forces the risk of damage to the wall panels. With these Known construction systems are the shield modules at the same time static support of the entire structure.

In a known shielding cabin of the aforementioned Genus (US-PS 37 90 696) is not a load-bearing structure available, which is covered with the wall panels. Instead, there are only strips and elbows as well Intersection pieces are present, which serve as joint covers Overlap butt joints between the wall panels and with these are screwed. This structure creates again butt joints between the individual parts of the Joint covers. These butt joints are particularly in the Area of intersection not with overlap executed and therefore represent interruptions of the Shielding. In addition, the screws protrude through the Joint covers and through holes in the inner Metal cladding of the wall panels and are in Threaded pieces screwed inside the wall panels. Through these screw connections, the joint covers  pressed against the edges of the wall panels; this but only happens at the screw points that in relatively large distances. The Surface pressure is therefore not even; in the areas lying between the screws can become result in relatively large sections in which none there is sufficient surface pressure. The screws themselves contribute to the electrically conductive connection between the Joint covers and the wall panels not because they no close metallic connection with the shielding of the Have wall panels.

The object of the invention is therefore a shielding cabin the genus mentioned in such a way that it an effective and with little installation effort achieving shielding that is also very high Requirements for achievable damping enough.

This object is achieved in that the joint covers a load-bearing structure of the Shielding cabin form that from hollow section beams Aluminum or an aluminum alloy and with the wall plates by means of self-tapping driving screws is covered, in a profile wall of the hollow profile beam are screwed in.

Made from a load-bearing structure Profile beams are achieved that the static forces be absorbed exclusively by this skeleton and do not have to be carried by the wall panels. The Wall panels can therefore be easily and in one for the Shielding effect optimal construction can be carried out. The metallic screen surface of the wall panels is included not exposed to any stress.  

Compared to conventional clamp connections Wall plates with a line contact between the Clamping profiles and the wall panels are used in the shielding cabin according to the invention a flat and solid Contact between the two wall panels on the one hand and the profile beam covering the butt joint on the other reached. By the resulting from the screwing selective connections arise in the intermediate ones Areas of waveguide in the form of slots. These Waveguides are dimensioned so that there are no gaps in the shield. By changing the Distance between the screws and the contact width between the The frequency response of the frame and the screen area can Attenuation can be determined.

The self-tapping driving screws that come in one Profile wall of the hollow profile carrier made of aluminum or one Aluminum alloy are screwed in as electrical connection between the wall panels and the load-bearing framework. The self-tapping Driving screws are screwed into the aluminum or the aluminum alloy is cold welded. Since the self-tapping propeller in the same way electrically conductive connection with the metallic Produces the screen surface of the wall plate, a electrical connection between the hollow profile beam and reached the wall plate, regardless of the size the surface pressure achieved in this area. The intermediate, relatively short sections can be regarded as a waveguide, so that by appropriate choice of screw spacing a targeted predictable damping is enabled.

Since the self-tapping propellers are replaced by a Profile wall of the hollow profile beam are screwed and thus end inside the hollow beam, which in its Longitudinal direction has a waveguide effect is achieved  that from the screw no radiation from the waveguide can come out, even if exceptionally the contact of the screw with the metal should not be sufficient. A Forwarding to the shield is excluded, see above that leaks are avoided.

According to a preferred embodiment of the inventive concept it is provided that the wall panels from a non-metallic base material on which the Screen area is applied. This is the screen area free of all mechanical loads and can therefore be carried out thinly without the mechanical The strength of the wall panels suffers.

The base material for the wall panels can be commercially available Materials are used, preferably made of wood or from a wooden product, for example chipboard.

According to an advantageous embodiment of the The idea of the invention provides that between each the profile beams and the wall panels screwed to them a metallic deformable intermediate layer is arranged, for example made of copper wire mesh or sheet metal Corrugated or corrugated structure. Such intermediate layers are the same Bumps in the distance between the surfaces from and result in defined waveguides.

In addition to single-layer planking of the load-bearing framework with wall panels, it is in a further embodiment of the The concept of the invention is also possible from the load-bearing structure To clad profile beams on both sides with wall panels, the one pressed against the profile beam Have screen area. This means with little Double-walled shielding is also easy producible. Such double-walled shields result higher damping values. With double-sided shielding  also the use of different materials (e.g. Copper and iron) possible, whereby very special Have shielding requirements met. Furthermore lets a variable through the choice of the profiles of the framework Distance between two screen surfaces with double-walled Reach shields, which also causes certain Attenuation curves can be achieved.

Since the profile of the framework always the butt joints of the Overlap wall panels, it is excluded that Butt joints of components of the framework at the butt joints of the screen surfaces come to rest.

Further advantageous embodiments of the The idea of the invention is the subject of further Subclaims.

The invention is described below using exemplary embodiments explained in more detail, which are shown in the drawing. It shows  

Fig. 1 is a partial horizontal section through the vertical butt joint between two wall panels of a shielding cabin, which are bolted to a hollow profile carrier,

Fig. 2 is a comparison with FIG. 1 modified embodiment with an intermediate layer between the wall panels and the hollow profile beam,

Fig. 3 in a representation corresponding to FIGS. 1 and 2, a double-walled shield and

Fig. 4 shows a corner connection with an angular hollow profile.

The drawing shows structural details of the structure of a shielding cabin, which is used, for example, to shield a magnetic resonance scanner in such a way that the emergence of high-frequency magnetic fields is largely prevented. The shielding cabin has a load-bearing structure made of metallic profile beams, for example hollow profile beams 1 made of aluminum, to which wall plates 2 are attached, which form the wall surface of the shielding cabin.

The wall plates 2 butt butt in a butt joint 3 each consist of a base material 4 , for example a chipboard and a metallic screen surface 5 , for example copper foil, attached to it on one side. Instead, other embodiments of the wall panels 2 can also be selected, for example self-supporting metal panels. The edges of the wall plates 2 are screwed to a wall of the hollow profile support 1 by means of screws 6 , for example self-tapping fast construction screws or driving screws, so that the profile support 1 overlaps the butt joint 3 . The supporting framework of the shielding cabin consisting of the profile beams 1 is designed so that all butt joints 3 of all wall panels 2 are overlapped by profile beams 1 .

By means of the screws 6 , which are screwed in at a sufficient mutual distance along the edges of the wall panels 2 , the screen surface 5 is pressed against the profile carrier 1 , which thereby creates a connection between the screen surfaces 5 of adjacent wall panels 2 in the high-frequency range. The contact surfaces of the screen surface 5 with the profile carrier 1 can be smooth or structured, for example roughened. The contact surface of each edge of a wall plate 2 is preferably chosen to be wider than approximately 30 mm. If a narrower overlap is necessary for design reasons, the distance between the screws 6 can be chosen to be smaller, so that a reduction in the damping in this area is avoided by increasing the contact pressure. The materials lying one on top of the other in the contact area are preferably chosen to be easily deformable in order to achieve a very low electrical high-frequency contact resistance. In addition to copper and brass, stainless steel or steel can also be used as materials.

As shown, the framework consisting of the profile beams 1 is preferably made of hollow profiles, aluminum and aluminum alloys having proven particularly useful because of their mechanical and electrical properties. Due to the deformation of the materials in the area of the screws 6 , in particular due to the swelling effect of the aluminum, a good conductive contact is made to the screw, so that the escape of the high-frequency magnetic field in the area of the screws 6 is prevented, especially since this is done by using a hollow profile can be shielded additionally for the profile support 1 . By using self-tapping driving screws 6 , an insulating oxide coating of the aluminum of the profile carrier 1 is overcome.

The metallic shield surface 5 forming the shield and the profile carrier 1 connected to it in the high-frequency range can be arranged on the inside or the outside of the wall of the shielding cabin.

The embodiment shown in Fig. 2 differs from the embodiment of FIG. 1 only in that an intermediate layer 7 is inserted on the contact surfaces between the screen surface 5 and the profile carrier 1 , which consists of an easily deformable, electrically highly conductive material, preferably Copper braid or brass braid.

Fig. 3 shows that to build a double-walled shielding cabin in the manner already explained in Fig. 1, wall panels 2 can be screwed onto the profile beams 1 from both sides, the screen surfaces 5 each facing the profile beam 1 and being electrically conductively connected to it.

The shielding cabins described can be used without essential Modification of the construction principle as self-supporting cabins or as fixed installations in existing rooms be carried out. The installation of equipment that the Penetrating shielding is easy during assembly possible.

At the corners of the shielding cabin angle profiles ( 1 ') can be used, to which the wall plates 2 are screwed. Fig. 4 shows in section in a representation corresponding to FIGS. 1 to 3 a corner joint of two wall panels. The butt joint of the wall panels 2 overlapping profile beam 1 'is in this case as an angle profile, and preferably also carried out as a hollow profile.

Claims (7)

1. shielding cabin for high-frequency magnetic fields, in particular for magnetic resonance tomographs in medical technology, each with at least one metallic screen surface bearing wall panels, the joints of which are overlapped by joint covers which are screwed to the wall panels in such a way that the screen surface attached to the wall panels is pressed against the joint cover is characterized in that the joint covers form a supporting skeleton of the shielding cabin, which consists of hollow profile beams ( 1, 1 ' ) made of aluminum or an aluminum alloy and is covered with the wall plates ( 2 ) by means of self-tapping propellers ( 6 ) which are in a profile wall of the hollow section support ( 1, 1 ' ) are screwed in. 2. shielding cabin according to claim 1, characterized in that the wall plates ( 2 ) consist of a non-metallic base material ( 4 ) on which the screen surface ( 5 ) is applied. 3. shielding cabin according to claim 2, characterized in that the base material ( 4 ) of the wall plates ( 2 ) consists of wood or a wood product. 4. shielding cabin according to claim 2, characterized in that the shield surface ( 5 ) consists of copper. 5. shielding cabin according to claim 1, characterized in that a metal deformable intermediate layer ( 7 ) is arranged in each case between the profile beams ( 1, 1 ') and the wall plates screwed thereon ( 2 ). 6. shielding cabin according to claim 1, characterized in that the supporting frame made of profile beams ( 1 ) is covered on both sides with wall panels ( 2 ), each of which has a pressed against the profile beams ( 1, 1 ') screen surface ( 5 ). 7. shielding cabin according to claim 1, characterized in that shield surfaces ( 5 ) which are on the side facing away from the profile supports ( 1 ) of the wall panels ( 2 ), are soldered or welded together.