DE202017005885U1 - magnetic resonance system - Google Patents

Abstract

Magnetic resonance system (1, 1 '), comprising: - a magnetic resonance device (6) arranged in a magnet space (5) with a plurality of imaging components for acquiring magnetic resonance data of an examination subject, and - a plurality of power electronics components (17) each associated with at least one imaging component, characterized in that the power electronics components (17) are arranged in the magnet space (5).

Description

The invention relates to a magnetic resonance system, comprising a magnetic resonance device arranged in a magnetic space with a plurality of imaging components for acquiring magnetic resonance data of an examination subject, and a plurality of power electronics components each associated with at least one imaging component.

Magnetic resonance imaging is now an established and common tool in the medical care of patients, especially in the diagnosis. Corresponding magnetic resonance systems, as known in the prior art, have a magnetic resonance device arranged in a typically shielded magnetic space. The magnetic resonance device comprises a main magnetic unit in which besides the usually superconducting main magnet (basic field magnet) for generating the basic magnetic field (B0 field) of the magnetic resonance device also further imaging components can be installed or available as accessories, in particular a gradient coil arrangement and a high-frequency coil arrangement. The spins aligned in the basic magnetic field can be excited by means of high-frequency signals of the high-frequency coil arrangement, and the resulting excitations can in turn be received as high-frequency signals. Gradient coils allow a modification of the basic magnetic field for localization. As a further component, such a magnetic resonance device usually has cooling systems for various imaging components and / or at least one static and / or dynamic shim device. In cylindrical magnetic resonance devices, the basic field magnet or the corresponding, provided with a disguise main magnetic unit encloses a patient admission, in which the patient can be retracted by means of a patient bed.

At least a portion of the imaging components are associated with power electronics components, in particular amplifiers for the high-frequency coil arrangement and the gradient coils of the gradient coil arrangement being given as examples. Such power electronic components are arranged outside of said magnetic space, for example in an operating room, which may contain at least one electronic cabinet of the magnetic resonance system, and / or in an operating room in which an operating device, for example a control console, can be arranged. In such an operating room and / or operating room and other components of the magnetic resonance system may be provided, for example, components of a control device of monitoring devices that monitor the operation of the magnetic resonance device and the like. The components listed here by way of example, in particular imaging components, power electronics components, monitoring devices, control devices and operating devices, must communicate with one another and be supplied with electrical power for the purpose of producing the function of the magnetic resonance system, which often involves a high outlay, in particular with regard to the wiring and the cable routing brings. In addition, there is an extremely high space requirement, since many components of the magnetic resonance system are to be arranged outside of the actual magnetic space due to the high magnetic fields.

Due to the increasing cost pressure in the health care system magnetic resonance systems are to become cheaper. Starting points for this are the use of new technologies, for example new magnet technologies, reduced performance values in the most sensitive market segments, integration of individual components into a large overall component and the use of new system architectures. The life cycle costs of a magnetic resonance system (life cycle costs) usually comprise the unit costs, the installation costs on site (including transport), the operating costs during clinical operation and the costs for dismantling or scrapping. The focus of current efforts is the unit costs, but also the installation costs, as these represent the temporally nearest largest expenditure for a customer. As already indicated, with regard to the installation costs there is the problem that current system architectures of magnetic resonance systems consist of a magnetic resonance device in the magnet space, an electronic device in at least one electronics cabinet in an operating room and at least one operating device in an operating room. The three rooms are interconnected by a plurality of cables and hoses to receive electrical power, information / data, cooling water, high frequency signals and gradient currents at the appropriate location. This requires a sometimes very extensive wiring between the different locations, which must be filtered by appropriate filter devices in the transition to the magnetic space for high-frequency Abschirmgründen so that a high-frequency interference-free magnetic resonance operation is guaranteed.

The DE 10 2006 052 437 A1 and the DE 10 2008 017 819 B3 each show a structure of an MR control system, the DE 10 2007 058 872 A1 , the US20090137898A1 . US20160174928A1 in each case devices for data transmission in an MR system.

The invention is therefore based on the object of specifying a cost-saving, compact and installable with reduced effort system architecture for a magnetic resonance system.

This object is achieved by a magnetic resonance system according to claim 1. Advantageous embodiments emerge from the subclaims.

A magnetic resonance system according to the invention, comprising a magnetic resonance device arranged in a magnetic space and having a plurality of imaging components for acquiring magnetic resonance data of an examination subject and a plurality of power electronics components respectively associated with at least one imaging component, is characterized in that the power electronics components are arranged in the magnetic space.

The basic idea of the present invention is therefore to integrate the power electronics components of the magnetic resonance system instead of the usual way in an operating room, to the magnetic resonance device itself or close to the magnetic resonance device in the magnetic space. This means system functions for which an external housing was previously required can now be provided in the magnet space itself on the magnet, so that in particular the installation effort is reduced. For example, cable connections that were previously required can be dispensed with, so that in particular only one power supply cable connection and one communication cable connection are to be led into the magnet space (in addition to optionally cooling lines of a coolant circuit). This results in very low commissioning costs (installation costs) as well as a low error rate in the installation, because the magnetic resonance system can be further pre-integrated and fewer system components must be separated from each other. This allows in particular a reduction of the installation effort, the error rate and the installation and quality costs. Ideally, as will be discussed in more detail below, the integration of power electronics components into the magnet space also offers the possibility of integrating as completely as possible further components of the magnetic resonance system in the magnet space or the magnetic resonance device itself in order to achieve a further simplification, in particular at least approximately complete Pre-integration of the magnetic resonance system.

Expediently, the power electronic components can be assigned at least one screen device for shielding the fields generated by at least one of the power electronics components from the fields used to record magnetic resonance data. In order to disturb as little as possible the acquisition of magnetic resonance data, thus the usual operation of the magnetic resonance device, a shielding of fields of the power electronic components and payload fields in the magnetic resonance imaging is expediently to be provided. In the context of the present invention, it has been found, in particular, that with small basic field strengths of the magnetic resonance apparatus, such screen devices can be designed in a particularly cost-effective and space-saving manner with sufficient shielding effect, which hitherto precluded integration into the magnet space. Thus, a particularly advantageous embodiment of the present invention provides that the magnetic resonance system has a basic magnetic field strength of less than 1 T, in particular of less than 0.7 T. This means that in particular in the low field range, the unit cost of the magnetic resonance system in implementing the present invention can be kept extremely low, so that a total reduction of effort, error rate and cost can be achieved. Incidentally, at low field strengths, it is also conceivable to dispense with shielding with respect to the static magnetic field. A shielding of the component against emission and / or imission of high-frequency electromagnetic waves may still be required.

It should also be noted at this point that in the context of the present invention, the magnetic resonance device may expediently comprise a main magnetic unit, which includes the main magnetic field (B0 field) generating, in particular superconducting main magnet as well as other imaging components, which in particular a gradient coil and / or a radio frequency coil assembly may include. In the main magnetic unit, a cylindrical patient receiving device is preferably formed, into which a patient couch of the magnetic resonance device can be retracted. The radio-frequency coil arrangement and the gradient coil arrangement can thereby extend around the patient reception, for example behind a panel.

The power electronics components may include radio frequency power amplifiers for amplifying radio frequency signals to be transmitted and / or analog to digital converters (ADCs) for converting received radio frequency signals and / or gradient power amplifiers for amplifying gradient pulses converted by gradient currents. Radio frequency power amplifiers (RFPA) and ADCs for received high-frequency signals are, for example, at least one high-frequency coil arrangement of the Assign magnetic resonance device as imaging component; Gradient Power Amplifier (GPA) of a gradient coil arrangement as an education component. Corresponding gradient pulses as part of a magnetic resonance sequence are converted by corresponding gradient currents to be generated by the gradient power amplifiers. A particularly simple implementation, in particular with regard to the abovementioned shielding devices, results in this case when the intensity of the gradient currents is less than 70 A, in particular less than 60 A.

In a particularly preferred embodiment of the present invention, it can be provided that a complete transmission system, a complete reception system and a complete gradient system are formed by the power electronics components and the imaging components. This means that all components of the magnetic resonance system necessary for transmitting and receiving high-frequency signals and for outputting gradient pulses can be integrated in the magnetic space, in particular in or on the magnetic resonance device itself. This also reduces the installation effort, the susceptibility to errors and the installation costs through appropriate pre-integration.

Expediently, the power electronic components can be realized as a structural unit with the magnetic resonance device, in particular a main magnetic unit of the magnetic resonance device, and / or arranged in a structural unit attached to the magnetic resonance device, in particular a main magnet unit of the magnetic resonance device. In this way, a particularly extensive integration is achieved after, in particular, the magnetic resonance device can be supplied and installed together with the power electronics components as a structural unit, or only a further structural unit has to be added to the magnetic resonance device. An additional unit for the power electronics components can connect, for example, near the bottom of the side of a main magnetic unit of the magnetic resonance device. In a cylindrical magnetic resonance device, such an arrangement offers itself anyway, since along the side surfaces the smallest stray fields of the magnetic fields used for magnetic resonance imaging occur.

Preferably, a control unit controlling the acquisition of magnetic resonance data and / or a control unit of the magnetic resonance system comprising evaluation unit designed for evaluating magnetic resonance data may also be arranged in the magnet space, in particular on the part of the power electronics components. In particular, therefore, a complete control system (control system) can also be integrated into the magnet space, which in particular can have at least one control unit for the measurements and at least one evaluation unit for the reception data processing. In particular, it can be provided that at least one of the at least one evaluation unit is an image reconstruction unit. In this way, a further, particularly advantageous pre-integration takes place, which further reduces the installation effort and the susceptibility to errors.

A likewise particularly preferred embodiment provides that at least one monitoring device monitoring the operation of the magnetic resonance device is also arranged in the magnet space, in particular on the side of a structural unit comprising the power electronics components. In particular, all required monitoring devices are also provided in the magnet space, in particular on the part of the unit. The advantageously provided pre-integration can therefore completely encompass the monitoring devices including a (shielded or EMC-interference-free) connection to at least one external computing device, in particular an external computer network (Internet).

With regard to these further integrations, an advantageous development provides that at least one shielded and / or optical communication cable connection is guided out of the magnet space by the at least one monitoring device and / or the control device to at least one computing device located outside the magnet space. Due to the high degree of pre-integration, which preferably affects both the control device and the monitoring devices, ultimately only one communication cable connection from the magnetic space is required. In this case, a corresponding shielding / EMC interference freedom can be produced in a correspondingly known manner, for example by at least a part of the communication lines of the communication cable connection being optically executed.

Alternatively or additionally, it can also be provided that at least one communication device is provided for wireless communication of the control device and / or the at least one monitoring device with one or the computing device. In this case, it is expedient to select frequency ranges for wireless communication which bring about the least possible disturbance due to or interference with the recording of the magnetic resonance data. Of course, it is also conceivable to use wireless communication variants, for example, on optical Signal exchange or the like based. Such communication variants have already been proposed in the prior art and are characterized by their high freedom from interference.

As already mentioned, the magnetic resonance system can also have an operating device arranged outside the magnetic space in an operating room. Conveniently, the operating device can communicate as a computing device via the communication cable connection and / or the communication device with the control device and / or the at least one monitoring device. An example of a computing device to be placed outside the magnetic space, even in the case of a high degree of integration in the magnetic space, is an operating device, for example an operating console, which can be arranged, for example, in an operating space. Ideally, it is within the scope of the present invention possible to provide all components or subsystems except the operating device within the magnetic space.

The magnetic resonance system can furthermore have at least one cooling device using a coolant in the magnet space, wherein at least one cooling line carrying the coolant is guided into the magnet space and / or, in particular in the case of helium as coolant, a compressor for the coolant is arranged in the magnet space. Accordingly, an embodiment of the magnetic resonance system is conceivable in which, for example, power electronics components and / or further components are cooled by a liquid coolant, for example water. In this case, a corresponding cooling line for supplying the coolant, in particular the cooling water, in the magnetic space conceivable. However, it is preferred to use completely air-cooled components in this regard, so that even a cooling line for a liquid coolant, for example water, can be dispensed with in the magnet space, which further simplifies the installation. If a superconductive main magnet is provided, to which a cooling device, for example helium, is used as the coolant, a compressor for the coolant, in particular helium, is already provided in the magnet space, so that a cooling line can also be dispensed with here.

Within the scope of the present invention, a magnetic resonance device with a main magnet is used with particular advantage, in which no quench line is no longer required due to advanced technology. If a main magnet is used in which such a quench line is still required, provision can accordingly be made for it to be guided out of the magnet space.

The magnetic resonance device and the other components in the magnet space, in particular the power electronics components, are naturally to be supplied with power, so that it may be provided in a development of the magnetic resonance system that at least one power supply cable connection is guided into the magnet space, which comprises at least one power supply for the power electronic components. In this case, various concrete embodiments are conceivable in order to ensure the power supply of the power electronic components.

Thus, a first possible embodiment of the present invention provides that by means of the power supply cable connection, an AC line voltage is fed to a system unit as a power electronics component, which converts the AC mains voltage into input voltages required by further power electronics components. In this case, therefore, a system unit, in particular integrated into the assembly with the power electronics components, also provided in the magnetic space, where the correspondingly required input voltages are generated. In this case, the power cable connection expediently have at least one screening device and / or a portion of filter devices filtering out frequency ranges used in the measurement of the magnetic resonance data, in particular on entry into the magnet space, in order to guide the AC line voltage as problem-free as possible to the system unit. In order to generate the input voltages, the system unit can have at least one transformer, so that it can be used in the existing magnetic fields. In a preferred embodiment, the system unit may comprise at least one switching power supply. For switching power supplies have already been proposed in the prior art interpretations that allow it to be able to operate in the magnetic stray field, in particular in a magnetic stray field with a thickness greater than 0.1 T.

In a second possible embodiment of the present invention with regard to the power supply, which is somewhat less preferred, it can be provided that at least one transformer and / or at least one switched-mode power supply are provided outside the magnet space for providing input voltages to be transmitted to the power electronics components via the power supply cable connection having provisioning unit is provided. At least one transformer and / or at least one switched-mode power supply can therefore also be provided outside the magnet space, that is to say the high-frequency cabin, one or more input voltages to the power electronics components can be introduced. It is also preferred in this case to use switched mode power supplies, in particular if only a few input voltages are necessary. These switching power supplies can be accommodated with particular advantage in the control room, since they can be accommodated extremely space-saving. However, it is altogether expedient if the power supply unit is arranged in or in the control room. For example, at least one transformer with possible downstream rectifier and voltage converter modules can be accommodated in a control room, since a space-saving implementation is also conceivable here.

A particularly expedient development further provides, after usually a communication cable connection and a power supply cable connection to be provided that the communication cable connection and the power supply cable connection are realized as a common cable with a common at least on the side to be connected in the magnetic space connector. In this way, in particular in the preferred embodiments in which a quenchline and / or a cooling line are not required, all the necessary connections can be realized via a single cable, in which the power supply lines and the communication lines run accordingly. In this way, a particularly simple installation is given. Preferably, only one plug is provided outside the magnet space, which is to be connected, for example, to a pre-integrated distribution device which can be arranged in an operating room and / or in an operating room.

Further advantages and details of the present invention will become apparent from the embodiments described below and with reference to the drawing. Showing:

1 A first embodiment of a magnetic resonance system according to the invention,

2 a schematic representation of a cable, and

3 A second embodiment of a magnetic resonance system according to the invention.

1 shows a schematic diagram of a preferred first embodiment of a magnetic resonance system according to the invention 1 , In this case, the representations, also with regard to the size relationships, are to be understood as purely schematic, to all components of the magnetic resonance system 1 to be able to represent correctly. Except for one as a control panel 2 trained operating device 3 in an operating room 4 is arranged, are all components of the magnetic resonance system 1 in an externally shielded magnet space 5 arranged, which can also be referred to as a high-frequency cabin. The magnetic resonance system 1 comprises, as basically known, a magnetic resonance device 6 with a main magnetic unit 7 in which a cylindrical patient admission indicated here only 8th is trained. In this, a patient from the magnetic resonance data to be recorded, using a patient bed 9 be retracted. The magnetic resonance device 6 includes the imaging components necessary for magnetic resonance imaging, in the present case a superconducting main magnet 10 for generating the basic magnetic field, a patient admission 8th enclosing radio frequency coil assembly 11 and a radio frequency coil assembly 11 enclosing gradient coil assembly 12 are shown.

The superconducting main magnet 10 is through a cooling device 13 with a helium cycle only indicated here 14 cooled, including the compressor 15 , specifically in one at the main magnet unit 7 fixed unit, inside the magnet room 5 is arranged. After all the others in the magnet room 5 arranged, the cooling needy components of the magnetic resonance system 1 are air-cooled and the main magnet 10 No quench line needed, no cooling lines and no quench line in the magnet space 5 be guided.

On the outside of the main magnet unit 7 is also another unit 16 provided in the other components of the magnetic resonance system 1 are provided. Instead of the assembly 16 , which is shown here significantly enlarged, it is also conceivable, the corresponding components in the main magnetic unit 7 immediately to obstruct, so that this the unit 16 forms.

The components of the assembly 16 initially include power electronics components 17 In the present case, by way of example, high-frequency power amplifiers 18 , Gradient power amplifier 19 and ADC 20 are shown. The power electronics components 17 each have screen facilities 21 to avoid interactions with magnetic fields for magnetic resonance imaging. After the design of the magnetic resonance system 1 The present invention is such that the basic magnetic field strength is less than 0.7 T and the gradient currents are less than 60 A, is a compact and inexpensive design of the screen devices 21 possible.

Further in the unit 16 Existing components of the magnetic resonance system comprise a control device 22 and monitoring equipment 23 for monitoring the function of the magnetic resonance device 6 , The control device 22 in the present case comprises at least one control unit 24 for controlling the measuring operation of the magnetic resonance device 6 as well as evaluation units 25 , in particular also comprising at least one image reconstruction unit. By providing the control device 22 and the power electronics components 17 inside the magnetic space 5 It contains a complete gradient system, a complete transmission system, a complete reception system and a complete control system. Of course, if necessary, umbrella facilities 21 also with regard to other components in the unit 16 be provided.

The power supply and the communication with external computing / computing networks such as the operating device 3 or a network 26 takes place here via a single cable 27 which thus contains communication lines of a communication cable connection and power supply lines of a power-supply cable connection. This is in 2 schematically illustrated, wherein the communication cable connection 28 and the power supply cable connection 29 in the cable 27 run.

The cable 27 is about the system unit 30 to which it is connected with a single plug, to the unit 16 coupled. In the system unit 30 are switching power supplies 31 provided via the in the power supply cable connection 29 transported AC line voltage into suitable input voltages for the power electronics components 17 as well as the other components of the magnetic resonance system 1 in the magnet room 5 is converted. In order to avoid disturbances due to the mains AC voltage, is at the entrance to the magnetic space 5 a filter device 32 intended; Further, the cable 27 appropriately shielded. Communication lines of the communication cable connection 28 can outside the magnet room 5 be performed separately according to, for example, the operating device 3 and / or to the network 26 while the power supply cable connection is connected to a corresponding terminal of a power supplier. To achieve this separation, a distribution device not shown in detail, for example in the control room, can be provided to which the cable 27 also connected with only one plug.

3 shows a modified embodiment of a magnetic resonance system 1' in which, for the sake of simplicity, identical components are given the same reference numerals. In contrast to the magnetic resonance system 1 are in the magnetic resonance system 1' two cooling devices 13 . 32 present, the cooling device 32 the cooling of components other than the superconducting main magnet 10 Serve by water, so that appropriate cooling lines 33 from the magnet room 5 are guided.

Furthermore, there is no system unit 30 provided, but the input voltages are outside the magnetic space 5 through a service delivery unit 34 in the control room 4 generated, in turn, switching power supplies 31 can be included and can be realized as part of the mentioned distribution device. via the power supply lines of the power supply cable connection 29 are the input voltages to the power electronics components 17 forwarded.

Although the invention has been further illustrated and described in detail by the preferred embodiment, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102006052437 A1 [0005]
• DE 102008017819 B3 [0005]
• DE 102007058872 A1 [0005]
• US 20090137898 A1 [0005]
• US 20160174928 A1 [0005]

Claims (22)

Magnetic Resonance System ( 1 . 1' ), comprising: - one in a magnetic space ( 5 ) arranged magnetic resonance device ( 6 ) having a plurality of imaging components for acquiring magnetic resonance data of an examination subject, and - multiple power electronic components respectively associated with at least one imaging component ( 17 ), characterized in that the power electronics components ( 17 ) in the magnetic space ( 5 ) are arranged. Magnetic Resonance System ( 1 . 1' ) according to claim 1, characterized in that the power electronics components ( 17 ) at least one screening device ( 21 ) for shielding by at least one of the power electronics components ( 17 ) associated fields are assigned to the used for receiving magnetic resonance data fields. Magnetic Resonance System ( 1 . 1' ) according to claim 1 or 2, characterized in that it has a basic magnetic field strength of less than 1 T, in particular of less than 0.7 T. Magnetic Resonance System ( 1 . 1' ) according to one of the preceding claims, characterized in that the power electronics components ( 17 ) High Frequency Power Amplifier ( 18 ) for amplifying radio-frequency signals to be transmitted and / or analog-to-digital converters ( 20 ) for converting received radio frequency signals and / or gradient power amplifiers ( 19 ) for amplifying gradient pulses converted by gradient currents. Magnetic Resonance System ( 1 . 1' ) according to claim 4, characterized in that the strength of the gradient currents less than 70 A, in particular less than 60 A, is. Magnetic Resonance System ( 1 . 1' ) according to claim 4 or 5, characterized in that by the power electronics components ( 17 ) and the imaging components are each formed a complete transmission system, a complete receiving system and a complete gradient system. Magnetic Resonance System ( 1 . 1' ) according to one of the preceding claims, characterized in that the power electronics components ( 17 ) as a structural unit ( 16 ) with the magnetic resonance device ( 6 ) and / or in one at the magnetic resonance device ( 6 ) fixed unit ( 16 ) are arranged. Magnetic Resonance System ( 1 . 1' ) according to one of the preceding claims, characterized in that in the magnetic space ( 5 ), in particular by one of the power electronics components ( 17 ) comprehensive assembly ( 16 ), also a control unit controlling the acquisition of magnetic resonance data ( 24 ) and / or an evaluation unit designed for the evaluation of magnetic resonance data ( 25 ) comprehensive control equipment ( 22 ) of the magnetic resonance system ( 1 . 1' ) is arranged. Magnetic Resonance System ( 1 . 1' ) according to claim 8, characterized in that at least one of the at least one evaluation unit ( 25 ) is an image reconstruction unit. Magnetic Resonance System ( 1 . 1' ) according to one of the preceding claims, characterized in that in the magnetic space ( 5 ), in particular by one of the power electronics components ( 17 ) comprehensive assembly ( 16 ), at least one operation of the magnetic resonance device ( 6 ) monitoring monitoring device ( 23 ) is arranged. Magnetic Resonance System ( 1 . 1' ) according to one of claims 8 to 10, characterized in that at least one shielded and / or optical communication cable connection ( 28 ) of the at least one monitoring device ( 23 ) and / or the control device ( 22 ) to at least one outside the magnetic space ( 5 ) located computing device from the magnetic space ( 5 ) is guided. Magnetic Resonance System ( 1 . 1' ) according to one of claims 8 to 11, characterized in that at least one communication device for wireless communication of the control device ( 22 ) and / or the at least one monitoring device ( 23 ) is provided with a or the computing device. Magnetic Resonance System ( 1 . 1' ) according to claim 11 or 12, characterized in that it further comprises an outside of the magnetic space ( 5 ) in a control room ( 4 ) arranged operating device ( 3 ), which as computing means via the communication cable connection ( 28 ) and / or the communication device with the control device ( 22 ) and / or the at least one monitoring device ( 23 ) communicates. Magnetic Resonance System ( 1 . 1' ) according to one of the preceding claims, characterized in that it further comprises at least one cooling means ( 13 , 32 ) in the magnetic space ( 5 ), wherein at least one refrigerant line leading the coolant ( 33 ) in the magnetic space ( 5 ) and / or, in particular in the case of helium as a coolant, a compressor ( 15 ) for the coolant in the magnetic space ( 5 ) is arranged. Magnetic Resonance System ( 1 . 1' ) according to one of the preceding claims, characterized in that at least one quench line from the magnetic space ( 5 ) is guided. Magnetic Resonance System ( 1 . 1' ) according to one of the preceding claims, characterized in that at least one power supply cable connection ( 29 ) in the magnetic space ( 5 ) having at least one power supply line for the power electronics components ( 17 ). Magnetic Resonance System ( 1 . 1' ) according to claim 16, characterized in that by means of the power supply cable connection ( 29 ) an AC line voltage to a system unit ( 30 ) as power electronics component ( 17 ), which supplies the AC line voltage in further power electronics components ( 17 ) converts required input voltages. Magnetic Resonance System ( 1 . 1' ) according to claim 17, characterized in that the power supply cable connection ( 29 ) at least one screen device and / or a portion of filtering in the frequency ranges used in the measurement of magnetic resonance data filtering device ( 32 ), especially when entering the magnetic space ( 5 ), having. Magnetic Resonance System ( 1 . 1' ) according to claim 17 or 18, characterized in that the system unit ( 30 ) at least one transformer and / or at least one switching power supply ( 31 ). Magnetic Resonance System ( 1 . 1' ) according to claim 16, characterized in that one outside the magnetic space ( 5 ) provided, at least one transformer and / or at least one switching power supply ( 31 ) for providing via the power supply cable connection ( 29 ) to the power electronics components ( 17 ) to power supply unit to be transmitted ( 34 ) is provided. Magnetic Resonance System ( 1 . 1' ) according to claim 20, characterized in that the power supply unit ( 34 ) in one or the control room ( 4 ) is arranged. Magnetic Resonance System ( 1 . 1' ) according to one of claims 16 to 21, comprising a communication cable connection ( 28 ) according to claim 11, characterized in that the communication cable connection ( 28 ) and the power supply cable connection ( 29 ) as a common cable ( 27 ) with at least one in the magnetic space ( 5 ) to be connected side common plug are realized.

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