DE102006060036A1 - Tomograph i.e. magnetic resonance tomograph, for representation of structure inside e.g. human body, has sensor arrangement including power supply device for magnetic field and temperature sensors, and with photovoltaic power supply element - Google Patents

Abstract

The tomograph has a sensor arrangement (SA1) provided in an area of an interior lighting. The arrangement has a magnetic field sensor (MS), a temperature sensor (TS), and a power supply device for the sensors. The power supply device has a photovoltaic power supply element (SZ). The power supply device has a power storing device (C) for intermediate storage of the power supplied from the photovoltaic power supply element. The power supply device is formed for supplying power to a wireless communication device (A).

Description

The The invention relates to the field of tomographs, in particular magnetic resonance tomographs.

The Magnetic resonance imaging (MR, MRI or MRI, also known as magnetic resonance imaging is used to represent structures inside the body. With an MRI you can, for example, sectional images of the human or animal body generate an accurate assessment of organs and organ changes allow. Magnetic resonance imaging uses this in contrast for X-ray tomography magnetic fields.

In Modern magnetic resonance tomographs are increasingly being used for sensors Use in the course of carrying the magnetic resonance tomography record more data. Such data may be, for example the temperature or the magnetic field on the patient in the measuring range of the Be tomographs. Another example is a microphone as a sensor, for example, for communication with a tomograph located Patients.

• – Einmal kann die Energieversorgung durch elektrische Zuleitungen sichergestellt werden. Nachteilig ist hierbei, dass die hochfrequenten Wechselmagnetfelder, die der Magnetresonanztomograph verwendet, zu einer Induktion von Strömen in den Zuleitungen führen. Diese Ströme führen zu unerwünschten Magnetfeldinhomogenitäten und sowie zu einer Erwärmung der Zuleitungen, die dadurch wiederum eine thermische Isolation benötigen.
• – Weiterhin können zur Energieversorgung der Sensoren Batterien verwendet werden. Diese müssen in unregelmäßigen Zeitab ständen erneuert werden, was einen erhöhten Wartungsaufwand für den Magnetresonanztomographen bedeutet.

Two types of power supply of these sensors are known:

• - Once the power supply can be ensured by electrical leads. The disadvantage here is that the high-frequency alternating magnetic fields used by the magnetic resonance tomograph lead to an induction of currents in the supply lines. These currents lead to unwanted magnetic field inhomogeneities and to a heating of the leads, which in turn require thermal insulation.
• - Furthermore, batteries can be used to power the sensors. These must be renewed at irregular Zeitab states, which means an increased maintenance of the magnetic resonance tomograph.

Of the Invention is based on the object, a tomograph with additional To provide sensors which avoids the above-mentioned disadvantages i.e. avoids the leads, without increased maintenance to require.

These The object is solved by the features of claim 1.

Of the Tomograph according to the invention has at least one sensor arrangement, wherein the sensor arrangement is arranged in the region of an interior lighting of the tomograph and at least one sensor element and at least one power supply device for the Sensor element, wherein the power supply device at least having a photovoltaic power supply element. The energy supply element is preferably realized as a solar cell.

The This invention avoids the above-mentioned disadvantages. leads for energy supply and maintenance for the replacement of batteries also omitted. The invention uses in a particularly advantageous Make an energy source that consists of tomographs. tomography be in operation by means of the interior lighting in the area Magnetic field tube extremely bright illuminated, around the magnetic field tube for the Patients in the tomograph, i. in the magnetic field tube, less to appear narrow and uncomfortable. This is the operation the tomograph light is transmitted through the photovoltaic power supply element exploited to power the sensor assembly. The Characteristics of a tomograph thus become particularly advantageous Used way to just those in the tomograph particularly disadvantageous To avoid supply lines.

In advantageous embodiment, the power supply device at least one energy storage device for temporary storage the energy supplied by the photovoltaic energy supply element on. Such an energy storage device can, for example from one or more batteries or at least one capacitor of large capacity, for example a so-called electrochemical double-layer capacitor.

The Energy storage device allows advantageous that the sensor arrangement temporarily more Electrical power can consume as the power supply device normally available provides. This applies at least as long as the average energy consumption the sensor assembly during the operation of the scanner below the average power output of the power supply element in the same period.

In a further advantageous embodiment and development of Invention, the sensor arrangement comprises at least one device for wireless communication. Examples of such wireless communication are ZigBee, Bluetooth and / or UWB. This ensures that the sensor does not need signal lines for its measurement results, the again the introductory mentioned Disadvantages in a tomograph have. The energy supply device is preferred configured to power the wireless communication device, whereby supply lines for electrical supply also for the device to wireless communication accounts.

In a further advantageous embodiment and development of Invention is the device for wireless communication to the optical data transfer designed. For example, this can be at least one light emitting diode be used. Measurement results wirelessly transmitted are, are called intensity variation modulated on the light of the LED and example of a photodiode, advantageously in conjunction with a narrowband optical filter, to be received. By using the optical data transmission become possible Avoid interference with other RF fields.

In A further embodiment of the invention comprises the sensor arrangement at least one display device. Such a display device is For example, an LCD display. The display device is advantageous designed as an electrochromic element. An electrochromic element needed essentially just to change its display energy and thus has an energy-saving effect. This will make it possible a direct visual feedback the measurement results, for example, inwards, ie to the patient, and / or outward to give.

Prefers the sensor element comprises at least one magnetic field sensor, temperature sensor, a Camera, a microphone and / or a sensor for creating a Electrocardiogram.

In In another embodiment of the invention, the tomograph is such designed so that the sensor assembly outside an operating time the tomograph is in a resting state, being at rest in the Essentially no energy is consumed by the sensor array.

hereby will reach that outside the operating time of the scanner, i. if the interior lighting the tomograph is not active, no unnecessary energy from the sensor array is consumed. Is there an energy storage device, will be beneficial to their unnecessary Discharge avoided. Furthermore, in this time the energy storage device reinforced getting charged.

Prefers the tomograph is a magnetic resonance tomograph.

Further Details and advantages of the invention will be apparent from a explained in the drawing illustrated embodiment. there demonstrate:

1 a sensor arrangement

2 a sensor arrangement with display for temperature display

1 does not show to scale as an exemplary embodiment of the invention a first sensor array SA1 mounted in a magnetic resonance tomograph, comprising a plurality of elements: a solar cell SZ, a capacitor C, a magnetic field sensor MS, a temperature sensor TS, a microprocessor P and an antenna A. The elements are arranged on a substrate SU. Furthermore, there are electrical connections V between the solar cell SZ and the capacitor C, between this and the microprocessor P and from this to the antenna A, the magnetic field sensor MS and the temperature sensor TS.

Of the Magnetic resonance tomograph in which the first sensor arrangement SA1 is mounted is is known and therefore not shown in the figures.

at the capacitor C is a so-called. Electrochemical Double-layer capacitor, i. a capacitor with very high Capacity, which is suitable for storing electrical energy. In which Temperature sensor TS is a platinum thermocouple, whose temperature is determined by the electrical resistance.

The Antenna A is for wireless communication, in this example ZigBee is used as the communication protocol. As a microprocessor P is a well-known microprocessor used in the situation is to control the magnetic field sensor MS and temperature sensor TS and the measured data over to send the ZigBee protocol via the antenna.

The Solar cell converts the light present in the magnetic resonance tomograph into electrical energy. With this energy, the capacitor C resistant loaded. The processor P, the magnetic field sensor MS, the temperature TS and the antenna A in turn remove each for operation needed Energy the capacitor C.

In this embodiment, the solar cell has an area of 10 cm ² (square centimeter) and an efficiency of 20%. Inside the MRI scanner the illuminance is 800 lux during operation. Under these conditions, the solar cell generates about 0.5 mW of electrical power.

If the operating time of the magnetic resonance tomograph is half an hour, a total energy of 0.5 mW × 0.5 h = 0.25 mWh is available for operating the elements of the sensor arrangement within this time. Outside the operating time of the magnetic resonance tomograph, that is to say when the illumination thereof is switched off, the solar cell can correspond to the other existing ones Lighting produces very little electricity. Therefore, the available energy in this example is obtained only during the operating time. It is expedient if the microprocessor P of the first sensor arrangement SA1 goes into an idle state outside the operating time of the MRT in order not to unnecessarily discharge the capacitor C.

There the energy stored in the capacitor C, the power consumption the elements too 0.5 mW, as long as the total energy intake within half Hour of operation of the magnetic resonance tomograph not that of the solar cell SZ provided exceeds 0.25 mWh. So in this Example of the temperature sensor TS and the magnetic field sensor MS only queried every second, with a power of 0.05 s 2 mW needed becomes.

Of the Processor saves the measurement results of the sensors between and send them over wirelessly the antenna A.

In other embodiments According to the invention, the solar cell can have a different area and a different efficiency exhibit. Also the light intensity inside the magnetic resonance scanner, for example structural reasons or due to the location of the solar cell in the magnetic resonance tomograph different fail.

A second embodiment of the invention according to the not to scale 2 includes a second sensor array SA2. This has a display D with an electrochromic display surface LA. Furthermore, the second sensor arrangement SA2 has a solar cell SZ, a temperature sensor TS and a light-emitting diode LD. Electrical connections V exist between the solar cell SZ and the light-emitting diode LD, the temperature sensor TS and the display D. Furthermore, there are electrical connections between the light-emitting diode LS and the temperature sensor TS and between this and the display D.

In this case, the solar cell SZ feeds the light-emitting diode LD, the temperature sensor TS and the display D without the interposition of a capacitor C. The area of the solar cell SZ is 20 cm ² in this case. It can therefore produce a power of about 1 mW.

The measurement result of the temperature sensor TS is transmitted to the display D for display. Furthermore, the measurement result is transmitted to the light-emitting diode LD. An in 2 not shown electronic circuit converts the measurement result of the temperature sensor TS in a frequency which is impressed on the power supply of the light emitting diode LD. Light emitted by the light-emitting diode LD therefore has an intensity fluctuation whose frequency depends on the measurement result of the temperature sensor TS. The light of the light-emitting diode LD can be recorded elsewhere, for example, via a photodiode, wherein expediently a color filter in the photodiode provides for a selection of the wavelengths originating from the light-emitting diode.

Claims (9)

Tomograph with at least one sensor arrangement (SA1, SA2), wherein the sensor arrangement (SA1, SA2) in the region of Interior lighting of the scanner is arranged and at least one sensor element (TS, MS) and at least one energy supply device for the sensor element (TS, MS), wherein the power supply device at least a photovoltaic power supply element (SZ) has. Tomograph according to claim 1, wherein the power supply device at least one energy storage device (C) for caching the photovoltaic power supply element (SZ) supplied energy. Tomograph according to claim 1 or 2, in which the sensor arrangement (SA1, SA2) at least one Wireless communication device (A, LD), in particular via ZigBee, Bluetooth and / or UWB. Tomograph according to one of the preceding claims, in which the device for wireless communication (LD) to the optical data transfer is designed. Tomograph according to one of the preceding claims, wherein the power supply means for supplying the device for wireless communication (A, LD) is designed. Tomograph according to one of the preceding claims, in which the sensor arrangement (SA1, SA2) has at least one display device (D). Tomograph according to one of the preceding claims, in which the sensor element (TS, MS) has at least one magnetic field sensor (MS), temperature sensor (TS), a camera, a microphone and / or a Includes sensor for creating an electrocardiogram. Tomograph according to one of the preceding claims, designed such that the sensor arrangement outside an operating time the tomograph is in a resting state, being at rest in the Essentially no energy is consumed by the sensor array. Magnetic resonance tomograph according to one of the preceding claims.