Patent Application
20140097699
The invention relates to a circuit according to the preamble of claim 1, a tomograph, particularly a computer tomograph, as claimed in the preamble of claim 26, and to a method as claimed in the preamble of claim 27.
In many electrical appliances, there is a device which is movable with respect to a stator and which must be supplied with energy from an energy source via the stator. An example of this is a tomograph such as, for example, a computer tomograph, having an annular tunnel in which an object can be accommodated, the structure of which is to be recorded. The annular tunnel is also called gantry in conjunction with a computer tomograph. In the annular tunnel, a number of imaging sensors are arranged which move around the object with the annular tunnel and thus scan it. From the sum of all scanned values, an image of the structure of the object is generated which can be output, for example, on a screen.
To supply the imaging sensors and other elements in the annular tunnel, such as, for example, an X-ray source or a data transmission device for transmitting the scanned values to a processor in the stator, with electrical energy and in order to send the data to the stator, various methods are known conventionally. On the one hand, the electrical energy and the data can be transmitted to the annular tunnel via a cable which, however, restricts the margin for movement due to the finite length of the cable. On the other hand, it is known to use sliding contacts which slide at the annular tunnel or at the stator which, however, leads not only to
a high material wear but also entails a high requirement of space. Finally, it is known to transmit the electrical energy inductively which, however, leads to a poor efficiency of the transmission due to high losses due to parasitic elements such as the stray inductance of the magnetic coupling. To lower the losses, U.S. Pat. No. 5,608,771 proposes to attenuate the stray inductance by means of a capacitance connected in series with the stray inductance.
In every case, it is necessary to stabilize the load voltage in the annular tunnel.
It is the object of the invention to improve the stabilization of the load voltage in a device movable relative to a stator.
The object is achieved by the features of the independent claims. The dependent claims contain preferred developments of the invention.
The invention is based on the concept of improving the stabilization of the load voltage by a control of the load voltage. The invention is based on the finding that the load voltage is conventionally stabilized by controlling the input voltage at the stator on the basis of a feedback of the load voltage from the annular tunnel. It is a further finding of the invention that at the beginning of an electrical energy transmission by means of magnetic coupling, the possibilities for wireless feedback of the load voltage are limited because a corresponding data transmission device must first be supplied with electrical energy. When using magnetic coupling, as a result, it can take a very long time in some cases until the feedback for the control is available. When the feedback is finally available, the load voltage may be changed into states from which, after an intervention of the control, it takes a very long time to stabilize it. However, a transformer operating by means of magnetic coupling can be divided, in network theory, into an ideal transformer without losses, into a main inductance connected in parallel with the ideal transformer on the input side, and into a stray inductance connected in series on the input side. If a capacitance is connected to the input of the transformer, the resonant circuit produced therefore acts only at the input side and dominates the transmission characteristic of the entire system. If the transmission characteristic and the input voltage of the transformer are known, the load voltage can be derived without having to be measured. The conventional control of the load voltage can therefore be omitted at least in the initial phase and replaced by simple control. This is particularly advantageous for the electrical energy transmission by means of magnetic coupling since the load voltage itself can be stabilized even without a data transmission device in the start-up phase of the entire system.
The invention, therefore, specifies a circuit for transmitting an input voltage from an electrical energy source in a stator to a load within a device movable relative to the stator, which comprises the following features: an actuating element for converting an input voltage into a transmission voltage, a resonant circuit for receiving the transmission voltage, wherein the resonant circuit contains a capacitance and a primary winding of a transformer; and the transformer comprising the primary winding and a secondary winding, wherein the primary winding is provided for transmitting the transmission voltage to the secondary winding and the secondary winding is provided for delivering the received transmission voltage to the load, wherein the actuating element is provided for adjusting the frequency of the transmission voltage in such a manner that the transmission ratio of the resonant circuit remains essentially constant for a predetermined range of values of a load which can be connected to the secondary winding so that the transmission ratio of the resonant circuit is independent of the load within the predetermined range of values.
The invention has the advantage that the stray inductance of the transformer can now be applied usefully for stabilizing the load voltage. Due to the load-independent transmission ratio, the circuit requires, in particular, no feedback from the movable device so that a control of the load voltage can be omitted. This reduces the complexity of the overall system and renders it more insusceptible to faults.
In a particular embodiment of the invention, the actuating element can be provided for adjusting the frequency of the transmission voltage on the basis of a control characteristic in which the transmission characteristic of the resonant circuit is plotted over the frequency to be adjusted.
In a development of the invention, a shape of the control characteristic can remain essentially constant within the predetermined range of values of the load so that the shape of the control characteristic is independent of the load within the predetermined range of values.
In a development of the invention, the actuating element is provided for adjusting the frequency within a predetermined frequency range. This enables the technical limits to be taken into consideration in the detection, processing and provision of the control characteristic and avoids the operation of a system having the specified circuit in unknown operating states damaging the system.
In a preferred development of the invention, the capacitance is selected in such a manner that the resonant frequency of the electrical resonant circuit is outside the predetermined frequency range. In this manner a strictly monotonous control characteristic is provided. This enables a control system to intervene in the control at any time. Without the strict monotony of the control characteristic, the control system could intervene at a point of the control characteristic from which it moves away from the operating point to be corrected in the control characteristic and thus runs unstably. This risk is avoided effectively by removing the resonant frequency from the frequency range.
In a particularly preferred development of the invention, the frequency range is selected in such a manner that the control characteristic has a fixed frequency in which the transmission ratio of the resonant circuit is independent of an impedance of the load. Within the range of this fixed frequency in the control characteristic, reliable controllability of the load voltage is given even when the load impedance is to be increased from a rest state and its load states thus change continuously.
In an additional development of the invention, the fixed frequency is the limit frequency of the frequency range which is on the side of the frequency range directed toward the resonant frequency. This avoids that the resonant frequency falls into the frequency range due to changes of the load state at the load impedance. This can happen because the control characteristic of the resonant circuit becomes deformed with increasing load and the resonant frequency during this process approaches the fixed frequency more and more. Although the resonant frequency can approach the frequency range arbitrarily, for example during the starting-up of the load impedance described before, due to the position of the frequency range according to the additional development, it can never fall into the frequency range.
In another preferred development of the invention, the other limit frequency of the frequency range is allocated to a transmission ratio of the resonant circuit, the change of which is limited to a predetermined value for a predetermined range of load states of the load impedance. In this manner, further stabilization of the control characteristic is achieved for a particular operating state.
The predetermined range of load states comprises preferably the load states during start-up of a load, connected to the circuit, in the movable device. Thus, the load can be started up with a constant supply voltage in the movable device on switch-on so that an essentially load-independent control characteristic is achieved by this means for the large load impedances present on start-up of the load and thus for low loads.
In another embodiment of the invention, the actuating element is provided for calling up the control characteristic from a memory so that the control characteristic is immediately available and does not have to be first acquired anew by calculation, measurement or other ways when the circuit is started.
In a preferred embodiment of the invention, the circuit has a write device for storing values of the control characteristic in the memory on the basis of a measurement of the transmission ratio of the resonant circuit. In this manner, the control characteristic can always be adapted to the real transmission characteristic of the resonant circuit when, for example, the values of the individual components of the resonant circuit change with time.
In a particularly preferred embodiment of the invention, the write device is provided for measuring the transmission ratio on the basis of a sweep of the frequency of the transmission voltage. A sweep is a sinusoidal signal, the frequency of which changes continuously starting from a lower limit frequency to an upper limit frequency. Such a sweep can be generated simply by means of a frequency generator and enables the control characteristic to be recorded with an arbitrarily high accuracy.
In a development of the preferred embodiment of the invention, the circuit is provided for directly connecting the resonant circuit to an output of the circuit during the sweep since, as a rule, movement of the movable device is not necessary during the learning process.
In another preferred embodiment of the invention, the write device is provided for measuring the transmission ratio on the basis of a voltage pulse as transmission voltage, the write device being provided for detecting a resonant circuit current with which the resonant circuit reacts as response to the voltage pulse. The voltage pulse can be implemented not only with comparatively little energy but the measurement can also be performed within a comparatively short period of time. Nevertheless, the phase difference between the voltage pulse and the resonant circuit current contains all the necessary information for determining the transmission ratio. Due to the shortness of the voltage pulse, the measuring of the transmission ratio of the resonant circuit based on the voltage pulse can also be performed during the operation of the load in order to update the control characteristic continuously.
In another embodiment of the invention, the circuit has a current measuring device for measuring a resonant circuit current through the resonant circuit, wherein the actuating element is provided for controlling the frequency of the transmission voltage in such a manner that the resonant circuit current does not exceed a predetermined value. This ensures that the current through the resonant circuit remains limited in order to protect the individual components in the circuit against an electrical overload.
In a further embodiment of the invention, the circuit has a voltage measuring device for measuring the load voltage, wherein the actuating element is provided for controlling the load voltage on the basis of the frequency of the transmission voltage in such a manner that the load voltage follows a nominal voltage value. In this manner, the accuracy of the load voltage can be increased further in order to correct, for example, unexpected disturbances for the load voltage.
In a preferred embodiment of the invention, the voltage measuring device is arranged on the stator side in the circuit, the voltage measuring device having a data receiving device for receiving the load voltage from the movable device. These data receiving devices can utilize in a particularly advantageous manner a pre-established data link of the movable device for the transmission of measurement data or other useful data in order to receive the load voltage. The control system for the load voltage can thus be implemented in a space-saving and cost-effective manner in the circuit according to the invention.
In a particularly preferred embodiment of the invention, the circuit is provided for starting the control of the load voltage on the basis of the frequency when the load voltage is available at the data receiving device. In this manner, the load voltage is initially converted by the actuating element, during the control process, into a state close to the state to be corrected so that the control of the load voltage can adjust it quickly and stably to the state to be corrected. Furthermore the control characteristic can also be used during the control of the load voltage for including the input voltage as interference variable intrusion into the control of the load voltage.
In a further development, the circuit is provided for ending the adjustment of the frequency of the transmission voltage on the basis of the control characteristic and thus the control of the load voltage when the control of the load voltage has been started. In this manner, it is possible to avoid the dynamic range of the control loop being restricted by the control of the load voltage.
In another embodiment of the invention, the transformer has an additional inductance connected in series with the primary winding so that the stray inductance can be increased, if necessary, when the capacitance is insufficient for achieving a desired transmission characteristic for the resonant circuit. Even if capacitors having suitable capacitances were available in theory, capacitors having capacitances which are more costeffective, more space-saving or more failure-proof can also be used for dimensioning the transmission characteristic of the resonant circuit due to the additional inductance. The margin for dimensioning of the resonant circuit is therefore extended by the additional inductance.
In a development of the circuit specified, the capacitance, the additional inductance and the primary winding are connected in series so that an LLC converter is obtained which is available as standard circuit so that the resonant circuit can be implemented cost-effectively. An LLC converter is an electrical component of a transformer, to the input of which a capacitor and a coil are connected in series.
In an additional development of the invention, the circuit comprises a further resonant circuit symmetric to the resonant circuit, which has a series circuit of a symmetry capacitance corresponding to the capacitance and a symmetry inductance corresponding to the additional inductance, wherein the primary winding is connected between the resonant circuit and the symmetry resonant circuit. Since the two resonant circuits are correspondingly located at the feed line to and the bleed line from the primary winding, they receive the transmission voltage displaced by one half wave. This has the effect that interfering emissions generated by the resonant circuits are also radiated displaced by one half wave so that they cancel each other.
In another development of the invention, the capacitance is connected in series with the primary winding, the circuit having a relief capacitance which is connected in parallel with the primary winding. The relief capacitance can be optimized for short-circuiting highly transient components in the transmission voltage and thus filtering these out of the transmission voltage. This limits the rise of the transmission voltage and the radiation of interfering emissions by the resonant circuit is reduced further.
The invention also specifies a tomograph, particularly a computer tomograph, for recording the spatial structure of an object arranged in an annular tunnel, wherein the annular tunnel rotates around a stator during the recording. The tomograph comprises a circuit according to the invention for transmitting an input voltage from an electrical energy source to a load within the annular tunnel.
Also part of the invention is a method for transmitting an input voltage from an electrical energy source in a stator to a load within a device movable relative to the stator having the steps of converting an input voltage into a transmission voltage, receiving the transmission voltage with a resonant circuit which contains a capacitance and a primary winding of a transformer, transmitting the transmission voltage to a secondary winding of the resonant circuit, delivering the transmission voltage received by the secondary winding to the load, detecting the input voltage and adjusting the frequency of the transmission voltage on the basis of a control characteristic in such a manner that the amplitude of the load voltage dropped across the load remains constant, the transmission ratio of the resonant circuit being plotted over the frequency to be adjusted in the control characteristic.
Developments of the method can be method steps which implement the features of the specified circuit appropriately according to the subclaims.
The characteristics, features and advantages of this invention, described above, and the manner in which these are achieved will become clearer and more clearly comprehensible in conjunction with the following description of the exemplary embodiments which are explained in greater detail in conjunction with the drawings, in which:
The exemplary embodiments described in the text which follows can be combined with one another also in parts.
Reference is made to
So that the margin for movement of the annular tunnel is not unnecessarily restricted and the material wear of the elements for the transmission of energy from the supply side 4 to the load side 6 remains limited, the energy transmission is effected wirelessly via a transformer which is shown as a real transformer 8 in
As shown in
In this equivalent circuit, it is conventionally desired to dimension the main inductance 16 as large as possible since it carries the magnetization current and to keep the stray inductance 18 as small as possible since its magnetic field does not contribute anything to the transmission and therefore interferes in the dimensioning. In contrast to this conventional approach, the invention uses the stray inductance 18 usefully, for example, in the modulation of an output voltage 20 of the circuit 2. The output voltage 20 is in this exemplary embodiment the load voltage which is dropped across the load on the load side. However, the output voltage 20 can still be reprocessed on the load side before the supply to the load in that, for example, it is rectified or filtered. For the subsequent explanations, the corresponding network components for rectification and/or for filtering can be assumed to be lossless for the sake of simplicity so that they will not be discussed further in the text which follows.
For the implementation of the invention in the present embodiment, a resonant circuit 24 is built up out of the primary winding 10 of the real transformer 8 and a capacitance 22, via which resonant circuit the transmission voltage 9 can be transmitted to the load side 6 by the real transformer 8. Since, as in
The transmission characteristic of the resonant circuit 24 is described via control characteristics 30 which are shown, by way of example, in
The appearance of the control characteristics 30 is influenced by the electrical load which is not shown in
In addition, the appearance of the control characteristics 30 can also be changed actively by the values of the capacitance 22. This primarily relates to the resonant frequencies 31 of the resonant circuit 24. If the available values of the capacitance 22 are not sufficient for matching the control characteristics to a desired transmission characteristic of the resonant circuit 24, an additional inductance 32 can also be accommodated optionally in the resonant circuit.
For the technical implementation of the control approach, described above, for modulating the output voltage 20, an actuating element 34 is provided which receives an input voltage 36 supplied to the supply side 4 and converts it into the transmission voltage 9. For the conversion, the actuating element 34 has an inverter 38, known to the expert, which adjusts the frequency 27 of the transmission voltage 9. For adjusting the frequency 27, the inverter 38 needs drive signals 40 which it receives from a corresponding drive unit 42. For generating the drive signals 40, the drive unit 42 receives the frequency 27 which is to be adjusted in the transmission voltage 9 from an allocation unit 44 in which one of the control characteristics 30 of the resonant circuit 24, described above, can be stored.
In the operation of the previously described modulation of the output voltage 20, the allocation unit 44 can be initially initialized in that it receives the input voltage 36, arbitrarily selects a starting frequency for the frequency 27 of the transmission voltage 9 and, on the basis of this, determines the output voltage 20. If the inverter 38 outputs the transmission voltage 9 on the basis of this firmly predetermined frequency, this previously determined output voltage 20 occurs on the load side 6. If the input voltage 36 then changes, for example due to interfering influences, the allocation unit 24 can calculate, on the basis of the previously determined output voltage 20 and the now new input voltage 36, assuming that the inverter 38 is free of electrical losses, a necessary transmission ratio 25 in order to keep the output voltage 20 constant.
Since, due to the principle involved, the output voltage 20 is an alternating voltage, this means that it is attempted by the drive to keep the output voltage 20 constant in its amplitude. But the output voltage 20 can also be a direct voltage, the transmission voltage 9 received at the secondary winding 12 being rectified before it is output as output voltage 20. In this case, the level of the output voltage 20 is kept constant. For the sake of simplicity, however, the level of a direct voltage is to be designated as amplitude of a direct voltage in the sense of the invention.
On the basis of the necessary transmission ratio, the allocation unit can output the corresponding frequency 27 for the transmission voltage 9 to the inverter 38 in the control characteristic 30, so that the inverter adapts the transmission voltage 9 correspondingly in its frequency.
As already mentioned, the control characteristic 30 depends on a load connected on the load side 6, which is problematic in particular during the start-up of the load as the electrical power recorded, and thus the load, keeps on increasing. Although it is possible, in principle, to store all control characteristics 30 in the allocation unit, the selection of the correct control characteristic requires knowledge about the state of the load on the load side 6 and thus a feedback of information. However, this should be avoided which is why a suitable control characteristic 45 has to be selected from the control characteristics shown in
A fixed transmission ratio 48 of one, through which all control characteristics 30 run at a particular fixed frequency 50, is characteristic of all control characteristics 30. This fixed frequency 50 is therefore selected as lower limit frequency 50 for the frequency range 46. To determine the upper limit frequency 52 of the frequency range 46, a load range and a transmission ratio difference 54 can be predetermined. In the next step, the frequency 27 is determined in the diagram of
Compared with the first exemplary embodiment, the second exemplary embodiment is extended by a relief capacitance 56 and a symmetry resonant circuit 58.
The relief capacitance 56 short-circuits the transmission voltage 9 for high frequencies. By this means, highly transient components which lead to a rapid rise in the transmission voltage 9 are filtered out of the transmission voltage 9. This counteracts an unwanted radiation of interfering emissions by the resonant circuit 24. The relief capacitance 56 can either be selected in such a manner that it has no influence on the transmission characteristic 27 of the resonant circuit 24 or it can also be taken into consideration in the determination of the transmission characteristic of the resonant circuit 24.
As an alternative or additionally, a symmetry resonant circuit 58, in which the capacitance 22 and the additional inductance 32 are again arranged in series, can be arranged in the feedback branch of the supply side 55 of the circuit. Since the feedback branch of the supply side 55 of the circuit receives the transmission voltage 9 phase shifted by 180° compared with the resonant circuit 24, radiated interfering emissions are mutually cancelled by the resonant circuit 24 and the symmetry resonant circuit 58.
In
The learning device 66 can be a processor which automatically measures an actual control characteristic of the resonant circuit 24 at a particular load state as suitable control characteristic 45. For this purpose, the load 70 can be put into a predefined state or disconnected completely from the load side 6.
For measuring the actual control characteristic, the learning device 66 can cause the inverter 62, for example via the drive unit 42, with suitable drive signals 40 to output a transmission voltage 9 with a sweep, in which the transmission voltage 9 moves once over all frequencies 27 of the frequency range 46 of the suitable control characteristic 45. The learning device 66 can thereupon detect the reaction of the output voltage 20 and the input voltage 36 and, using the resulting control characteristic data 74, update the suitable control characteristic 45 in the allocation unit 44.
As an alternative the learning device 66 can also measure a current 76 through the primary winding 10 and, on the basis thereof, determine a phase difference between the transmission voltage 9 and the current 76. From this phase difference, the characteristic variables of the resonant circuit 24 can be derived directly.
According to the fourth exemplary embodiment, the circuit 78 can have a voltage controller 80 which drives the drive unit 42 on the basis of a voltage control difference 81 between a nominal voltage 82 and the output voltage 20. The voltage controller can intervene when the data link 68 between the supply side 4 and the load side 6 has been built up. The control according to the basic concept of the invention supports the voltage control in a particularly advantageous manner due to the fact that it moves the output voltage 20 very close to the nominal voltage 82. As a result, the control can settle rapidly to the nominal voltage 82.
In addition, a current controller 84 can also be provided which controls the drive unit 42 on the basis of a current control difference 86 between a nominal current value 88 and the current 76 through the primary winding 10. The nominal current value 88 can be a limit value for the current 76 through the primary winding 10 so that the components within the resonant circuit 24 are protected against too high a current and therefore against an electrical overload.
Overall, the transmission characteristic of a resonant circuit constructed of the primary winding of a real transformer and a capacitance connected thereto is thus utilized for controlling the output voltage of the transformer.
Although the invention has been illustrated and described in greater detail by the preferred exemplary embodiment, the invention is not restricted by the examples disclosed and other variations can be derived therefrom by the expert without departing from the protective scope of the invention.
2 Circuit
4 Supply side
6 Load side
8 Real transformer
9 Transmission voltage
10 Primary winding
12 Secondary winding
14 Ideal transformer
16 Main inductance
18 Stray inductance
20 Output voltage
22 Capacitance
24 Resonant circuit
25 Transmission ratio
27 Frequency of the transmission voltage
28 Influence of the load on transmission voltage
30 Control characteristics of the resonant circuit
31 Resonant frequencies of the resonant circuit
32 Additional inductance
34 Actuating element
36 Input voltage
38 Inverter
40 Drive signals
42 Drive unit
44 Allocation unit
45 Selected control characteristic for the control
46 Operating frequency range of the inverter
48 Fixed transmission ratio
50 Fixed frequency, lower limit frequency
52 Upper limit frequency
54 Transmission ratio difference for the upper limit frequency
55 Supply side
56 Relief capacitance
58 Symmetry resonant circuit
60 Circuit
62 Inverter
63 Rectifier
64 Three-phase voltage
66 Learning device
68 Data line
70 Load
72 Multiplexer
74 Control characteristic data
76 Current through the primary winding
78 Circuit
80 Voltage controller
81 Voltage control difference
82 Nominal voltage
84 Current controller
86 Current control difference
88 Nominal current value
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2011 077 085.2 | Jun 2011 | DE | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/EP2012/059387 | 5/21/2012 | WO | 00 | 12/6/2013 |
