HU223884B1 - Method and circuit arrangement for decreasing oscillation intention of parasitic circuits of secondary coils of an anode-transformer of a half-wave x-ray equipment without loss of power - Google Patents

Abstract

The subject of the invention is a method for reducing the vibration tendency of parasitic circuits in the secondary coil (17) of the anode transformer (15) of a half-wave X-ray device without loss of power. During the procedure, the anode transformer of the half-wave X-ray equipment is fed with a quadrature alternating voltage with a frequency higher than the mains frequency. The invention further discusses the switching arrangement for reducing the vibration tendency of the parasitic circuits in the secondary winding (17) of the anode transformer (15) of the half-wave X-ray equipment without power loss. The switching arrangement has an energy transfer frequency square wave generator (1), while the outputs of a high-frequency switching power amplifier (5) with a fixed or variable DC power input (24) containing a PWM control unit (6) and a bridge-connected inverter (9) are connected to the inputs of the anode transformer (15) of the X-ray tube (19) . The essence of the method according to the invention is that - the square-shaped alternating voltage is produced with a high-frequency switching amplifier (15), and - during the ramp-up or ramp-up and ramp-down time of the square-wave voltage, the duty cycle of at least one PWM signal is continuously changed, and - the ramp-up or the ramp-up and the optimal slope of the descent is set by decreasing or increasing the rate of change of the filling factor. The essence of one version of the switching arrangement according to the invention is that the output (2) of the square wave generator (1) is connected to the control signal input (7) of the PWM control unit (6) that determines the degree of control via a slope and amplitude limiting unit (3). The essence of another version of the switching arrangement according to the invention is that the output (2) of the energy transfer frequency square wave generator (1) is connected to the inhibit input (21) of the PWM control unit (6), while the soft start circuit of the PWM control unit (6) is suitable for adjusting the ramp slope. (23) is bound. ŕ

Description

The present invention relates to a method for reducing power loss in a secondary winding of parasitic circuits in the secondary winding of anode transformers of half-wave X-ray equipment, wherein the frequency of the inverter controlling the anode transformer of the half-wave X-ray unit is more than The invention further relates to a circuit arrangement for reducing power loss in a secondary winding of a parasitic circuit of a secondary winding of the anode transformer of anode transformer of a half-wave X-ray equipment, which has a fixed frequency inverter The outputs of the switch mode amplifier are connected to the input of an X-ray anode transformer.

As is known, the advantage of using single-tier, half-wave X-ray equipment is to take advantage of the single-path, half-wave rectifier property of the X-ray tube, thereby eliminating the need for a high-voltage rectifier. As a result, the X-ray tube can be housed in a housing (X-ray tank) common to the high-voltage transformer, which in turn makes the high-voltage cable oblivious.

The X-ray emission intensity is determined by the heating current-controlled cathode temperature, while the emission wavelength spectrum is determined by the electric potential difference between the anode cathode. The latter can be controlled by changing the anode voltage. These are produced by the X-ray power supply.

If the anode transformer of the X-ray device is powered by a rectangular AC voltage, it has the advantage that the X-ray emission of the anode is positive, the cathode negative polarity is the same throughout the half-period of the rectangular voltage causing X-rays. The X-ray tube conducts during this half-life, behaves like a pure ohmic load, and does not contain an energy reservoir, ie a one-fourth load.

As is known, it is a general endeavor to reduce the external dimensions and weight of devices and equipment such as X-rays. The size of the X-ray tank is primarily determined by the size of the anode transformer supplying the anode voltage of the X-ray tube. The weight and size reduction of the anode transformer can be achieved by increasing the power transmission frequency. If, on the other hand, the anode transformer is fed at a frequency higher than the mains frequency, power converters must be used. Therefore, from a technical and economic point of view, it is advisable to use a high-voltage switching amplifier, the simplest version of which is the asymmetric half-bridge inverter.

However, supplying the anode transformer with a rectangular alternating anode voltage is a serious problem because the winding capacitance and scattering inductance of the high voltage secondary winding of the anode transformer form a parasitic oscillating circuit. The presence of a parasitic oscillating circuit and the high voltage insulation requirements make it difficult to choose the optimal power transmission frequency, since the higher the power transmission frequency would be desirable to reduce the anode transformer outer dimension, while the isolation aspects and the parasitic oscillating circuit limit it. Decreasing dimensions imply a proportional reduction in creep distances and insulation distances, thus increasing the risk of reducing the voltage tolerance and increasing the resonance frequency, so that the switching frequency must be determined by compromising the adjustment of these two opposing effects. In addition, the vibration tendency of the parasitic oscillator circuit should be damped at the power transfer frequency, with a power loss-free solution as far as possible.

A circuit arrangement such as the Problems of X-Ray Generators for Industrial Purposes is known. PEMC 98 Prag, September 8-10, 1998. Proc. pp. 8-111-8-115. c. wherein the anode transformer of a half-wave X-ray machine is powered by a quadrature voltage of more than a mains frequency, but no power loss solutions are used to attenuate the parasitic a rectangular power supply circuit for the anode transformer.

This solution has several disadvantages. On the one hand, optimum damping of the parasitic oscillator circuit is not achieved in any operating state, and on the other hand, the applied serial damping resistor generates power loss and voltage drop.

No power loss-free solution is available for damping parasitic vibration circuits in the anode transformer of quadrature-powered X-ray equipment.

It is an object of the present invention to provide a method and circuitry suitable for carrying out the method, whereby the rectification of a parasitic oscillating circuit in a rectangular-powered half-wave X-ray apparatus can be resolved without loss of power.

The invention is based on the discovery that reducing the vibration tendency of a parasitic oscillator circuit can be accomplished without power loss by adjusting the rectangular voltage supplying the anode transformer to a high-frequency switching power amplifier operating at a switching frequency substantially higher than its frequency, adjusting the fill factor of the PWM signal controlling the high frequency switching power amplifier to a specified value, which has a duty cycle of 0 or a minimum of 0 or 1 or

EN 223 884 Β1 increases continuously between a maximum value of less than 1, a constant value of less than 1 during a run, and a value of less than 0 or a minimum of 0, the mean value of the voltage at the output terminals and the slope of the change can be set to an optimum slope at which the parasitic oscillating circuit becomes aperiodic and consequently the anode voltage of the half-wave X-ray tube is adjusted without overshoot.

The essence of the process according to the invention is that

generating the rectangular AC voltage with a high frequency switching power amplifier comprising a PWM controlled inverter, and

- continuously changing the fill factor of at least one PWM signal during the rise of the rectangular voltage, or during the rise and fall of the rectangle, and

adjusting the optimum slope of the ascent, or the ascent and the deceleration, by reducing or increasing the rate of change of the fill factor.

According to one embodiment of the invention, the output of the power transmission frequency rectangular wave generator is steep and is connected via an amplitude limiting unit to the control signal input of the PWM control unit which determines the output level. Another embodiment of the circuit arrangement of the present invention is that the power transmission frequency rectangular output is connected to the inhibit input of the PWM control unit and a soft starter circuit for adjusting the ramp slope of the soft starter input of the PWM control unit.

The invention will be explained in more detail with reference to the embodiments shown in the figures, Fig. 1 is a block diagram of an embodiment of the invention, Fig. 2 is a block diagram of another embodiment of the invention, shows timeline diagrams explaining the procedure.

In the switching arrangement of FIG. 1, the power transmission frequency rectangular wave generator 1 output 2 slope and amplitude limiter 3 slope limiter control input 4, and the output of the limiting circuit 3 determines the high frequency switching amplifier 5 control input signal control unit 7. One of the control signal outputs of the PWM control unit 6 is connected to one of the control signal inputs 10 of the bridge inverter 5 of the amplifier, while the other control signal output 11 of the PWM control unit 6 is connected to the other control input 12 of the inverter. The inverter 9 is a preferred embodiment of an asymmetric half-bridge inverter 9.

The outputs of the inverter 9, which are also the outputs 13, 14 of the amplifier 5, are connected to the two ends of the primary winding 16 of the anode transformer 15. The anode transformer 15 has two secondary windings 17, 18, one of which is adapted to supply an x-ray anode voltage 19 and the other secondary winding 18 to provide an X-ray heating voltage 19. The limiting circuit 3 is provided with an input 20 suitable for introducing an amplitude adjustment signal. If the PWM control unit 6 also has a blocking input 21, the output 2 of the square wave generator 1 may also be connected to the blocking input 21. In this case, the run is unrestricted, ie it will be jumping.

The circuit arrangement according to another embodiment of Fig. 2 differs from that of Fig. 1 in that the amplifier 5 has a stop input 21 and an optional soft start input 22. Output 21 of rectangular oscillator 1 is directly connected to blocking input 21, and soft starter circuit 23 for adjusting ramp slope 22 is connected to soft starter input 22. The power input 24 of the amplifier 5 is a fixed or variable DC power supply 24. A variable voltage source 25 is connected to the control signal input 7 of the PWM control unit 6 to determine the degree of control.

The circuit arrangement according to the invention can be operated by the method according to the invention as follows:

The control signal input 7 provided to the amplifier 5 (which is also the control signal input of the PWM control unit 6) causes the control rate 31 to vary between 0 and 1 as a result of the control signal 31. The control signal 31 may be a voltage or a current signal. As a result, an average output signal 35, proportional to the control signal 31 applied to the control signal input 7 of the amplifier 5, is generated on a consumer comprising an energy storage device connected to the outputs 13,14 of the amplifier 5. In order to produce a voltage averaged by transient vibration-free voltage, the secondary winding 17 of the anode transformer 15 supplying the anode circuit of an provided 31 control signals. For example, the vibration tendency of parasitic circuits is prevented in the secondary circuit of the anode transformer 15 which supplies the X-ray tube 19 by damping the parasitic oscillator circuit by feeding the anode transformer 15 to the frequency of the amplifier 5, and a trapezoidal output signal 35 which is centered near the rectangle and is formed by a lower frequency modulated response signal 31 having a corresponding incidence. The frequency of the control signal - modulating signal 31 - determines the frequency of power transmission. From one of the control signal outputs 8 of the PWM control unit 6, a PWM signal 32 is output from one of the control signal inputs 10 of the inverter 9 and from the other control signal input 11 of the PWM control unit 6.

It is controlled by an incoming PWM signal 33, which is offset by half a period relative to the 32 PWM signal.

It follows that the method according to the invention is capable of preventing the vibration of the parasitic circuit by adjusting the optimum up and down slope of the control signal in a lossless manner. If the output 2 of the rectangular wave generator 1 is also connected to the blocking input 21, the run is unrestricted, i.e. it will be jump-like.

The process according to the invention may be implemented differently from the above, if the PWM control unit 6 has both a stop input 21 and a soft start input 22. In this case, a variable voltage constant signal 15 is output from the output of the DC voltage source 25 connected to the control signal input 7 of the PWM control unit 6, which causes the DC output signal 23 to be applied to the soft start input 22 via the soft start signal 22. but develops gradually, however, since the output 2 of the square wave generator 1 is connected to the blocking input 21, the run is unlimited, i.e. it will be leap-like.

Another embodiment is that the bridge inverter 9 has an asymmetric half-bridge arrangement and, according to prior art, one of the inputs 32 of one of the control signal outputs 8 of the PWM 6 is fed to one of the inputs 9 of the inverter 9, generates the control signal 34 from the output 2 of the generator. The dashed line in Figure 2 illustrates this connection and in this case the control signal output 11 of the PWM control unit 6 is not connected to the control signal input 12 of the inverter 9.

Claims (10)

PATENT CLAIMS A method for reducing the power loss of a parasitic circuit in a secondary winding of an anode transformer of a half-wave X-ray equipment, which method comprises changing the frequency of the generating the rectangular AC voltage with a high frequency switching amplifier (5) comprising a PWM controlled inverter (9); - continuously changing the fill factor of the at least one PWM signal (32, 33) during the rise or fall of the rectangular voltage, and adjusting the optimum slope of the ascent, or the ascent and the deceleration, by reducing or increasing the rate of change of the fill factor. Method according to Claim 1, characterized in that, in the second half of the energy transmission frequency, the operation of the high frequency switching amplifier (5) is disabled by the output signal (2) of a rectangular wave generator (1). Method according to claim 2, characterized in that in the high frequency switching amplifier (5) 50 asymmetric half-bridge inverters (9) are operated, one branch of which is a PWM control signal (32 or 33) and the other branch of the rectangular wave generator (1). ) output signal (34). 4. A circuit arrangement for reducing the power loss-free power of parasitic circuits in the secondary winding of anode transformers of anode transformers of hemispherical X-ray equipment, which circuit comprises a quadrature-frequency inverter with power transmission frequency inverter and a PWM control unit and bridge The anode transformer is connected to an input, characterized in that the output (2) of the square wave generator (1) is connected to the control signal input (7) of the PWM control unit (6) which defines the output level through the slope and amplitude limiter (3). The circuit arrangement according to claim 4, characterized in that the output (2) of the rectangular wave generator (1) is also connected to the blocking input (21) of the PWM control unit (6). 6. A switching arrangement for reducing power loss in a secondary arrangement of parasitic circuits in the secondary winding of anode transformers of half-wave X-ray equipment, which in a switching arrangement has a power transmission frequency. There are 40 rectangular wave generators, while a high frequency switching amplifier output with a PWM control unit and a bridge inverter with a fixed or variable DC power input for the input of an X-ray anode transformer 45, characterized in that the power transmission frequency rectangular wave generator (1) has a soft starter circuit (23) for disabling the input (21) of the PWM control unit (6) and a soft starter input (22) for the soft starter input (22) of the PWM control unit (6). connected. Circuit arrangement according to claim 6, characterized in that one of the control signal outputs (8) of the PWM control unit (6) to one of the control signal inputs (10) of the bridge inverter (9) and the PWM control unit 55 (6) of the other the control signal output (11) is connected to the other control signal input (12) of the bridge inverter (9). The circuit arrangement according to claim 6, characterized in that the PWM control unit (6) One of the control signal outputs (8) is a bridge inverter EN 223 884 Β1 (9) is connected to one of the control signal inputs (10), while the output (2) of the square wave generator (1) is connected to the other control input (12) of the bridge inverter (9). 9. A 6-8. A switching arrangement according to any one of claims 1 to 6, characterized in that a variable voltage source (25) is connected to the control signal input (7) of the PWM control unit (6) which determines the degree of control. 10. Circuit arrangement according to any one of claims 1 to 4, characterized in that the bridge-connected inverter (9) is an asymmetric half-bridge inverter (9).