EP0487767A1 - High frequency X-ray generator - Google Patents

Abstract

In operation with an X-ray tube with a metal centre part, it is intended to compensate for the current from the metallic centre part of the X-ray tube when using two individual invertors (6, 7) and high-voltage transformers (9, 10) for two high-voltage rectifiers which are connected in series. <??>The capacitance of the capacitor (12) of the invertor (7) on the cathode side is greater than the capacitance of the other invertor (6). <IMAGE>

Description

The invention relates to a high-frequency X-ray generator with two resonant circuit inverters fed by a DC voltage source, each of which feeds a high-voltage transformer, an X-ray tube being connected to two high-voltage rectifiers connected in series and each high-voltage rectifier being fed by one of the high-voltage transformers.

In such a high-frequency x-ray generator, an x-ray tube with a metal middle part can be used as the x-ray tube, which is connected to the connecting line between the two high-voltage rectifiers. A current flows through the metal middle part, which represents an additional load for the high voltage side of the X-ray generator.

In the case of a high-frequency X-ray generator of the type mentioned, in which the high-voltage transformers are not rigidly connected on the primary side, but are each supplied by their own inverter, the current from the metal center part causes the center point of the high voltage to shift.

The invention has for its object to design a high-frequency X-ray generator of the type mentioned so that this shift of the center of the high voltage is avoided.

This object is achieved in that the resonant circuit impedances are different. If the capacitance of the resonant circuit capacitor of the cathode-side inverter is increased in comparison to the capacitance of the resonant circuit capacitor of the anode-side inverter, then, if appropriate Dimensioning of the current flowing through the metal middle part can be compensated.

A further development of the invention is that the capacity of one of the resonant circuits can be switched over. In this way, the high-voltage X-ray generator can be used both in connection with an X-ray tube without a metal middle part and in connection with an X-ray tube with a metal middle part. In the first case, two capacitors with the same capacitance are chosen, in the second case the capacitors are chosen differently.

Fig. 1

die für die Erfindung wesentlichen Teile eines Hochfrequenz-Röntgengenerators zur Erläuterung des Erfindungsgedankens, und

Fig. 2 bis 4

verschiedene Ausführungsformen der Wechselrichterschaltung bei dem Hochfrequenz-Röntgengenerator gemäß Fig. 1.

The invention is explained below with reference to the drawing. Show it:

Fig. 1

the parts of a high-frequency X-ray generator essential for the invention to explain the inventive concept, and

2 to 4

Various embodiments of the inverter circuit in the high-frequency X-ray generator according to FIG. 1.

1 shows an X-ray tube 1 with a metal middle part 2, which is connected with its anode to the positive pole of a high-voltage rectifier 3 and with its cathode to the negative pole of a high-voltage rectifier 4. The high-voltage rectifiers 3, 4 are connected in series via a measuring resistor 5. The metal middle part 2 is connected to the negative pole of the high-voltage rectifier 3.

An inverter 6, 7 is assigned to each high-voltage rectifier 3, 4. The inverters 6, 7 are fed by a DC voltage source 8. Each high-voltage rectifier 3, 4 is preceded by a high-voltage transformer 9, 10 (FIGS. 2 to 4) fed by the corresponding inverter 6, 7.

2 shows that the high-voltage transformers 9, 10 together with capacitors 11, 12 form series resonant circuits which lie in a diagonal of the respective inverter 6, 7. The capacitance of the capacitor 12 of the cathode-side inverter 7 is greater than the capacitance of the capacitor 11 of the anode-side inverter 6. As a result, the current flowing off from the metal center part 2 is compensated for.

3, two capacitors 13, 14 are provided in the cathode-side inverter. The capacitor 13 has the same capacitance as the capacitor 11 and is used alone when an X-ray tube without a metal middle part is used. When using an X-ray tube with a metal middle part, as shown in FIG. 1, the capacitor 14 is switched on by a switch 15, as a result of which the capacitance of the resonant circuit of the cathode-side inverter 7 is increased. The circuit according to FIG. 3 can accordingly be used optionally for an X-ray tube with or without a metal middle part.

The same applies to the circuit according to FIG. 4. Here, the cathode-side inverter 7a has two separately controllable half bridges 16, 17. The half bridge 16 is used when using an X-ray tube without a metal middle part and only switches on the capacitor 13, while when using an X-ray tube with Metal middle part for switching on both capacitors 13, 14, both half bridges 16, 17 are controlled synchronously. It is also possible in this case to control only the half bridge 17 and to switch off the capacitor 13 completely if the capacitor 14 has a correspondingly high capacitance.

Claims (4)

High-frequency X-ray generator with two resonant circuit inverters (6, 7) fed by a DC voltage source (8), each of which feeds a high-voltage transformer (9, 10), one X-ray tube (1) being connected to two high-voltage rectifiers (3, 4) connected in series and each high-voltage rectifier (3, 4) is fed by one of the high-voltage transformers (9, 10), characterized in that the resonant circuit impedances are different. High-frequency x-ray generator according to claim 1, characterized in that the resonant circuit capacitor (12, 14) of the cathode-side inverter (7, 7a) has a larger capacitance than the resonant circuit capacitor (11) of the anode-side inverter (6). High-frequency X-ray generator according to Claim 2, characterized in that the resonant circuit capacitance of one of the inverters (7, 7a) can be switched over. High-frequency X-ray generator according to Claim 3, characterized in that an oscillating circuit has two different capacitors (13, 14) which are connected to two separately controllable inverter half bridges (16, 17).

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