FR2479635A1 - Diagnostic X=ray machine radiation level control circuit - uses function generator connected to equaliser to maintain voltage above required level - Google Patents

Abstract

The method of controlling the level of radiation from a diagnostic X-ray machine uses a circuit for the h.v. supply, which includes two triodes with the anode of one triode and the cathode of the other connected to the high voltage connections of the X-ray tube. The control grids of the triodes are connected to an amplifier forming part of radiation control unit. The amplifier (4) is connected to an equaliser with nominal and actual value inputs so as to control the grid potentials of the triodes (2,3). The actual value is supplied by a radiation detector (9). Also connected between the amplifier and equaliser is a function generator (10) and a scanning circuit (11). The function generator is brought into operation when the voltage for the X-ray tube (1) falls below a required level.

Description

 The invention relates to a radiological generator for a radiodiagnostic device comprising a dose rate adjustment circuit, which has, as adjustment element, at least one resistor which can be electronically controlled in the high voltage circuit of the ray tube. X and to which a control signal is sent which is delivered by the dose rate adjustment device comprising an input of the set value and an input of the actual value.

 A radiological generator for this type of radiodiagnostic device is described, for example, in the German patent application published under No. 22 04 453.

In this radiological generator, the high-voltage circuit contains three triodes, the gate potential of which is adjusted in such a way that in these triodes a voltage drop occurs, causing the correct tension of the X-ray tube to be adjusted. The known radiological generator allows very quick elimination of adjustment Xcarts. In the known radiological generator, in addition to modifying the tension of the X-ray tube in the direction of agreement of the real value of the dose rate with the set value, one can also act on the current of the tube to X-rays.

 The object of the invention is to produce a radiological generator of the type indicated above so that the adjustment range is increased compared to the state of the art.

 This problem is solved in accordance with the invention thanks to the fact that the adjustment device has a function generator making it possible to control the undulation of the voltage of the X-ray tube. In the radiological generator according to the invention, it is possible , in order to adjust the dose rate from a maximum value of the X-ray tube voltage up to a lower limit value of for example 50 kV, to modify the X-ray tube voltage. If this adjustment range does not should not be sufficient, it is possible to act additionally on the shape of the voltage curve of the X-ray tube via the function generator. As a result, the adjustment range is significantly increased compared to the state of the art.

 By way of example, an embodiment of the subject of the invention has been described below and illustrated diagrammatically in the appended drawing.

 The drawing shows the high voltage circuit of a radiological generator according to the invention, in which two triodes 2 and 3 are connected in series with an X-ray tube 1. Between the anode of triode 2 and the cathode of triode 3 is present the high voltage delivered by a voltage rectifier and which represents the maximum voltage of the X-ray tube.

The control grids of the triodes 2 and 3 are controlled by an amplifier 4, which is a constituent part of a device 5 for adjusting the dose rate.

The amplification factor of amplifier 4 and consequently the gate potential of triodes 2 and 3 are controlled by a comparator 6 comparing a real value signal present at input 7 and a setpoint signal present at l 'input 8 for dose rate. The actual value signal is delivered by a radiation detector 9.

 A function generator 10, which is controlled by an exploration circuit 11, is mounted between the amplifier 4 and the comparator 6.

 When the difference between the actual value and the set value of the dose rate is between predetermined limits, an agreement of the actual value of the dose rate with the set value by means of a modification of the ohmic resistance of the triodes 2 and 3 is produced by the amplifier 4. The voltage of the X-ray tube then varies within a predetermined range between for example 50 and 150 kV.

When the adjustment deviation exceeds a predetermined value to the point that it would be necessary to carry out a voltage adjustment at a value lower than the lower limit value of for example 50 kV, the function generator 10 is activated by the intermediate of the exploration circuit 11. The function generator 10 modifies the shape of the curve of the voltage of the X-ray tube by means of pulses which it sends to the amplifier 4, so that the triodes 2 and 3 are switched periodically, correspondingly, between a high resistance value and a low resistance value. It is thus possible to act additionally on the actual value of the dose rate in order to achieve a balancing of this value with the set value. The function generator 10 can then be equipped with a thyristor circuit making it possible to produce the pulsation of the voltage of the X-ray tube.

Claims (3)

1) X-ray generator for a diagnostic device comprising a dose rate adjustment circuit, which has, as adjustment element, at least one resistor which can be electronically controlled in the high voltage circuit of the X-ray tube and at which is sent a control signal which is delivered by the dose rate control device compoftan a.entering of the set value and an input. of the actual value, characterized in that the adjustment device (5) includes a function generator (-, 0 for controlling the undulation of the voltage of the X-ray tube. 2) X-ray generator according to claim 1, characterized in that the function generator (1CJ is connected to the resistor (2,3) which can be electrically controlled. 3) X-ray generator according to one of claims 1 or 2, characterized in that there are provided means (11) for connecting the function generator (10) and influencing the ripple as a function of the difference between the setpoint and the actual value of the dose rate.