DE2924682A1 - Supply circuit for X=ray tube - has feedback from HV output of multiplier cascade to control amplitude or oscillator at input of cascade - Google Patents

Abstract

The supply circuit has an oscillator whose output is amplified and applied to the primary of a transformer whose secondary is coupled to a high voltage cascade comprising a ladder of diodes and capacitors. Teh output of the high voltage cascade is connected to the X-ray tube's anode. The h.v. output of the cascade is connected to a resistive voltage divider whose tapping voltage is compared in a differential amplifier with a reference to produce an error signal that controls the amplitude of the oscillator's oscillations. The X-ray tube's grid has its own control circuit.

Description

Food arrangement The invention relates to a food arrangement genäß the preamble of claim 1.

X-ray tubes are thermionic emission devices and sensitive to the heating temperature (filament temperature) and that of the tube applied high voltage. Therefore, most dental systems contain x-ray systems now some sort of feedback circuit to both the high voltage as well as regulating the heating current. A common way to apply a high voltage is to apply a line voltage to a transformer with a large turns ratio to apply the output of a voltage in the EV range directly to the anode and cathode who puts on X-ray tubes. Because of the high turns ratio that goes through a direct voltage conversion is required, are the high-voltage converters used up to now very big and massive. Often there is in the transformer a high one Flux loss (leakage flux) resulting in a low coupling coefficient and a corresponding reduction in the efficiency of the transformer results. There the secondary coil requires many turns, the result is a high internal resistance. Because of this high resistance and also because of the possible change in budget or flow loss, the voltage across the tube is not constant, but changes according to the tube current and according to the mains voltage. The pipe stream is however extremely sensitive or dependent on the heating temperature, and therefore are exact facilities for regulating the heating current required, which facilities to preheat the filament before the high voltage is applied.

The invention is therefore based on the object of providing a feed arrangement, in particular for triode X-ray tubes to create, which compared to the known feed arrangements for TriodA X-ray tubes is improved.

According to the invention, this object is achieved by the subject matter of the patent claim 1 solved. Further embodiments of the invention emerge from the subclaims.

The invention provides an improved feed arrangement over the previously existing, used circuits, with the aim of reducing the Transformer size, cost and weight. The dining arrangement creates an initially constant high voltage; the feed arrangement according to the invention is also less sensitive to the tube current.

In the case of the feed arrangement according to the invention, an oscillator generates a Signal that is amplified and controls a high-voltage transformer. the The transformed voltage is generated by a voltage multiplier, which is connected in series has switched capacities, further elevated. The transformed Voltage is rectified and stored across each capacitance, and the total voltage is greater than the transformed voltage. The Nilltiplier lies over the anode and cathode of a triode X-ray tube and generates a current when the grid is pulsed. The voltage on the tube can be sampled and the amplitude of the oscillator signal can be adjusted to maintain a constant high voltage to obtain.

The number of grating pulses can be counted as an additional feature to turn off the X-ray tube when it reaches a predetermined level is.

The invention provides a feed arrangement for generating a high voltage for an X-ray tube with grid control. A Oscillator is a high-frequency signal that is amplified and converted into a voltage in the KV area is converted. A voltage multiplier increases this high voltage a potential suitable for the tube. The voltage multiplier contains a Series of capacitors connected in series that tend to have a Maintain constant high voltage when the tube is not energized (conductive) is.

The invention relates generally to x-ray assemblies and more particularly relates to a high voltage supply arrangement for x-ray tubes with grid control.

The following is a preferred embodiment of the invention Feed arrangement to explain further features described with reference to the drawing. Show it: Fig. 1 is a schematic view of an embodiment the supply arrangement, Fig. 2 in the circuit of FIG. 1 occurring voltages and currents, and FIG. 3 shows details of parts of the circuit of FIG.

1 illustrates an overall view of a preferred embodiment a feed arrangement according to the invention.

A triode radiator 1 has a heating cathode 2 Grid 3 and an anode 4. The cathode 2 is by a supply source 5 for heated to a low voltage.

When a high voltage is applied between the cathode 2 and the anode 4 electrons are emitted by the hot cathode and hit the node, which emits X-rays. The high voltage is in the kilovolt range and amounts to in this example about 65 KV (direct voltage).

The glow voltage can be 4 volts DC. It is one known property of tubes with grid control that the high voltage is continuous between the cathode 2 and the anode 4 can be maintained when the grid 3, which is inserted between the cathode and the anode, the electron flow with a grid potential of around - 200 volts (DC voltage) stops.

In a preferred embodiment, an oscillator 6 generates a Signal with a frequency that is a multiple of the mains frequency. Preferably the oscillator frequency is between 15 and 20 KHz compared to the typical mains frequency of 50 or 60 Hz.

The output signal of the oscillator 6 is amplified by linear amplifiers, preferably by a driver or. Control unit 7 and output stages 8, 9. The amplified signal is sent to the primary winding of the high voltage transformer 10 applied and transformed into a high voltage.

In the preferred embodiment, the transformed voltage then applied to the voltage multiplier 11.

The voltage multiplier 11 sets the transformed voltage into a higher, rectified and positive voltage and applies it to the anode 4 of the X-ray tube 1 on. The IvIultiplier 11 contains a number of series capacities 12, 13, 14, 15, 16, as shown in Fig. 1, i.e. a so-called capacitor block from series capacitors, which stores the high voltage until the tube is switched on will. The tension multiplier is explained in detail below.

According to the invention, the tube 1 is controlled by a grid control circuit 17 pulsed, which periodically applies a negative grid voltage over time periods and removes causing current pulses to flow through the tube during the switch-off time, as can be seen from FIG. The current pulse is present for a short period of time (tl - t2) and lasts, for example, 150 Ificroseconds, so that the capacitors 12 to 16 are only partially discharged, which increases the voltage on the tube by a value A V reduced. A sufficient switch-off time (t2 to t3) is provided between the pulses approved so that the capacitors recharge.

It was found that a switch-off bw. Locking time of 750X1see for these pulses are sufficient to recharge the capacitors. This means at In the present example, that a 900 microsecond cycle (tl to t3) is present.

In addition to the voltage change Q V that occurs due to the discharge of the capacitors occurs, a high voltage change that lasts for a long time can occur occur as a result of changes in the mains voltage. To this line voltage change To compensate, an additional circuit can be used be provided. From Fig. 1 it can be seen that a voltage divider 18 the voltage at the output of the voltage multiplier 11 scans. The sampled voltage is fed to a differential amplifier 19, in which it is compared with a reference voltage 20. An error signal will be generated by an amplifier, which indicates whether the voltage occurring at the voltage multiplier Voltage is too high or too low. According to the invention, this error signal is the Frequency oscillator 6 is supplied and used to determine the size or Junplitude of the output signal to control, thereby forming a feedback circuit so that the high voltage is kept constant regardless of network fluctuations.

The use of a capacitor block made up of several capacitors 12 through 16 in voltage multiplier 11 leads to the final result of an initial high voltage that is independent of the tube current or the heating temperature.

The discharge rate for capacitors 12 to 16 is, however a function of the @@@ renstromes. It is for the purpose of controlling the tube current still desirable to provide a regulated source of heating voltage and a preheat period for the filament to reach the temperature before the tube "conducts". In addition, the high voltage that occurs across the X-ray tube becomes more constant and be more independent of the filament temperature than is the case with many known circuits the case is.

The invention also relates to X-ray dosing, the a function of the high voltage (KV) across the tube and the tube current over time integrated, is. A milliampere-second integrator 21 may be provided which switches off the circuit when the current-time integral reaches a certain value. Some current integrating circuits are already known and for example in U.S. Patents 4,039,811 and 3,284,631.

As an additional feature of the invention, the number the grid pulses can be counted by a pulse counter. Since the high voltage (in EV range) is reasonably constant and the filament, i.e. the heating temperature, is subject to regulation, the tube current will be almost constant. When the grid pulses have a uniform duration, the product of tube current and time can simply go through Counting the pulses can be determined. When the number of pulses is a predetermined Amount can be reached by means of the grid or by removing the high voltage be switched off.

In a preferred embodiment, the cathode is close by the ground potential. Therefore, as an advantage of the invention, the tube current only through Insertion of an analog ammeter measured between cathode and ground. The aripremeter provides an indication of the average tube current. Because the tube is pulsed the average current only has to be multiplied by a constant, to give the tube peak current used to set up the circuit can be.

Fig. 3 shows in detail some components of the circuit.

Typical values of the components are only given as an example.

The oscillator 6 contains a functional amplifier with an RC feedback circuit for generating oscillations.

An output signal of the oscillator 6 has a frequency between 15 up to 20 KHz, which is fed to a driver 7 (control unit), which first drives the The signal is amplified and then fed to a phase-dividing transformer 24.

The transformer 24 generates two signals with opposite faces, which are then fed to two Gegenentkt power amplifiers 8.9, which the signals amplify to a sufficient power to the primary winding of the high voltage transformer 10 to be driven with 160 volts peak to peak.

The secondary, transformed peak-to-peak voltage applied to the Secondary winding occurs, is about 13 KV and is the voltage multiplier 11 fed.

The following are details of a high voltage transformer described, which is suitable for carrying out the food arrangement according to the invention. The high-voltage transformer consists of a primary winding with 80 turns, made of 22 measuring wire, which is wound onto a core made of material with high permeability is. A secondary coil is wound on the primary winding, with the 20 layers 160 turns each made of 40 measuring wire. The turns ratio is concerned 80: 1 @ compared to 400: 1 for a conventional transformer. The primary winding may have a center tap that derives a B + voltage to the push-pull power amplifiers 8, 9 allows.

The core of the transformer should be a high flux material, for example Stackpole 305. The geometry of the core represents a rectangle made up of three 2 - itself, i.e. 0.98 cm outer dimensions, each consisting of 5/8 inch, i.e. 0.25 cm square arms are formed.

In the embodiment shown, an advantage according to the invention is that the transformer size, weight and cost are smaller with this construction are.

In the following, reference is made to FIG. 1, in order to show the voltage multiplier 11, which consists of a multitude of stages. Every level of the multiplier consists of two capacitors and two diodes arranged according to the drawing are. Ceramic capacitors with 1200 pF were used, which have a working voltage of 20 KV.

The first stage includes capacitors 12 and 26 and diodes 31 and 32. The capacitor 26 and the diode 31 shape the secondary voltage into a positive one Value over wet order, that through the diode 32 and the capacitor 12-is rectified into a DC voltage. This procedure is supported by the the following stages repeated. Five levels can be used to produce an output of about 65 KV.

The components of the four remaining stages are made up of the capacitors 13 to 16, the diodes 33 to 40 and the capacitors 27 to 30 are formed. The potential of 65 KV becomes through the capacitor block of series capacitors 12 to 16 bis to "conduct" the tube 1, which causes the capacitors to partially discharge.

Some additional advantages are provided by the illustrated feed arrangement achieved compared to the previously known circuits. For example, the efficiency the circuit is much larger, with only 195 watts as opposed to 1200 watts at a known circuit are required. Also, unlike well-known Units no instantaneous energy withdrawal from the network observed, which is known occurs when a voltage is held in a capacitor block so that in the present invention, there is less network oscillation. With other, well-known Units were observed impulse currents up to 1000 amps in the network when the high voltage has been switched on. Furthermore, since the oscillator operates at a relatively high frequency and the grid control pulse is also relatively quick compared to a 50 to 60 Hertz system, the error signal can respond quickly, reducing the output sho chsp annnE can be controlled much more precisely than with a 50 or 60 Hertz system was previously possible.

The arrangement according to the invention thus fully meets the objectives and the advantages noted above. Obviously, several Modifications and changes are made, even if this is not the case above is specified.

L e r s e i t e

Claims (3)

Claims 1. Feed arrangement, in particular for feeding a Triode X-ray tube with a high voltage, whereby the X-ray tube has a cathode, has a grid and an anode, that an oscillator (6) for generating an electrical output signal, at least an amplifier connected to the oscillator to amplify its output signal (7,8,9) are provided that a transformer (10) is connected to the amplifier (7,8,9) and a transformed voltage which is higher than the voltage of the amplified output signal Voltage supplies that a voltage multiplier (11) is connected to the transformer (10) and a capacitor block of series-connected capacitors (12 to 16, 26 to 30) for the X-ray tube contains that the voltage multiplier is arranged in such a way is that it rectifies the transformed voltage and the rectified voltage at j each of the series capacitors stores, reducing the total voltage on the capacitors a multiple of the transformed clamping ring that the Capacitor block in electrical connection with the anode (4) and cathode (') of the X-ray tube is standing, and that a pulse device (17) is arranged to distance to apply mutually respectful electrical impulses to the tubular grid (3), so that the x-ray tube conducts for a first period of time while it conducts during a second period of time is switched off, wherein the capacitor block during the partially discharged during the first time period and again during the second time period is loaded. 2. Feed arrangement according to claim 1, characterized in that one Device (18) for sampling the high voltage on the X-ray tube for comparison the sampled voltage with a reference voltage and for outputting one of the Deviations of the sampled voltage relative to the reference voltage are dependent Error signal is provided and that a device (19) for minstellung the level of support of the oscillator output is arranged so that a constant Rochspannungspotential on the X-ray tube is maintained. 3. Feed arrangement according to claim 1 or 2, characterized in that that a counter for counting the number of pulses on the grid and for switching off of the tube when a certain value is reached by the number of pulses is