RU2593379C2 - X-ray feeding device - Google Patents

Abstract

FIELD: instrumentation; physics.

SUBSTANCE: x-ray feeding device comprises a module for converting network AC voltage into DC high voltage, in which a low-power supply source has a voltage of ten…thirty kV and power from one half kV to ten kV by means of a switch “Charging”-“Exposure” which is connected to capacitors in parallel when the switch is in “Charging” position, and when it is in “Exposure” position the capacitors are connected in series and are connected to input terminals of the panel for automatic high-voltage control of voltage and the current of anode of the x-ray tube. Switch is made in the form of a glass of an insulating material, filled with insulating liquid; on opposite walls of the glass there are capacitors' terminals, input terminals of the switch are connected to output terminals of the low-power supply source for ten…thirty kV according to the polarity of voltages, and output terminals of the switch are connected to terminals of high-voltage circuit for control of voltage and current of anode of the x-ray tube in the corresponding polarity. Rotor of the switch is installed along the glass axis and is equipped with two pairs of parallel buses connected to capacitor terminals in “Charging” position; in “Exposure” position - by jumpers with output terminals of the switch, earthed by a bridge connecting the right and left capacitor panels and by skewed jumpers connecting, in series, capacitor terminals into a series circuit, and, by output terminals, connected to input terminals of the high-voltage circuit for control of voltage and current of anode of the x-ray tube.

EFFECT: disclosed is an x-ray feed unit.

1 cl, 6 dwg

Description

 The invention relates to x-ray technology and can be used to create energy-efficient x-ray machines that do not require large power supply from the network when receiving images.

A known method of supplying x-ray tubes, including adjusting a predetermined voltage on an autotransformer, supplying a predetermined low-voltage voltage to a high-voltage transformer, rectifying a high voltage on a high-voltage six-phase or twelve-phase rectifier, supplying a rectified predetermined voltage to an x-ray tube, adjusting the current on the x-ray tube by changing the cathode voltage Blinov N.N., Leonov B.I., X-ray diagnostic devices. T. 1, Moscow 2001, 220 p., Pp. 46 ... 51, fig. 2.1., P. 47].

The main disadvantages of this method of operation of the power supply device are the large overall dimensions of the power supply device and the high consumption of installation power (forty ... one hundred kilowatts) from the network during exposure.

A known method of operation of an X-ray power device, including: transformerless rectification of a three-phase voltage with a six-phase rectifier (Larionov circuit), converting direct voltage to high-frequency alternating current (10 ... 100 kHz), regulating voltage to specified values by pulse-width modulation of high-frequency low-voltage pulses, increasing voltage on the high-frequency transformer, rectification of the high-frequency voltage and its supply to the x-ray tube, regulation of the current tr damages by changing the voltage of the cathode [Blinov NN, Leonov B.I. X-ray diagnostic devices. T. 1, Moscow 2001, 220 p., Pp. 46 ... 51, fig. 2.1, p. 47].

The advantage of this method of operation of the power supply device is the reduction of overall dimensions due to the use of a high-frequency inverter and a high-frequency high-voltage transformer.

The main disadvantage of this method of operation of the power supply device is the same high consumption of installed power (forty ... one hundred kilowatts) from the power supply during exposure.

The prototype of the proposed method is a method of operating a high-voltage power supply device, including: transformerless rectification of a three-phase voltage with a six-phase rectifier (Larionov circuit), converting direct voltage to alternating high frequency (10 ... 100 kHz), stabilizing voltage to specified values by pulse-width modulation of high-frequency pulses of low frequency voltage, increasing voltage on a high-frequency transformer, rectifying high-frequency voltage and supplying it to x-ray my pipe; the X-ray tube is supplied with a falling load, i.e. at start-up, the maximum permissible current and voltage are supplied to the cold cathode, then the current is reduced, which causes an increase in voltage, and therefore the voltage is also reduced. The voltage and current are driven along the border of the permissible power of the x-ray tube [Blinov NN, Leonov B.I. X-ray diagnostic devices. T. 1, Moscow 2001, 220 p., P. 15 ... 24]. The current regulation of the tube is carried out by changing the voltage of the cathode, and the voltage regulation on the tube is carried out on the high-voltage side [Blinov NN, Leonov B.I. X-ray diagnostic devices. T. 1, Moscow 2001, 220 p., Pp. 77 ... 79, Fig. 2.15, p. 79].

The advantages of this method of operation are: automatic exposure and increased accuracy of setting the voltage and exposure time on the tube and the current of the anode.

The main disadvantage of this method of operation is the consumption of large installation capacity (forty ... one hundred kilowatts) from the network when taking a picture.

The technical task of the invention of the method of operation of the x-ray apparatus is to reduce the power consumed from the network during exposure.

The stated technical problem is solved in that the method of operation of the supplying X-ray device includes increasing the network voltage to forty ... two hundred kilovolts, rectifying it, smoothing it and supplying it to a high-voltage control device that controls the voltage and current of the anode on the X-ray tube in accordance with the program, while the capacitor bank charge through the switch "Charging" - "Exposure"; when the switch is in the “Charging” position, the capacitors are connected in parallel with the low-power module by ten ... thirty kilovolts, half a kilowatt power ... ten kilowatts, after charging the capacitors, the switch is put into the “Exposure” position, while the charged capacitors are connected by a switch in series, the voltage from the capacitors connected in series fed to the circuit of high-voltage control of the voltage and current of the anode of the x-ray tube.

A device for supplying an X-ray apparatus is known, comprising: an autotransformer for adjusting the input voltage at a step-up high-voltage main transformer, a high-voltage main transformer, a high-voltage rectifier for supplying an X-ray tube and a cathode glow regulator for regulating the tube current [Blinov N.N., Leonov B.I. X-ray diagnostic devices. T. 1, Moscow 2001, 220 p., Pp. 46 ... 59, fig. 2.6, p. 55].

The main disadvantage of this device is the high consumption of installation power (forty ... one hundred kilowatts) from the supply network during exposure and large overall dimensions.

A device for supplying an X-ray apparatus is known, comprising a transformerless input rectifier, a high-frequency or mid-frequency DC / AC converter (inverter), with feedback on a high-frequency output voltage, for example, with a PWM controller of this high-frequency voltage to set the voltage on the x-ray tube, a high-frequency step-up transformer, a high voltage rectifier connected to the x-ray tube, and anode current regulator of the tube by changing to voltage filament at the cathode of the x-ray tube [Blinov NN, Leonov B.I. X-ray diagnostic devices. T. 1, Moscow 2001, 220 p., Pp. 54 ... 55, fig. 2.6, p. 55].

The advantage of this device is the reduction of overall dimensions due to the use of high-frequency high-voltage transformer.

The main disadvantage of this device is the high consumption of installation power (forty ... one hundred kilowatts) from the mains during exposure.

A prototype of the present invention is a known X-ray tube power supply device containing a three-phase voltageless transformer rectifier with a six-phase rectifier (Larionov circuit), a DC to AC converter of medium frequency (10 ... 20 KHz) on thyristor or high frequency (30 ... 70 KHz) on transistor switches, a high-voltage high-frequency transformer, a high-voltage rectification circuit and a high-voltage electronic control circuit that controls the voltage on X-ray tion tube, its switching and control given by the anode current [Blinov NN Lyavonau BI X-ray diagnostic devices. T. 1, Moscow 2001, 220 p., Pp. 77 ... 79, Fig. 2.15, p. 58]. The advantages of this device are: increased accuracy of setting the voltage on the tube and the current of the anode and a simpler circuit for setting the exposure time.

The main disadvantage of this device is the consumption of large installation power from the network when taking pictures.

An object of the present invention is to simplify the design, reduce the power consumed from the network during exposure, reduce the overall dimensions and complexity of the converter power supply device.

The problem is solved in that the X-ray power device contains a module that converts the AC voltage to direct current of high voltage, in which a low-power power supply with a voltage of ten ... thirty kilovolts and a power of half a kilowatt to ten kilowatts using the switch "Charging" - "Exposure" is connected with capacitors in parallel when the switch is in the "Charging" position, and when the switch is in the "Exposure" position, the capacitors are connected in series and connected s with the input terminals of the circuit the high-voltage control and current anode X-ray tube; the switch is made in the form of a glass of insulating material filled with an insulating liquid; on the opposite walls of the glass, the contact terminals of the capacitors are made, the input terminals of the switch are connected to the output terminals of a low-power power supply by ten ... thirty kilovolts in accordance with the voltage polarity, and the output terminals of the switch are connected to the terminals of the high-voltage circuit for controlling the voltage and current of the anode of the x-ray tube in the corresponding polarity; the rotor of the switch is mounted along the axis of the cup and is equipped with two pairs of parallel buses connected to the capacitor terminals in the “Charging” position; in the Exposure rotor position, jumper wires with switch output terminals, a grounded jumper connecting the right and left capacitor panels, and oblique jumper wires connecting the capacitor terminals in series with each other, and output terminals connected to the input terminals of the high-voltage voltage control circuit and the current of the anode of the x-ray tube.

The invention is illustrated in FIG. 1, 2, 3, 4, 5, 6.

In FIG. 1 is a structural diagram of charging capacitors from a low-power low-voltage module.

In FIG. 2 is a schematic diagram of the “Charging” - “Exposure” switch in the “Charging” rotor position.

In FIG. 3 shows a schematic diagram of the operation of the device in the position of the switch "Exposure".

In FIG. 4 shows a schematic diagram of a switch in the position of the rotor "Exposure".

In FIG. 5 is a schematic diagram of a low-power low-voltage module with voltage multipliers when powered by a three-phase network.

In FIG. 6 is a schematic diagram of a low-power low-voltage module with an input step-up low-frequency transformer and voltage multipliers when powered from a single-phase network 220 volts 50 Hz.

In FIG. 1 shows a diagram of a capacitor bank charge when the switch is in the “Charging” position. Low-voltage (10 ... 30 kV) low-power (0.5 ... 10 kW) module 1 consists of a transformerless rectifier 2 connected to a step-up converter 3 DC to high-frequency voltage, a rectifier high voltage 4 and an output voltage regulator 5, which controls the converter 3. Switch 6 contains two capacitor terminal panels - the negative terminals of the capacitors are connected to the terminals 7, the positive terminals of the capacitors are connected to the terminals 8. The capacitors C1, C2, ..., Cn of the first (left) terminal panel create negative voltage on the tube, capacitors С01, С02, ..., C0m of the second (right) terminal panel create a positive voltage on the x-ray tube relative to the mid-ground point. When the switch is in the “Charging” position, the parallel buses 11 connect the negative capacitor terminals 7 to the input negative terminals 9, and the positive capacitor terminals 8 to the positive input terminals 10. The output terminals of the switch 13 are negative and 14 are positive with the terminals of the charged capacitors and are connected only with the input terminals 15 and 16 of the panel for high-voltage control of the voltage and current of the anode of the x-ray tube, respectively.

In FIG. 2 shows the position of the rotor 17 of the switch 6 "Charging" - "Exposure" in the position of the rotor "Charging". Top view, along the axis of rotation of the rotor 17. Here, on the rotor of the switch 17 are two pairs of parallel buses 11 and 12, which connect the capacitor terminals 7 and 8 to the input terminals 9 and 10, which are constantly connected to the output terminals of the low-voltage low-power module 1. Output terminals 13 and 14 mounted on the switch housing are connected to the positive terminal 15 and the negative terminal 16 of the high voltage panel in accordance with their polarity. On the rotor 17 is installed in the open inoperative position connecting (grounded) jumper 18 and connecting oblique jumpers 20, 21.

In FIG. Figure 3 shows a schematic diagram of the “Charging” - “Exposure” switch in the position of the rotor 17 “Exposure” (rotated 90 ° clockwise). In this position of the rotor of the switch 6, the negative terminal 7 of each capacitor is connected by an oblique jumper to the positive terminal of the previous capacitor 8, the negative terminal of the last capacitor Cn is connected to the output terminal of the switch 13 by the connecting jumper 21. The output terminal 13 is in turn connected to the negative terminal 16 of the high-voltage block circuit control voltage and current of an x-ray tube. The positive terminal of the capacitor C1 is connected by a jumper 18 to ground and the negative terminal of the capacitor C01. The positive terminal of capacitor C01 is connected by an oblique jumper 20 to the negative terminal of capacitor C02, and so on to the capacitor C0m, whose positive terminal is connected by connecting jumper 22 to the output terminal 14 of switch 6, which is connected to the positive terminal 15 of the high-voltage X-ray tube voltage and current control unit. Thus, the voltage removed from the capacitor bank С01 ... C0m is applied to the tube anode, and the voltage taken from the capacitor bank C1 ... Cn is applied to the tube cathode. These voltages on the panel of the high-voltage control voltage of the tube are limited by the regulators to the required values.

The device operates as follows. After charging all the capacitors connected in parallel to the low-voltage module to the required voltage (Fig. 1, 2) by turning the rotor 17 of switch 6 90 ° clockwise, parallel buses 11 and 12 disconnect the input terminals 9 and 10 from the terminals of the capacitors 7 and 8, and connecting (direct and oblique) jumpers 18, 19, 20,21 and 22 connect the capacitors in series. The jumper 18 is connected to ground, and the jumpers 21 and 22 connect the series-connected capacitors to the output terminals 13 and 14, which are connected to the input terminals 15 and 16 of the high-voltage control panel voltage and current of the tube anode.

Current flows through the tube, and the voltage across the capacitors decreases exponentially, so the capacitors must be charged an amount greater than the voltage drop across the capacitors at maximum exposure and at the maximum current of the tube anode. The rate of voltage drop across the capacitors directly depends on the tube current and is inversely proportional to the capacitance of the battery capacitors.

To charge capacitors, a simpler low-voltage (10 ... 30 kV) low-power (0.5 ... 5 kW) module, powered by a three-phase network, built on three-phase diode-capacitor two-half-voltage voltage multipliers: positive and negative (Fig. 5) can be used. The charging of capacitors approaches the amplitude value of the three-phase voltage of 380 V. This, taking into account the losses U _a = 380 * 1.4 = 532 V. With tenfold multiplication, this is about 5300 V. But since the positive and negative multipliers are used, the resulting voltage is twice as large as 10600 B. When using a capacitor bank of 14 capacitors, we obtain a voltage of 10,600 * 14 = 148,000 V. At operating voltages on the diagnostic tube of 40 ... 110 kV.

When using a single-phase voltage of 220 V, a step-up input transformer is used, for example, with a transformation coefficient n = 1.5 ... 3, then the amplitude voltage at the input of the multiplier is U _a = 1.4 * 220 * 3 = 920 V. With a tenfold multiplication of 9200 V. Since it is used two multipliers - positive and negative, then the output of the multipliers, i.e. module 6, there will be a voltage of 18400 V. When using ten capacitors in the battery, we get an output voltage of 184000 V.

Claims (1)

An X-ray power supply device containing a module that converts the mains voltage to direct current of high voltage, in which a low-power power supply with a voltage of ten ... thirty kilovolts and a power of half a kilowatt to ten kilowatts is connected in parallel with the capacitors with the Charge - Exposure switch at the position switch in the "Charging" position, and when the switch is in the "Exposure" position, the capacitors are connected in series and connected to the input terminals of the panel mathic high voltage control and the current x-ray tube anode, characterized in that the switch is configured as a sleeve of insulating material, the insulating liquid filled; on the opposite walls of the glass, the contact terminals of the capacitors are made, the input terminals of the switch are connected to the output terminals of a low-power power supply by ten ... thirty kilovolts in accordance with the voltage polarity, and the output terminals of the switch are connected to the terminals of the high-voltage circuit for controlling the voltage and current of the anode of the x-ray tube in the corresponding polarity; the rotor of the switch is mounted along the axis of the cup and is equipped with two pairs of parallel buses connected to the capacitor terminals in the “Charging” position; in the Exposure rotor position, jumper wires with switch output terminals, a grounded jumper connecting the right and left capacitor panels, and oblique jumper wires connecting the capacitor terminals in series with each other, and output terminals connected to the input terminals of the high-voltage voltage control circuit and the current of the anode of the x-ray tube.

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