RU2008760C1 - Small-size x-ray generator - Google Patents

Abstract

FIELD: X-ray equipment. SUBSTANCE: enhanced efficiency of X-ray generator is achieved due to provision for advanced tuning of trajectory of electron beam in X-ray tube. This is obtained as a result of complication in design of at least one shielding ring and use of two controlled voltage dividers and two proper control units. EFFECT: enhanced efficiency. 4 dwg

Description

 The invention relates to x-ray technology and can be used in the development and manufacture of small x-ray generators.

 Known x-ray generator containing a housing in which are located a three-electrode x-ray tube and a sectional diode-capacitor voltage multiplier, made according to the Cockcroft-Walton circuit; the multiplier is installed coaxially with the x-ray tube and is made in the form of two diametrically located increasing and leveling columns, each section of which has one voltage doubling point. A disadvantage of the known generator is low operational reliability and low efficiency [1].

 Closest to the proposed technical solution is a small x-ray generator containing a housing in which there is a three-electrode x-ray tube and a sectional diode-capacitor voltage multiplier, made according to the Cockcroft-Walton circuit, while the diode-capacitor multiplier is installed coaxially with the x-ray tube and is made in the form two diametrically located raising columns and leveling columns, each section of which has one voltage doubling point, as well as medium screening Twa, made in the form of metal rings mounted coaxially X-ray tube, wherein each ring is electrically connected to the voltage doubler point situated opposite to it a voltage multiplier section [2].

 The prototype generator is small-sized, involves the use of a three-electrode x-ray tube and provides the ability to work with anode voltages up to 100 kV. The disadvantage of the prototype generator is the relatively low efficiency; the latter is due to the fact that when assembling and tuning the generator, it is not possible to accurately project the electron beam in the x-ray tube onto the anode target. As a result, the dose rate level at the generator output decreases and distortions of its output radiation pattern occur.

 The aim of the invention is to increase the efficiency of the x-ray generator by expanding its functionality by providing the possibility of preliminary adjustment of the path of the electron beam in the x-ray tube.

The purpose of the known small-sized x-ray generator containing a housing in which are located a three-electrode x-ray tube and a sectional diode-capacitor voltage multiplier, made according to the Cockcroft-Walton scheme, while the diode-capacitor multiplier is mounted coaxially with the x-ray tube and is made in the form of two diametrically located increasing columns and leveling columns, each section of which has one voltage doubling point, as well as shielding made in the form of metal rings installed coaxially to the x-ray tube, wherein each ring is electrically connected to the voltage doubling point of the opposite section of the voltage multiplier, due to the fact that at least one, for example, nth, metal ring of the shielding means is provided with first and second sector metal elements, the voltage multiplier is additionally equipped with a first and second controlled voltage dividers, each having one controlled element and one midpoint, and the first and and the second control means, wherein the first and second metallic elements n-th ring formed electrically isolated from each other and from the ring and are spaced apart by an angle ^90, the first terminals of a voltage divider electrically connected to the point of the voltage doubler n-1-th section a voltage multiplier, the second terminals of the voltage dividers are electrically connected to the voltage doubling point of the n + 1st section of the voltage multiplier, the middle point of the first voltage divider is electrically connected to the first element of the nth metal ring, the midpoint of the second voltage divider is electrically connected to the second element of the nth metal ring, the first controls are contactlessly connected to the controlled element of the first voltage divider, and the second controls are contactlessly connected to the controlled element of the second voltage divider.

 In FIG. 1 shows a simplified design of a small generator; in FIG. 2 shows a diagram of sections of a voltage multiplier electrically connected to a metal shielding ring and its elements; in FIG. 3 schematically shows the placement of divider components and controls in sections of a voltage multiplier; in FIG. 4 illustrates the principle of controlling the path of an electron beam in an x-ray tube.

 The X-ray generator is assembled in a metal case 1. Coaxially with a three-electrode tube 2 installed inside the case 1 and having three electrodes (anode, cathode, grid and glow), there is a sectional diode-capacitor voltage multiplier 3, made according to the Cockcroft-Walton circuit in frame 4 and consisting of increasing 5 and leveling 6 columns located diametrically opposite to each other with respect to the axis of the tube 2. Columns 5, 6 of the multiplier 3 consist of a series of sections 7 arranged sequentially one after another along the x-rays tube 2, which provides a uniform increase in potential in the direction from the cathode to the anode of tube 2 [2].

 The electrical circuit of sections 7 (n-1st, nth and n + 1st sections) of the voltage multiplier 3 is shown in FIG. 2. Each section 7 contains at least two capacitors 8, 9 (C1, C2) and two diodes 10, 11 (D1, D2) connected according to the Cockford-Walton circuit and providing a doubling of the potential of each section 7, with each section corresponding to one point of voltage doubling, at which potential doubling is achieved with respect to the potential of a similar point in the previous section.

 The voltage multiplier 3 also includes a first controlled voltage divider 12, consisting of a series-connected first resistor 13 (R1), a controlled element 15, a second resistor 14 (R 2). In this case, the first output of the divider 12 (output of the resistor R1) is electrically connected with the voltage doubling point of the n-1st section 7, and the second output of the divider 12 (the output of resistor R 2) is electrically connected with the voltage doubling point of the n-1st section 7. In addition, the voltage multiplier 3 includes a second controllable voltage divider 16 comprising serially connected a third resistor 17 (R 3), a controllable element 19, and a fourth resistor 18 (R 4). In this case, the first output of the divider 16 (the output of the resistor R 4) is electrically connected to the voltage doubling point of the n-1st section 7, and the second output of the divider 16 (the output of the resistor R 3) is electrically connected to the voltage doubling point of the n + 1st section 7 .

 The voltage multiplier 3 contains the first control means 20, contactlessly connected to the controlled element 15 of the divider 12, and the second control means 21, contactlessly connected to the controlled element 19 of the divider 16. As the controlled elements 15, 19, photodetectors with a variable resistance value can be used (for example, phototransistors or photoresistors), and light emitting devices (for example, incandescent bulbs or LEDs with a variable luminous intensity) can be used as control means 20, 21. The controls and the controlled element can be combined within a single device - a power optocoupler, which does not lead to going beyond the scope of the invention. Resistors R1, R3 can have the same ratings, less than the ratings of resistors R2, R4, which ensures the implementation of the required voltage adjustment range at the outputs of the dividers 12, 16. As the outputs of the dividers are used their midpoints; for the divider 12, this is the point between the element 15 and the resistor 14, for the divider 16 the point between the element 19 and the resistor 18.

 Dividers 12, 16 and control means 20, 21 are structurally located in sections 17 of the voltage multiplier 3 (in this example, in the n-th and n + 1-th sections, see Fig. 3). In this case, the control means 20, 21 and the corresponding elements 15, 19 should be located in the section opposite each other, and between them a free channel should be provided (for example, when casting) for contactless interaction (for example, optical interaction). In addition, control means 20, 21 should be placed as far as possible from the remaining elements of section 7 in order to avoid electrical breakdown. The conclusions of the control means 20, 21 are output by means of wire connections to the surface of the voltage multiplier 3 in the cathode region of the tube 2, which allows easy access to the control means during the setup process.

Between the x-ray tube 2 and each section 7 of the voltage multiplier 3, a cylindrical metal ring 22 is installed, electrically connected to the voltage doubling point of this section 7. The combination of metal rings 22 forms a means of shielding the x-ray tube 2. In the proposed x-ray generator, at least one metal ring 22 ( for example, n-e) is complex (see Fig. 2) and additionally includes the first and second sector metal elements: the first is 23 and the second is 24. These elements are electrically insulated The axes of the elements 23, 22 are spaced apart by an angle of 90 ^° , and the corresponding sector angles are about 60 ^° (see Fig. 2). The first element 23 of the ring 22 is electrically connected to the midpoint of the first voltage divider 12 of the voltage multiplier 3. The high voltage resulting from the conversion of the transformer’s alternating voltage by the multiplier 3 is supplied from the output of the last section 7 of the multiplier 3 to the anode of the X-ray tube 2, as a result of which a high-voltage (about 80-100 kV) potential difference is formed between the anode and the cathode (glow) of the tube 2 .

 The glow tube 2 is supplied with a low-voltage power source external to the generator (not shown in FIG. 1). When applying to the control electrode of the tube 2 (to the grid) the triggering voltage pulses (under the conditions of the anode and filament voltages), the X-ray generator should generate X-ray pulses with a directivity pattern of a symmetrical nature at the output.

 The magnitude of the amplitude of these pulses (that is, in fact, the magnitude of the efficiency of the generator) and the type of radiation pattern are significantly affected by the nature of the electron beam irradiation of the target of the anode of the x-ray tube 2. In practice, the focused electron beam in the x-ray tube sometimes does not completely irradiate the anode target , which causes a decrease in the amplitude of the output x-ray pulses and distortion of the shape of the radiation pattern at the output of the x-ray generator. Such displacements of the electron beam relative to the target may be intrinsic to the x-ray tube 2 or may arise during operation due to aging of the target (such defects are not always detected during the output inspection of the tube at the manufacturer and may lead to the need for quick replacement of the tubes in operation).

 To eliminate these drawbacks, the proposed generator uses two (at least) control electrodes (two segmented metal elements 23, 24 of the ring 22). By supplying the indicated electrodes with control voltages slightly different from the potential of the ring 22 itself (differences can be up to Δ U = 1 kV), it is possible to control the path of the electron beam in the tube 2.

 Ring 22 is used solely for the purpose of shielding an x-ray tube from the influence of external electrostatic fields.

So, when a voltage U _{n is} applied to the ring 22, a voltage U _n ± Δ U can be applied to the control element (for example, element 23). This voltage is generated at the output of the first controlled voltage divider as a result of applying the corresponding action to its controlled element 15. Control action , as a rule, is formed by a circuit external to the generator and transmitted through the first control means 20. The use of the aforementioned means (control electrode, voltage divider and control means) allows controlling the path of the electron beam (within the necessary limits) in one plane of the tube 2. Accordingly, the use of a second control electrode (element 24 of ring 22), a second voltage divider, and second control means 21 allows you to correct the path of the electron beam in another plane of the tube 2 (orthogonal to the first plane). The possibility of correcting the path of the electron beam in two coordinates allows you to accurately project the focused electron beam onto the target of the anode and on this basis significantly (by 30-50%) increase the amplitude of the output pulses of the generator (and, consequently, the value of the efficiency of this generator), as well as bring the shape of the output radiation pattern to the symmetric. External control actions supplied to the means 20, 21 can be formed either manually (for example, using adjustable direct current sources during the initial setup of the generator in the conditions of its manufacture) or automatically (for example, during operation of the generator using appropriate radiation detectors that monitor the output signal of the generator, and the conversion circuit and the formation of the control action). These control circuits, with the exception of controls 20, 21, are external to the proposed generator and are outside the scope of the invention.

 Thus, in the proposed small-sized x-ray generator, while maintaining the dimensions unchanged due to the expansion of its functionality associated with the use of means for correcting the path of the electron beam in the x-ray tube, the efficiency of the generator and its output radiation pattern are improved. The latter also greatly facilitates the setup of the generator during its manufacture and operation and the life of the X-ray tubes. (56) Copyright certificate of the USSR N 599738, cl. H 05 G 1/02, 1978.

 USSR author's certificate N 1526555, cl. H 05 G 1/02, 1988.

Claims (1)

A SMALL X-RAY GENERATOR comprising a housing in which an X-ray tube and a sectional diode-capacitor voltage multiplier are arranged according to the Cockcroft-Walton circuit, while the diode-capacitor multiplier is installed coaxially with the X-ray tube and is made in the form of two diametrically arranged increasing and equalizing columns each section of which has one voltage doubling point, as well as shielding means made in the form of metal rings mounted coaxially X-ray tube, wherein each ring is electrically connected to the voltage doubling point of the opposite section of the voltage multiplier, characterized in that at least one, nth, metal ring is provided with first and second sector metal elements, the voltage multiplier is additionally provided with first and second controlled voltage dividers, each having one controlled element and one midpoint, and the first and second controls, the first and second sector metallic s n-th elements of the metal rings are made electrically insulated from each other and from the rings and spaced at an angle of 90 ^o, the first terminal of the driving voltage divider electrically connected to the voltage doubling point (n - 1) th voltage multiplier section, the second terminals of controllable divider the voltage is electrically connected to the voltage doubling point of the (n + 1) th section of the voltage multiplier, the midpoint of the first controlled voltage divider is electrically connected to the first sector metal element of the nth metal eskogo ring midpoint second controlled voltage divider electrically connected to a second metal member by the sector n-th metal ring, first and second control means contactlessly connected to the control element, respectively the first and second voltage divider.

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