SU745030A1 - X-ray generator - Google Patents

Description

(54) X-RAY GENERATOR

The invention relates to X-ray technology, and more specifically to X-ray generators, comprising two X-ray tubes with grounded anodes and is used, for example, in fluorescent separators. An x-ray generator is known, containing two x-ray tubes with grounded anodes, incandescent transformers, anodic current stabilizers for each of the tubes, " means for obtaining voltages, rijponational currents of each of the 1J tubes. The disadvantage of the known generator is that a voltage signal is used for stabilization, which makes it impossible to use standard "stabilizers" (nodo current. The closest technical solution is an x-ray generator containing two x-ray tubes with grounded anodes, a high voltage source. heat transfer transformers, anodic current stabilizers, means for dividing the total anodic current into two current-slugables, included in the earthing circuit of the anodes of the X-ray tubes and Filled in the form of two parallel circuits, each of which contains an electrical resistive control and an anodic current stabilizer sensor, means for obtaining control of voltage voltages connected to control electrodes of electrically controlled resistances and including non-linear functional transducers connected to heat transformers 2. In the specified generator, control signals are obtained by subtracting from a voltage proportional to the total anode current, voltages proportional to inversely transformed voltage {r1I m (currents) of the heat of each of the tubes. This leads to complication of the scheme, the presence of cross-links between the stabilization schemes of each of the tubes and, of course, 1 1 result in a decrease in the accuracy of stabilization. The purpose of the invention is to improve the accuracy of stabilization. According to the invention, the goal is achieved in that an x-ray reriepaifbpe comprising two x-ray tubes with grounded anodes, a high voltage source, incandescent transformers, anodic current stabilizers, means of dividing the total anodic current into current-component cores / included in the x-ray anode ground circuit kih tubes and made in the form. two parallel circuits, each of which contains an electrically controlled resistance and an anode current stabilizer sensor, means for obtaining control voltages connected to control electrodes of electrically controlled resistances and incorporating nonlinear functional converters connected to transformers in means of obtaining control voltages; voltage circuits are derived; voltage comparison circuits are connected to each of which is connected to the sensor of the anode current stabilizer of one of the tubes and the output of the nonlinear f An actuator connected to the same tube transformer, and the control electrodes are electrically controlled resistances are connected to the outputs of the respective comparison circuits. SUMMARY OF THE INVENTION FIG. The X-ray generator contains X-ray tubes 1, 2, zero-core 3, sensors 4, 5 of anodic current stabilizers 6, 7, electrically controlled resistances 8, 9, X-ray transformers 10, 11 of X-ray tubes 1, 2 are connected to nonlinear functional converters The sensors 12, 13. Sensors 4, 5 and converters 12, 13 are connected to comparison circuits 14, 15. The outputs of Comparison 14, 15 circuits are connected to resistors 16-19, from which the signal is fed to control electrodes electrically controlled 8, 9. Stabilizers b, 7 welded. Wives setters 20, 21 to set the required values of the anode currents. The generator works as follows. -. . . The anode currents flowing through the X-ray tubes 1 and 2 are located at the ground point of the Tpy6oK anodes, v after which the total anadic current is split in the zero corrector 3 and the two current flows around the sensor Anode current 6 and 7, and also electrically controlled resistances 8 and 9. Information about anode currents in a tube is obtained by measuring the voltages on the primary windings of the heat transformers 10 and 11 of each tube and function tube. non-linear conversion of these voltages in blocks 12 and 13 into proportional anode currents of corresponding windings of tubes 1 and 2. In general, voltages taken at the output of blocks 12 and 13 can be used as adjustable parameters (indirect) , supplied directly to the input of the anode current stabilizers CAT-1 and CAT-2 (6 and 7). At the same time, stabilizers 6 and 7 will stabilize the anode currents each in its tube, respectively, 1 and 2. But the accuracy of such stabilization will be small, since changes in the parameters of elements included in blocks 12 and 13, which inevitably happen for random reasons and in as a result, aging will be uncontrollable and may go unnoticed. As a result, there may be a significant discrepancy between the readings of the device intended to determine the anode current and the actual value of the anode current in the tube. The presence of two parallel-connected circuits, each of which contains a series-connected anode current stabilizer sensor, a measuring instrument and an electrically controlled resistance, makes it possible to judge the true value of the sum of the anode currents of both tubes by the sum of the readings of the measuring instruments. for accurate distribution of currents between parallel-connected voltage circuits taken from sensors 4 and 5, and voltages from the outputs of blocks 12 and 13 are compared in pairs with each other (4 with 12 and 5 with 13), in comparison circuits 14, 15 The mismatch voltages across the resistors 16, 17, and 18, 1 are applied to the control electrodes of the electrically controlled resistances 8.9. When changing the set point: setpoint adjuster 20 (21) of the anode current stabilizer b (7), the latter will change the voltage value on the primary winding of the glow transformer, which will cause a change in the anode current in this tube. But at the same time, the magnitude of the sum of the anode currents of both tubes changes. There will be a mismatch between the voltages on the sensors 4 and 5 and the output of blocks 12 and 13. As a result of these disagreements; The value of electrically controlled additional resistance 8 (9) will increase, and the value of resistance 9 (8) will decrease, due to which current in parallel circuits will be redistributed in exact correspondence with the new setting value of setpoint 20 (21) in the anode current stabilizer 6 (7) . . - The invention provides a more accurate current separation, in the scheme of separate stabilization of iodine currents in two tubes with grounded anodes.

Claims (1)

Claim An x-ray generator containing two x-ray tubes with grounded anodes, a high voltage source, glow transformers, anode current stabilizers, means for dividing the total anode current into two current components, included in the ground circuit of the anodes of the x-ray tubes and made in the form of two parallel circuits, each of which contains an electrically controlled resistance and anode current stabilizer sensor, means for obtaining control voltages connected to control electrodes and controllable resistivity and including nonlinear characterized in that, in order to increase the accuracy stavili-; In order to obtain control voltages, voltage comparison circuits are introduced, each of which has a key, anode current stabilizer sensor of one of the tubes and the output of a nonlinear functional converter connected to the glow transformer of the same tube, and electrically controlled resistances are connected to the leveling electrodes outputs of the respective comparison circuits.