SU858216A1 - X-ray apparatus - Google Patents

Description

one

The invention relates to X-ray technology, and more specifically to X-ray machines with means for controlling the current and / or voltage of the X-ray radiator.

A X-ray machine containing a radiator, a high-voltage power supply source with a setting system and a commutation switch, a transformer with a measuring resistor in the primary circuit of a transformer heat generator, a means of controlling the heat, an emitter with a circuit for setting the initial current value of the heater before switching on the anode voltage (the final value of the anode current in the process of ignition of the filament in front of the image), and this circuit contains a pulse shaper, which characterizes a filament current, connected measuring resistor, the pulse shaper characterizing voltage .nakala included in parallel with the primary winding of transformer 25 Matora filament, pulse shapers phase comparing circuit, pulse generating circuit, which characterize the phase shift, an integrator and a threshold device 30 whose output is connected

with switch in. voltages anode voltage.

In this apparatus, the trigger level of the threshold device is determined from the condition that the anode current reaches the desired value and is monitored by the apparatus setting system l.

However, such a device is characterized by insufficient accuracy of the pre-exposure control of the filament current, due to the inability to accurately monitor the temperature of the filament over the phase shift of the pulses characterizing the current and the filament voltage.

Claims (2)

The closest technical solution to the forerunner is an X-ray unit containing an X-ray emitter, a high-voltage power source with a setting system and a switchboard, a transformer with the primary and secondary windings, means for controlling the X-ray emitter, including a measuring resistor inserted into the primary winding of the transformer naxsha, reference voltage source, generating a signal proportional to a given final temperature of the filament of the cathode radiator , the comparison circuit, generated by a signal proportional to the difference between the real and reference signals, and the output of the comparison circuit is connected to the input of the X-ray emitter regulating means, and the reference voltage source I is connected to the device settings system 2,. However, in a known apparatus, information about the real temperature of the cathode filament is obtained as a signal proportional to either the current or voltage in the primary circuit of the transformer, which introduces some uncertainty in the measured value, because the real temperature depends on the initial temperature of the filament, which It is not taken into account in the indicated measurement method. This is of particular importance in devices that are intended for successively conducting a series of exposures, for example, in devices for obtaining Serial images, devices with a falling load, which switch and reduce the current in the process of a single image, which is actually divided into several exposures, and devices for x-ray filming. The purpose of the invention is to improve the accuracy of regulating the heat of the radiator and simplify protection of the radiator against overloads. The goal is achieved by the fact that in an X-ray machine containing an X-ray emitter, a high-voltage power source with a setting system and a switch, a transformer with the primary and secondary windings, means for controlling the X-ray emitter, including a resistor inserted into the primary winding of the transformer, the source of the reference voltage generating a signal proportional to a predetermined final temperature of the filament of the cathode of the radiator, the comparison circuit generating the signal proportional differences between real and reference signals, the output of the comparison circuit is connected to the input of the X-ray emitter control means, and the source of the reference voltage is connected to the system settings of the apparatus, a voltage divider and a unit for tracking the filament temperature are inserted, one The voltage divider input is connected to the primary winding of the transformer and the other is connected to the measuring resistor; one output of the divider is connected to one of the inputs of the comparison circuit, the second output of the divider is connected to the input of the Single tracking the temperature of the filament output of which is connected to the high-voltage power supply switch and the other input - system setting unit. The drawing is a diagram of the proposed x-ray apparatus. The X-ray machine contains emitter 1, a high-voltage power supply 2 with a system of 3 setpoints and a switch 4, a heating transformer 5 with a primary winding 6 and a secondary winding 7 to which the filament 8 of the radiator cat 1 is connected. The glow of the radiator 1 is controlled by means 9, which can be made in the form of an adjusting autotransformer with a control system. The means for controlling the filament 9 controls the signal coming from the comparison circuit 10, the inputs of which are connected to the outputs of the voltage divider 11 and the voltage source 12. One input of the voltage divider 11 is connected in parallel with the primary winding b of the glow transformer 5, and the other input is connected to the measuring resistor 13. The second output of the voltage divider 11 is connected to the temperature tracking unit 14 of the heat filament. The system 3 of the X-ray apparatus settings is connected to the high-voltage power supply 2, the reference voltage source 12 and the filament temperature monitoring unit 14. The invention is based on the fact that there is an unambiguous relationship between temperature and the resistance of the filament of an x-ray emitter, which is linear, which simplifies the law of control. Using the primary winding of the transformer 5 of the heater of the voltage divider 11 connected in this way, its output receives signals proportional to the resistance of the filament 8 of the heat, and hence its temperature, which determines the anode current of the radiator 1. Thus, at the output of circuit 10 Comparison, a signal is generated that is proportional to the difference between the real and desired temperature of the filament 8, characterized by a reference signal, which comes from the reference voltage source 12 and the value specified by the system 3 settings. This control loop allows you to set the required glow before the snapshot and to provide the required anode current at the moment of switching on the high voltage. The second control loop, which includes the filament temperature monitoring unit 14, serves to ensure the correct switching on of the anode voltage in those cases when the device is operating in the sequential mode of several exposures. This mode is performed when taking serial shots or when operating with a switching load with switching during the taking of one snapshot of the anode current and changing its magnitude, which is equivalent to sequential multiple exposures. The tracking unit may have a different design depending on the required X-ray machine control law, in particular, it may contain a reference voltage source similar to source 12, also controlled from the system 3 of settings, and a trigger circuit that controls the processing of switch 4. When Thereby the levels of the reference voltage from source 12 and in block 14 may be identical (the reference level in block 14 at the time of the beginning of one exposure and changes to the level of the anode current setpoint of the next exposure, while the set point is point 12 during the exposure remains at the same level). Since during one exposure, the anode current and the anode voltage are constant, the integrated difference signal of the comparison circuit gives a value proportional to the difference of the radiator thermal load between successive exposures. By setting the required value of this difference and comparing it with the integrated value, a control signal can be obtained; switching off the switch 4. In this case, block 14 contains an additional source of reference voltage, controlled from the thermal protection unit of the radiator (not shown), specifying the change in the thermal load of the radiator during successive exposures. If the same reference signal is generated at the source of the reference voltage of the unit 14 and the source 12, i.e., the comparison circuit of the unit 14 and the comparison circuit 10 produces the same signals. Block 14 b carries out independent monitoring of the anode temperature and control the switch 4 of the source 2 of the high voltage, depending on the 3 set-points of the software control device, usually contained in the system, in order to ensure accurate. fulfilling the conditions of successive exposures and thermal protection of the radiator. At the same time, obtaining a signal similar to the signal from the comparison circuit 10 is necessary for switching the high-voltage source after the anode current has been adjusted by means of the device 9 to set the desired filament temperature. In this case, however, I should note that this function can also be performed using the comparison circuit 10 and the source 12 of the reference signal. With the help of the proposed X-ray apparatus, it is possible to ensure reliable protection of the X-ray tube against anode current overloads. X-ray apparatus containing an X-ray emitter, a high-voltage power source with a setting system and a switch, a heat transformer with primary and secondary windings, means for controlling the heat of the X-ray emitter, including a measuring resistor inserted into the primary winding circuit of the heat transformer, a source of reference voltage, developed by a generator, used in the primary winding of the heat source, the reference source, developed by the generator, used as a measuring resistor, is inserted into the primary winding circuit of the heat transformer, the source of the reference voltage, developed by the X-ray emitter, developed by the measuring resistor, is inserted into the primary winding circuit of the heat transformer, the source of the reference voltage, developed by the X-ray emitter, developed by the measuring resistor, is inserted into the primary winding circuit of the heat transformer, the source of the reference voltage, developed by the X-ray emitter, developed by the measuring resistor, is inserted into the primary winding circuit of the heat transformer, the source of the reference voltage, developed by the X-ray emitter, developed by the measuring resistor inserted into the primary winding circuit of the heat transformer, the source of the reference voltage, worked out a signal proportional to a given final temperature of the filament of the cathode of the emitter, the comparison circuit that generates a signal, The rational difference is between the real and reference signals, the output of the comparison circuit is connected to the input of the X-ray emitter control means, and the reference voltage source is connected to the apparatus setting system, which is designed to improve the accuracy of the emitter heat control and improve it. radiator from overloads, a voltage divider and a filament temperature tracking unit are introduced into the apparatus, with one input of the voltage divider connected to the primary side of the transformer and the other measuring resistor, an output divider connected to one of vhoov comparing circuit, a second output connected to the input divider unit follow the temperature of the filament / vyod which is connected to the high voltage power switch Source and nother input - aparata system settings. Sources of information taken into account in the examination 1. US patent 3,925,672, l. 250-402, publ. 1975. 2.V1.enced for the application for FRG 2229397, cl. 21 g 20/05, published 974 (prototype).