KR20090001119A - Method for pulse driving x-ray generation apparatus - Google Patents

Abstract

A pulse fluoroscopy driving method of an X-ray generator is provided to obtain many X-ray images in a short time by increasing the frequency of the pulse and response speed. An X-ray tube is supplied with tube current to a pulse shape. A cathode tube part and an anode tube part of the X-ray tube are supplied with tube voltage(VRMS,e) of a pulse shape. The tube current higher than the X-ray generation tube current is synchronized to the falling edge of the tube voltage and is supplied for a certain time. In the low level section of the pulse shape, the tube voltage maintains the voltage of 30%-80% comparing to the voltage of the high level section generated the X-rays.

Description

Pulse perspective driving method of an X-ray generator {Method for pulse driving X-ray generation apparatus}

1 is a configuration diagram of a general X-ray generator

2 is a block diagram of a typical X-ray tube

3 is a timing diagram of a continuous perspective system of a general X-ray generator;

Figure 4 is a timing diagram of the pulse perspective method of the conventional X-ray generator

5 is a timing diagram of a pulse perspective method of the X-ray generator according to the present invention;

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an X-ray generating apparatus, and more particularly, to a pulse perspective driving method of an X-ray generating apparatus capable of obtaining more X-ray images in a short time by rapidly turning on / off X-rays.

In general, X-ray generators are increasingly versatile and combined with various IT technologies to capture two-dimensional images many times from different angles rather than to obtain simple two-dimensional images. The trend is to make medical images by creating 3D images.

In other words, in the dentistry, tomography is performed using an X-ray generator and the photographed image is processed to create a three-dimensional (3D) image and applied to treatment.

It is also used to inspect packages at airports such as airports.

Such an X-ray generating apparatus will be described below.

1 is a configuration diagram of a general X-ray generator, Figure 2 is a configuration diagram of the X-ray tube.

As shown in FIG. 1, a general X-ray generator is divided into a main body 10 that outputs various driving signals and voltages and communicates with an external device, and an X-ray tank 20 that generates X-rays.

The main body 10 is supplied with commercial power (AC 100V to 220V) and a power board (Power Board) 11 for supplying driving power to each board, and the user receives the operating power from the power board 11 A control board 12 for outputting various control signals according to the key input signal of the controller and performing communication with an external device, and inputted from the power board 11 according to the control signal of the control board 12. It comprises a drive board (Drive Board) 13 for supplying power to the X-ray tube of the X-ray tank 20.

The X-ray tank 20 has an X-ray tube for generating X-rays to generate X-rays by the power supplied from the main body 10.

The configuration of the X-ray tube is shown in FIG.

As shown in FIG. 2, a general X-ray tube includes a glass tube 21 that is hermetically sealed and maintains a vacuum state, a cathode tube part 22 that is provided in one side of the glass tube 21 in a longitudinal direction, and the glass tube ( 21, an anode tube portion 23 provided in the longitudinal direction on the other side thereof, a filament 24 disposed on the cathode tube portion 22 to emit hot electrons, and between the filament 24 and the anode tube portion 23. And a target 25 made of a metal material such as tungsten for irradiating X-rays generated in an arbitrary direction.

The operation of the X-ray tube configured as described above is as follows.

First, when a current is supplied to the filament 24, heat is generated in the filament 24, and thus free electrons are generated. In addition, when a tube voltage (high voltage) of several tens to several hundred KV (40 KV to 100 KV) is applied to both ends of the X-ray tube (cathode tube part and anode tube part), free electrons generated from the filament 24 pop out at high speed and are located on opposite sides of the target. The X-rays are generated while hitting the (25).

In order to generate X-rays in the X-ray tube as described above, a current must be supplied from the main body 10 to the filament 24 of the X-ray tube, and also a tube voltage is applied to the cathode tube part 22 and the anode tube part 23 of the X-ray tube. (High voltage) shall be applied.

The method for supplying tube current and tube voltage to the X-ray tube may include converting digital data corresponding to a signal selected by a user into an analog signal through a digital / analog converter (not shown) in the control board 12. Output the level reference signal. Then, the fill width modulation integrated circuit (PWM IC) (not shown) of the driving board 13 compares a reference signal input from the control board 12 with a feedback signal of the X-ray tube to each other. Supply the tube voltage and tube current by adjusting the pulse width until the level is the same.

In this way, X-ray generation is divided into a continuous perspective method for continuously generating X-rays and a pulsed perspective method for generating X-rays in a pulse form.

3 is a timing diagram for describing a continuous perspective system of a general X-ray generator, and FIG. 4 is a timing diagram for explaining a continuous perspective system of a conventional X-ray generator.

In the X-ray continuous perspective system, as shown in FIG. 3, the reference signal is continuously output from the main body 10 so that the current is continuously supplied to the filament 24 of the X-ray tube, and at the same time, the cathode tube portion of the X-ray tube ( 22) and the tube voltage is continuously supplied to the anode tube 23 so that the X-rays are continuously output. In FIG. 3, it is a reference signal, and b is a feedback signal.

In the X-ray pulse fluoroscopy method, as shown in FIG. 4, the reference signal is output from the main body 10 in the form of a pulse so that the current is supplied to the filament 24 of the X-ray tube in the form of a pulse and synchronized with the current. The tube voltage is also supplied to the cathode tube part 22 and the anode tube part 23 of the X-ray tube in a pulse form so that the X-rays are output in a pulse form.

For example, the tube voltage c and the tube current d are synchronized to each other and applied to the X-ray tube in the form of pulses, the tube voltage swings from 0 V to 40 KV, and the tube current swings from 0 mA to 10 to 40 mA.

Since the continuous fluoroscopy continuously outputs a certain amount of X-rays, on average, more radiation is exposed than the pulse fluoroscopy, which is harmful to the human body, consumes more power, and generates a lot of heat. Therefore, the pulse fluoroscopy method is used a lot recently.

However, such a conventional pulse seeing method has the following problems.

In other words, in the conventional pulse-perspective method, in order to stop the X-ray output, even if the tube voltage is applied at 0V and the tube current is applied at 0mA, the X-ray is further generated by the RC time constant inside the circuit. There was a limit to raising the frequency of the pulse because it had to wait for the output of the X-rays to stop.

In addition, even when X-ray generation starts, it takes a long time to raise the tube current and the tube voltage from the initial state (10 mA, 0V) to the driving tube voltage.

Therefore, the conventional pulse seeing method has a disadvantage in that the response speed is slow.

The present invention is to solve the above-mentioned conventional problems, the X-ray generator of the X-ray on-off response speed of the X-rays by changing the driving method and the pulse frequency to increase the more X-ray image in a short time It is an object of the present invention to provide a pulse perspective driving method.

In the pulse perspective driving method of the X-ray generator according to the present invention for achieving the above object, X-rays for supplying a tube current in the form of a pulse to the X-ray tube, supplying a tube voltage in the form of pulses to the cathode and anode tubes of the X-ray tube The pulse perspective driving method of the generator is characterized in that a tube current higher than the X-ray generating tube current is supplied for a predetermined time in synchronization with the falling edge of the tube voltage.

In this case, the tube voltage may maintain a voltage of 30% to 80% of the voltage of the high section in which the X-rays are generated.

The pulse perspective driving method of the X-ray generating apparatus according to the present invention having the above characteristics will be described in more detail with reference to the accompanying drawings.

5 is a timing diagram illustrating a pulse perspective driving method of an X-ray generator according to the present invention.

Since the hardware configuration of the X-ray generating apparatus according to the present invention is the same as the conventional one, the description thereof will be omitted, and the operation of each part will be described with reference to FIGS. 1 to 2 mentioned in the prior art.

In the pulse perspective driving method of the X-ray generator according to the present invention, the reference signal is output in the form of a pulse from the main body 10, the tube current is supplied to the X-ray tube in the form of a pulse, and the cathode tube of the X-ray tube in synchronization with the tube current The tube voltage is also supplied to the unit 22 and the anode tube unit 23 in the form of pulses, and the X-rays are output in the form of pulses.

For example, the tube voltage (e) and the tube current (f) are synchronized to each other and applied to the X-ray tube in the form of pulses, the tube voltage swings from 0 to 40 to 100 KV, and the tube current swings from 0 mA to 10 mA to 40 mA. .

At this time, at the falling edge of the tube voltage (e) pulse, as shown in ⓐ of FIG. 5, the tube current (f) is forcibly applied to make the X-ray tube consume energy for a short time. The voltage in the X-ray tube is rapidly lowered, causing the X-ray output to stop quickly.

In addition, since X-rays are generated when a tube voltage (e) of a predetermined voltage or more is applied, as shown in (b) of FIG. A constant voltage of 30 to 80%, preferably 50%) is output to the X-ray tube to reduce delay caused by time constant so that X-rays can be generated at a higher frequency.

For example, in more detail as follows.

Assume that the X-ray tube has a specification (SPEC) with a tube voltage of 40 KV to 100 KV and a tube current of 10 mA to 40 mA.

In the X-ray tube having the above specification, when the reference signal is "high level" in order to generate X-rays, a tube voltage of about 40 KV is applied to the cathode and anode tubes, and a tube current of about 10 mA is applied to the filament to generate X-rays. Let's do it.

When the reference signal transitions to the "low signal" to turn off the X-ray generation, the tube voltage e drops to a low level. At this time, the tube current (f) is applied to 40mA for about 1 second, as shown in ⓐ of Figure 5 and then falls to a low level. Therefore, since the energy is consumed for a short time in the X-ray tube, the voltage in the X-ray tube is rapidly lowered to stop the X-ray output.

In addition, the tube voltage (e) also does not drop the low level to 0V, as shown in ⓑ of Figure 5, maintains about 20KV corresponding to 50% of the tube voltage. Therefore, the delay caused by the time constant is reduced so that X-rays can be generated at a higher frequency.

On the other hand, it is assumed that the X-ray tube has a specification (SPEC) with a tube voltage of 46 KV to 100 KV and a tube current of 10 mA to 30 mA.

In the X-ray tube having the above specification, when the reference signal is "high level" in order to generate X-rays, X-rays are generated by applying a tube voltage of about 60 KV to the cathode and anode tubes and applying a tube current of about 10 mA to the filament. Let's do it.

When the reference signal transitions to the "low signal" to turn off the X-ray generation, the tube voltage e drops to a low level. At this time, the tube current (f) is applied to 30mA for about 1 second, as shown in ⓐ of Figure 5 and then falls to a low level. Therefore, since the energy is consumed for a short time in the X-ray tube, the voltage in the X-ray tube is rapidly lowered to stop the X-ray output.

In addition, the tube voltage (e) also does not drop the low level to 0V, and maintains about 30KV corresponding to 50% of the tube voltage, as shown in ⓑ of FIG. Therefore, the delay caused by the time constant is reduced so that X-rays can be generated at a higher frequency.

The pulse perspective driving method of the X-ray generator according to the present invention as described above has the following effects.

When stopping the X-ray output, the tube current is forcibly applied at the falling edge of the tube voltage pulse so that the X-ray tube consumes energy for a short time, so that the voltage in the X-ray tube is rapidly lowered so that the X-ray output stops quickly.

In addition, since the voltage corresponding to about 50% of the driving voltage is supplied to the cathode and anode tubes of the X-ray tube in the section where the X-rays are not output, the delay caused by the time constant is reduced so that the X-rays can be generated at a higher frequency. .

As a result, the response speed is fast and the frequency of the pulse can be increased, so that more X-ray images can be obtained in a short time.

Claims (2)

In the pulse perspective driving method of the X-ray generator for supplying a tube current in the form of a pulse to the X-ray tube, and supplying a tube voltage in the form of pulses to the cathode and anode tubes of the X-ray tube, And a tube current higher than an X-ray generating tube current for a predetermined time in synchronization with the falling edge of the tube voltage. The method of claim 1, And the tube voltage maintains a voltage of 30% to 80% of the voltage of the high section generating the X-ray in the pulse level low level section.

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