KR100967346B1 - Tube current cotrolling circuit of field emission X-ray tube - Google Patents

Abstract

The present invention relates to a tube current control circuit of a field emission X-ray tube. Specifically, when the voltage is increased by comparing the applied voltage and a set resistance value, the light intensity of the light source unit 39 is sequentially increased, and the voltage is increased. When the lowering of the light source unit 39, the integral comparator 37 for sequentially lowering the light intensity and two input connection lines are connected to one side and the other side of the first resistor 33 made of one resistor, respectively, and the output connection line A first operational amplifier 31 for supplying a voltage by connecting to an input connection line of the integrating comparator 37 and a cathode 42 grounded to one side of the first resistor 33 and having a positive electrode panel; A second operational amplifier 35 connecting one side and the other side of the second resistor 34 formed of two resistors to two input connection lines, respectively, and a bleed resistor connected to the other side of the second resistor to feed back the voltage. Wow, A high voltage power supply 32 for supplying power to the circuit or receiving the feedback voltage by connecting the second operational amplifier 35 in parallel with a positive electrode on the side and a negative electrode on the other side. And the photodetector 41 which detects the light intensity of the light source unit 39 and adjusts the potential difference VG applied to the grid 43 and the emitter 44 to change the voltage, thereby forming the emitter 44. It relates to a tube current control circuit of the field emission X (X) tube, characterized in that it automatically adjusts the intensity of the X-rays emitted from.

Carbon nanotubes, photodetection, potential difference

Description

Tube current control circuit of field emission X-ray tube

The present invention relates to a tube current control circuit of a field emission X-ray tube. When a resistance exists within a set value of a variable resistor, a resistance value applied to the photodetector 41 is low, so that the cathode 42, the grid 43, A current flows toward the emitter 44 and the photodetector 41, a voltage flows toward the photodetector 41, the emitter 44, the grid 43, and the cathode 42, and the photodetector When the intensity of the light applied to (41) is out of the setting value of the variable resistor, the amount of current is sequentially reduced to reduce the intensity of light generated by the light source unit 39, thereby reducing the intensity of the light emitted from the emitter 44. It relates to a tube current control circuit of a field emission X (X) tube characterized in that the intensity is automatically adjusted.

Recently, with the development of carbon nanotube technology, a technology of replacing the cathode of a conventional X-ray tube of a thermal electron emission method using a conventional filament with a cold cathode method using carbon nanotubes (CNT) has been developed.

Since industrial non-destructive imaging and medical radiographic images are directly related to the output and focus size of the X-ray tube in order to obtain high contrast and high resolution images, the performance of the X-ray tube plays a critical role in the fundamental performance of the system.

In general, carbon nanotube-based X-ray tubes use a focusing electrode that serves as an electrical lens to improve focusing performance and improve a focusing performance by adjusting a voltage applied to the focusing electrode. In this case, a voltage equal to or similar to the voltage applied to the grid part is generally maintained to maintain the optimal focusing performance. When the voltage of the grid part increases to improve the tube current, the effect of the voltage decreases. Even if it is adjusted, the change in focus size is so severe that high quality X-ray images cannot be obtained.

In addition, the X-ray tube is composed of an emitter portion made of carbon nanotubes, a grid portion that is a metal panel for inducing field emission in the carbon nanotubes, and a cathode portion that accelerates the emitted electrons and generates X-rays by collision of electrons. It is equipped with a separate transformer or transformer connected to each said part to control the flow of voltage and current of each said part.

The three-pole X-ray tube, which is a structure of a general X-ray tube, uses a method of focusing by electron acceleration of the grid portion and the cathode portion or focuses electrons using a single focusing electrode, and increases the voltage of the grid portion to increase the tube current. Increasing the value increases the focus size. At this time, the voltage of the focusing electrode is maintained to be the same as or similar to the voltage of the grid portion, and under such an applied voltage condition, there is an effect of maintaining the focal position near the cathode portion and thus the best near the cathode portion. It helps maintain focus performance.

However, the three-pole X-ray tube, which is a structure of such a general X-ray tube, has a limitation on focusing of the emitted electron beam using a focusing method by electron acceleration of the grid portion and the cathode portion.

In particular, electron emission of carbon nanotubes is induced by the voltage of the grid portion, which determines the tube current of the X-ray tube. Therefore, in order to secure an appropriate amount of tube current according to the characteristics of the sample to be photographed using the X-ray tube, the grid portion voltage is adjusted and used. At this time, if the gate voltage is adjusted to adjust the tube current, a change in focus size occurs. Even if the standard triple structure or one focusing electrode is used to correct it to some extent, the change in the focus size is very large, resulting in deterioration of the X-ray image.

In other words, in the conventional carbon nanotube based X-ray tube, the focusing performance is improved by using a cathode, an anode, the grid portion, and one focusing electrode, but when the applied voltage of the grid portion is increased to improve the tube current, the focus is increased. The size is considerably larger and the focusing electrode is used to alleviate this, but it is hard to expect a big performance improvement.

In addition, when the applied voltage of the grid portion is increased to improve the tube current, the focal size changes considerably, and to avoid this, it is necessary to use it fixed to a specific tube current value or to suffer the degradation of the X-ray image due to the change in the focus performance. There was another problem.

Accordingly, the present invention has been made to solve the above problems, and by controlling the amount and flow of voltage and current by the light source unit and the photodetecting device without the need for an insulating transformer, it is possible to minimize the change in the focus size to obtain a high quality X-ray image. The present invention provides a tube current control circuit for a field emission X (X) tube, characterized in that the field emission efficiency is very excellent and high luminance and high efficiency X (X) can be generated.

In the tube current control circuit of the field emission X-ray tube according to the present invention, when the voltage is increased by comparing the applied voltage and the set resistance value, the light intensity of the light source unit 39 is sequentially increased, and when the voltage is lowered, An integrated comparator 37 for sequentially lowering the light intensity of the light source unit 39;

A first operational amplifier configured to connect two input connection lines to one side and the other side of the first resistor 33 formed of one resistor, and to connect the output connection line to one input connection line of the integral comparator 37 to apply a voltage ( 31);

A cathode 42 grounded at one side of the first resistor 33 and formed of an anode panel;

The second operational amplifier 35 which connects one side and the other side of the second resistor 34 made of one resistor to two input connection lines, respectively, and connects a bleed resistor to the other side of the second resistor so that the voltage is fed back. )Wow;

A positive electrode is formed on one side and a negative electrode is formed on the other side, and the second operational amplifier 35 is connected in parallel to supply power to a circuit or to receive the feedback voltage. ); And

The light source unit 39 detects the intensity of light and adjusts the potential difference (VG) applied to the grid 43 and the emitter 44 to change the voltage; It is characterized by automatically adjusting the intensity of the emitted X-rays.

In addition, the high-voltage power supply 32 is formed with two lines on the other side, any one of which is the negative electrode, and the negative electrode is the other side of the third resistor 40. The first line is connected to a line, and the other one line is applied with a voltage that is grounded and fed back from the output connection line of the second operational amplifier 35.

In addition, the second resistor 34 extends two connection lines to one side contact, grounds one of the two wires to one input connection line of the high voltage power supply 32, and grounds the other one wire. Grounded at one input connection line of the second operational amplifier 35;

One of the two wires is grounded to the other input connection wire of the second operational amplifier 35 by extending two connection wires to the other contact point, and the other wire is connected to one side of the bleed resistor 36. It is characterized in that the ground to the connecting line.

In addition, the first resistor 33 extends to one contact with three connection lines, one of the three wires to ground, the other to the cathode (Cathode) 42, and the other one of the three wires. Grounds at one input connection line of the first operational amplifier 31,

The other input contact ground of the first operational amplifier 31 and the one end connection line of the second resistor 34 are respectively connected in parallel between the other input contact line of the high voltage power supply 32. .

In addition, the automatic adjustment of the intensity of the X-rays emitted from the emitter 44, if the resistance exists within the set value of the variable resistor 38, the resistance value applied to the photodetector 41 is low, the cathode ( 42, a current flows toward the grid 43, the emitter 44, and the photodetector 41, and the photodetector 41, the emitter 44, the grid 43, and the cathode ( When the voltage flows to the side 42 and the intensity of the light applied to the photodetector 41 is out of the setting value of the variable resistor, the current amount is sequentially reduced to reduce the intensity of the light generated by the light source unit 39. It is done.

As described above, according to the present invention, the tube current control circuit of the field emission X-ray tube of the present invention does not require an insulation transformer, so that the tube current control circuit of the X-ray tube is simply formed, and carbon nanotubes and grids instead of filaments are formed. There is an advantage that can be used to form the correct focus.

In addition, since the voltage and the current amount are controlled by the light source unit and the photodetecting device, there is an advantage in that a high quality X-ray image can be obtained by minimizing the change in focus size.

The X-ray tube using the carbon nanotubes can emit electrons at room temperature, so the life of the light source is greatly improved. Compared with filament, electron emission efficiency is very good, high brightness, high efficiency X (X) ray can be generated, and compact size can be manufactured to improve product value.

In addition, there is no need to adjust the voltage by mounting a separate transformer to the carbon nanotube-based X-ray tube.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram of a tube current control circuit of a field emission X-ray tube according to an embodiment of the present invention.

As shown in FIG. 1, the tube current control circuit of the field emission X-ray tube of the present invention compares the applied voltage and a set resistance value and sequentially increases the light intensity of the light source unit 39 when the voltage is increased. When the voltage decreases, the input comparator 37 connects the integrating comparator 37 for sequentially decreasing the light intensity of the light source unit 39 and one input and the other side of the first resistor 33 composed of one resistor. A first operational amplifier 31 for applying a voltage by connecting an output connection line to one input connection line of the integrating comparator 37, and a cathode 42 grounded to one side of the first resistor 33; And a second operational amplifier which connects one side and the other side of the second resistor 34 composed of one resistor to two input connection lines, respectively, and connects a bleed resistor to the other side of the second resistor to feed back the voltage. 35, A high voltage power supply 32 receiving a positive electrode at one side and a negative electrode at the other side and connecting the second operational amplifier 35 in parallel to supply power to a circuit or to receive the feedback voltage. And the photodetector 41 which detects the light intensity of the light source unit 39 and adjusts the potential difference VG applied to the grid 43 and the emitter 44 to change the voltage, thereby forming the emitter 44. Automatically adjust the intensity of X-rays emitted from

Herein, when the resistance exists within the set value of the variable resistor 38, the resistance of the photodetecting device 41 is low when the intensity of the X-rays emitted from the emitter 44 is automatically adjusted. 42, a current flows toward the grid 43, the emitter 44, and the photodetector 41, and the photodetector 41, the emitter 44, the grid 43, and the cathode ( When the voltage flows toward 42 and the intensity of light applied to the photodetector 41 is out of the setting value of the variable resistor, the amount of light generated by the light source unit 39 is also reduced by sequentially reducing the amount of current.

Here, the second operational amplifier 35 is connected in parallel to the high voltage power supply 32.

Here, the high voltage power supply 32 generates a positive electrode on one side and a negative electrode on the other side. In this case, the high voltage power supply 32 is formed with two lines on the other side, and any one of these lines is the negative electrode, and the negative electrode is the third resistor 40. The other line is connected to the other line, and the other one line receives a voltage fed back to the ground by the output connection line of the second operational amplifier 35. In this case, the feedback is because the bleed resistor 36 is connected. In addition, it is obvious that the feedback is applied to the other side of the high voltage power supply 32 through comparative amplification of the voltage in the second operational amplifier 35.

Here, the second operational amplifier 35 connects one side and the other side of the second resistor 34 composed of one resistor to two input connection lines, respectively.

In this case, the second resistor 34 extends with two connection lines at one contact point, grounds one of the two wires to one input connection line of the high voltage power supply 32, and grounds the other one wire. Ground to one input connection line of the second operational amplifier 35, extend to two connection lines to the other contact, and ground one of the two to the other input connection line of the second operational amplifier 35 The other contact point of the second resistor 34, which grounds the other one wire to one connection line of the bleed resistor 36, extends to two connection lines so that any one of the two wires is connected to the first connection line. 2 Ground the other input connection line of the operational amplifier 35, and ground the other one line to one connection line of the bleed resistor 36.

Here, the high voltage power supply 32 has the positive electrode at one side thereof, and the other side of the first resistor 33 having one resistor in series with one input connection line, which is the positive electrode. Connect.

Here, the first resistor 33 extends with three connection lines at one contact, one of the three lines is ground, the other is a cathode (Cathode, 42), and the other one is Is grounded on one input connection line of the first operational amplifier 31, and the other input connection line ground of the first operational amplifier 31 and the second input terminal are connected to the other contact with the one input connection line of the high voltage power supply 32. One connection line of the resistor 34 is grounded in parallel.

At this time, a current flows from the one side input connection line of the high voltage power supply 32 to the cathode 42, which is an anode panel, through the first resistor 33.

Here, the first operational amplifier 31 connects the output connection line to one input connection line of the integral comparator 37. The variable resistor 38 is connected to the other input connection line of the integral comparator 37. In addition, a light source unit 39 for generating a light source is connected to the output connection line of the integral comparator 37. The first operational amplifier 31 connects one side and the other side of the first resistor 33 composed of one resistor to two input connection lines, respectively.

Here, the integrator comparator 37 compares the voltage input through the first operational amplifier 31 and the resistance value set through the variable resistor 38 to increase the voltage value. Increasing the intensity of the light source and lowering the voltage value also lowers the light intensity of the light source unit 39.

Here, the light source unit 39 is an element having an LED or a light detection function.

Here, the variable resistor 38 is a resistor for adjusting the current and may set a set value.

Here, the bleed resistor 36 has a relatively large electrical resistance by connecting a plurality of resistors in series, and provides a discharge path with respect to accumulated charge. At this time, the third resistor 40 which is one resistor is connected in series to the other side of the bleed resistor 36. In addition, the photodetector 41, the grid 43, and the emitter 44 are connected in parallel to the third resistor 40. That is, one of the other two lines of the high voltage power supply 32 is connected to the other side of the third resistor 40, the other connection line of the photodetecting device 41, and the emitter 44. One side connection line of the photodetecting device 41 and a contact point are connected to the grid 43 on a line connecting the one side of the third resistor 40 and the contact of the bleed resistor 36 in parallel.

The photodetecting device 41 is a cadmium sulfide (CDS) sensor or photodiode for detecting the intensity of light output from the light source unit 39.

Here, the photodetector 41 detects the light intensity and adjusts the potential difference VG applied to the grid 43 and the emitter 44 to vary the voltage.

Here, the resistance value is changed according to the intensity of the light output from the light source unit 39. In other words, according to Ohm's law, as the voltage increases, the resistance applied to the integral comparator 37 is relatively lowered. At this time, the light source unit 39 gradually becomes brighter.

In this case, as the intensity of the light increases, the resistance applied to the photodetector 41 also decreases, and the voltage is increased toward the photodetector 41, the emitter 44, the grid 43, and the cathode 42. The current flows toward the cathode 42, the grid 43, the emitter 44, and the photodetector 41.

Here, the grid 43 is a patterned metal panel in which a polygonal or circular regular array of pores is formed on a flat surface.

Here, the emitter 44 is a carbon nanotube (CNT) or an air tube.

Here, the current is automatically adjusted according to the potential difference VG between the grid 43 and the emitter 44.

Hereinafter, an embodiment of the present invention will be described in detail according to the flow of current and voltage.

First, when power is supplied to a circuit connected through the high voltage power supply 32, a positive electrode is generated at one side of the high voltage power supply 32, and a negative electrode is formed at the other side of the high voltage power supply 32.

Subsequently, the voltage is amplified by the second operational amplifier 35 and the second resistor 34 so that the voltage is fed back to the high voltage power supply 32 through the output connection line of the second operational amplifier 35. do. In this case, the voltage amplified by the first operational amplifier 31 and the first resistor 33 applies a voltage to the integral comparator 37 through an output connection line of the first operational amplifier 31.

Subsequently, the intensity of light emitted from the light source unit 39 varies according to the voltage output from the integral comparator 37. At this time, when the voltage is high, the light emitted from the light source unit 39 is sequentially lightened, and when the voltage is low, the light emitted from the light source unit 39 is sequentially darkened.

Subsequently, the amount of light emitted from the light source unit 39 is applied to vary the amount of X-rays emitted from the photodetecting device 41. That is, when the intensity of the light emitted from the light source unit 39 is applied to the photodetector 41, the photodetector 41 is a voltage difference applied to the grid 43 and a potential difference VG applied to the emitter 44. By varying the voltage to increase or decrease the amount of emission of the X-rays.

Next, the cathode 42, the grid 43, the cathode tube, the emitter 44, and the light sword, which are anode panels, through the first resistor 33 at one input connection line of the high voltage power supply 32. Current flows to the exit element 41 side. That is, when the intensity of light applied to the photodetecting device 41 is within the setting value of the variable resistor, the resistance value applied to the photodetecting device 41 is low so that the current flows. In addition, when the intensity of light applied to the photodetecting device 41 is out of the setting value of the variable resistor, the current amount is sequentially reduced to reduce the intensity of light generated by the light source unit 39.

As described above, the tube current control circuit of the field emission X-ray tube of the present invention detects the intensity of light at the light detecting element 38 and the light source unit 37 to automatically adjust the amount of X-ray emission by adjusting the amount of current. will be.

In addition, the photodetecting device 38 and the light source unit 37 improve the focusing performance of the X-ray tube of the conventional carbon nanotube application, and the emitter 44 and the grid 43 by the photodetecting device 38. Control the tube voltage and tube current flow by adjusting the voltage potential difference (VG).

In addition, in the tube current control circuit of the field emission X-ray tube according to the present invention, when a resistance exists within a set value of the variable resistor 38, the resistance value applied to the photodetector 41 is low, so that the cathode 42 The current flows toward the grid 43, the emitter 44, and the photodetector 41, and the photodetector 41, the emitter 44, the grid 43, and the cathode 42. When the voltage flows to the side and the intensity of the light applied to the photodetector 41 is out of the setting value of the variable resistor, the amount of light generated by the light source unit 39 is also reduced by sequentially reducing the amount of current.

Although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto and is intended by those skilled in the art to which the invention pertains to the spirit and scope of the present invention. Of course, various modifications and variations are possible within the scope of equivalents.

1 is a diagram of a tube current control circuit of a field emission X-ray tube according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

31: first operational amplifier 32: high voltage power supply

33: first resistor 34: second resistor

35: second operational amplifier 36: bleed resistance

37: integral comparator 38: variable resistor

39: light source 40: third resistor

41: photodetector 42: cathode

43 grid 44 emitter

Claims (5)

Integrating comparator 37 for sequentially increasing the light intensity of the light source unit 39 when the voltage is increased by comparing the applied voltage and a set resistance value, and sequentially decreasing the light intensity of the light source unit 39 when the voltage is lowered. Wow; A first operational amplifier configured to connect two input connection lines to one side and the other side of the first resistor 33 formed of one resistor, and to connect the output connection line to one input connection line of the integral comparator 37 to apply a voltage ( 31); A cathode 42 grounded at one side of the first resistor 33 and formed of an anode panel; The second operational amplifier 35 which connects one side and the other side of the second resistor 34 made of one resistor to two input connection lines, respectively, and connects a bleed resistor to the other side of the second resistor so that the voltage is fed back. )Wow; A high voltage power supply 32 receiving a positive electrode at one side and a negative electrode at the other side and connecting the second operational amplifier 35 in parallel to supply power to a circuit or to receive the feedback voltage. ; And The light source unit 39 detects the intensity of light and adjusts the potential difference (VG) applied to the grid 43 and the emitter 44 to change the voltage; A tube current control circuit of a field emission X-ray tube, characterized in that it automatically adjusts the intensity of the emitted X-rays. The method of claim 1, The high pressure power supply 32, It is formed with two lines on the other side, any one of which is the negative electrode, the negative electrode is connected to the other line of the third resistor 40, and the other one is the first line. 2 A tube current control circuit of a field emission X-ray tube, characterized in that a voltage fed from the output connection line of the operational amplifier 35 is fed back. The method of claim 1, The second resistor 34 is, One of the two wires is grounded to one input connection line of the high voltage power supply 32 by extending two connection lines to one contact point, and the other one input of one side of the second operational amplifier 35. Ground to the connecting wire, One of the two wires is grounded to the other input connection wire of the second operational amplifier 35 by extending two connection wires to the other contact point, and the other wire is connected to one side of the bleed resistor 36. A tube current control circuit of a field emission X (X) tube, characterized in that it is grounded to a connecting line. The method of claim 1, The first resistor 33 is, One of the three lines is grounded, the other one is a cathode (Cathode, 42), and the other one is the one side of the first operational amplifier 31. Ground to the input lead, Between the other side of the input connection line of the first operational amplifier 31 and the one side connection line of the second resistor (34) between the input connection line of the high voltage power supply 32, respectively, characterized in that the parallel grounding Tube current control circuit of field emission X-ray tube. The method of claim 1, Automatically adjusting the intensity of the X-rays emitted from the emitter 44, When the resistance exists within the set value of the variable resistor 38, the resistance value applied to the photodetector 41 is low, so that the cathode 42, the grid 43, the emitter 44 and the photodetector ( 41 flows toward the photodetector 41, the emitter 44, the grid 43, and the cathode 42, and the intensity of light applied to the photodetector 41 If outside the set value of the variable resistor, the electric current of the field emission X (X) tube of the field emission X (X) tube, characterized in that by sequentially reducing the amount of light generated by the light source unit 39.

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