KR101106717B1 - Apparatus for generating X-ray - Google Patents

Abstract

More particularly, the present invention relates to an X-ray generator, and more particularly to an X-ray generator that measures an output current of a secondary coil of a filament transformer that outputs a current to a cathode filament provided in an X- To an X-ray generator for controlling the magnitude of a current with a constant current.
The X-ray photographing apparatus according to the present invention controls the output current on the secondary coil side of the filament transformer by a constant current so that when the size of the current output from the secondary coil side of the filament transformer is initially set during manufacture of the X- It can be easily installed regardless of the structure or environment of the place where the line image pickup apparatus is installed. Therefore, it is not necessary to calibrate the current flowing through the X-ray tube at the time of installation of the X-ray imaging apparatus or periodically, and it is easy to manage / maintain the X-ray imaging apparatus.

Description

[0001] Apparatus for generating X-ray [0002]

The present invention relates to an X-ray imaging apparatus, and more particularly, to an X-ray photographing apparatus which detects an output current of a secondary coil of a filament transformer applying current to a negative filament provided in an X- And controls the magnitude of the current output from the secondary coil of the photodetector to a constant current.

An X-ray imaging apparatus is an apparatus for generating an X-ray and projecting the generated X-ray to a person or an animal to obtain an X-ray image. The obtained X-ray image confirms the health status of a person or an animal.

1, an X-ray photographing apparatus includes a power source driving unit 10, a power generating unit 20, and an X-ray tube 40. The X- The power generating unit 20 and the X-ray tube 40 are usually manufactured separately, and an X-ray tube 40 is installed at a place where an X-ray image of a real person or an animal is to be photographed. The power generating unit 20 and the X-ray tube 40 are electrically connected to the high voltage cables 34 and 35 through the connectors 31, 33, 37, and 38.

The power supply driving unit 10 includes a voltage driving unit 11, a current driving unit 13, a current detecting unit 15, and a control unit 17. The voltage driving unit 11 and the current driving unit 13 respectively drive a high voltage supplied to the X-ray tube 40 in the power generating unit 20 and a power source necessary to generate a current provided by the negative filament.

The voltage generating part 20 includes a high voltage generating part 21 and a filament transformer 23. Normally the high voltage generating part 21 and the filament transformer 23 are sealed in a high pressure tank filled with an insulating material such as insulating oil . The voltage driving unit 11 and the high voltage generating unit 21 are electrically connected to each other through the power line 18 and the connector 25. The current driving unit 13 and the filament transformer 23 are connected to the power line 19 and the connector 25, (Not shown). The power source driven by the voltage driving unit 11 is supplied to the high voltage generating unit 21 through the power source line 18 and the connector 25 and the power source driven by the current driving unit 13 is connected to the power source line 19 and the connector 27 to the filament transformer 23.

The X-ray tube 40 includes an X-ray tube housing 41 in which the interior of the X-ray tube 40 maintains a vacuum state, an anode 43 disposed inside the X-ray tube housing 41, And a negative electrode filament 45 disposed opposite thereto. The high voltage generated in the high voltage generating part 21 is supplied to the anode 43 and the cathode filament 45 and the filament current generated in the filament transformer is supplied to the cathode filament 45.

The filament current supplied to the cathode filament 45 generates heat electrons by heating the cathode filament 45. The resulting generated electrons collide with the anode 43 due to a voltage difference between the anode 43 and the cathode filament 45, Line. The intensity of the X-ray generated in the X-ray tube 40 is determined by the magnitude of the high voltage applied between the anode 43 and the cathode filament 45 or the magnitude of the X-ray tube current flowing between the anode 43 and the cathode filament 45 .

The size of the filament current applied to the cathode filament 45 is controlled to control the size of the X-ray tube current flowing between the anode 43 and the cathode filament 45 of the X-ray tube 40, The magnitude of the current applied to the primary coil of the filament transformer 23 is adjusted. More specifically, the current detector 15 detects the current applied to the primary coil of the filament transformer 23 in the current driver 13, and the controller 17 detects the magnitude of the detected current and the magnitude of the reference current And controls the current driving unit 13 so that the constant current having the same magnitude as the reference value is applied to the primary coil of the filament transformer 23. [ The magnitude of the current input to the primary coil of the filament transformer 23 is adjusted to the constant current by controlling the pulse lock of the driving current generated by the driving unit 13 by detecting the current applied to the primary coil of the filament transformer 23 .

It is necessary to precisely control the magnitude of the high voltage applied between the anode and cathode filaments and the current flowing through the X-ray tube in order to obtain a clear and high quality X-ray image without irradiating the patient or animal with too much X- have.

The conventional X-ray imaging apparatus described above detects the current applied to the primary coil of the filament transformer 23 to control the magnitude of the current applied to the primary coil of the filament transformer 23 do. Typically, the X-ray tube current is initialized to optimize the magnitude of the X-ray tube current during manufacture of the X-ray imaging apparatus, thereby setting the magnitude of the current applied to the primary coil of the filament transformer 23. However, depending on the structure and environment of the place for installing the X-ray imaging apparatus, the high-pressure tank sealing the filament transformer 23 and the X-ray tube 40 are disposed separately from each other, and the filament transformer 23 and the X- The cable resistance varies depending on the length of the high voltage cable 35 between the connectors 33 and 38 or the connection resistance of the connectors 33 and 38 changes. The resistance of the high voltage cable 35 between the filament transformer 23 and the X-ray tube 40 or the connection resistance of the connectors 33 and 38 is varied to change the magnitude of the current applied to the cathode filament 45.

Therefore, even when the size of the X-ray tube current is optimally initialized during the manufacture of the X-ray imaging apparatus, the length of the high voltage cable 35 or the length of the connectors 33 and 39 The magnitude of the current applied to the cathode filament 45 of the X-ray tube 40 is different each time depending on the connection resistance. Therefore, the initial setting of the current applied to the primary coil of the filament transformer 23 becomes useless during manufacture of the X-ray imaging apparatus, and when the X-ray imaging apparatus is installed, the length of the high voltage cable 35, It is inconvenient to correct the magnitude of the current applied to the primary coil of the filament transformer 23 according to the connection resistance of the primary winding 39,

Furthermore, since the magnitude of the X-ray tube current is indirectly controlled through the magnitude of the current applied to the primary coil of the filament transformer 23, it is difficult to control the magnitude of the X-ray tube current accurately.

An object of the present invention is to provide an X-ray photographing apparatus for controlling a secondary coil output current of a filament transformer applied with a negative filament by a constant current, .

Another object of the present invention is to provide an X-ray tube which can accurately control the magnitude of X-ray tube current even when the installation environment of the X-ray imaging apparatus is controlled by controlling the magnitude of the X-ray tube current directly from the secondary coil output current of the detected filament transformer. Ray imaging apparatus.

In order to accomplish the object of the present invention, an X-ray imaging apparatus according to the present invention comprises: an X-ray tube disposed opposite to an anode and an anode to have cathode filaments for emitting electrons; A filament transformer for generating a current to be applied to the negative filament, a current detector for detecting a secondary coil side output current of the filament transformer applied to the negative filament, and a current detector for detecting an output current of the filament transformer And a control unit for controlling the secondary coil side output current with a constant current. The high-voltage generating unit, the filament transformer, and the current detecting unit are sealed in a high-pressure tank filled with an insulating portion. On one surface of the high-pressure tank, a connecting portion for transmitting the current detected by the current detecting unit to the control unit is provided.

Wherein the control unit converts the detected output current of the secondary coil of the filament transformer into a detected voltage and outputs the converted detected magnitude of the detected voltage, And a current controller for controlling a magnitude of a current applied to the primary coil of the filament transformer based on a magnitude of the detected voltage and a difference in magnitude of the reference voltage.

Preferably, the anode is a rotating anode rotating at high speed, and the cathode filament has a converging filament and a focusing filament. The filament transformer includes a focusing filament transformer for generating a current applied to the focusing filament and a focusing filament transformer for generating a current to be applied to the focusing filament. The current detecting part detects a secondary coil side output current of the focusing filament transformer And a second current detector for detecting the secondary coil side output current of the focusing filament transformer.

In order to accomplish the object of the present invention, there is provided a device for controlling an amount of current applied from a filament transformer to a cathode filament of an X-ray tube, comprising: a current detector for detecting an output current on a secondary coil side of a transformer; A comparator for comparing the magnitude of the detected voltage and the magnitude of the reference voltage to calculate the magnitude of the detected voltage and the magnitude of the reference voltage; And a current controller for controlling the magnitude of the current applied to the primary coil of the filament transformer based on the magnitude of the voltage and the magnitude of the reference voltage.

Here, the converter includes a resistor connected in parallel to the output terminal of the current detector, and an RMS rectifier for converting the AC detection voltage measured at both ends of the resistor to the magnitude of the DC detection voltage.

Preferably, the current control unit controls the magnitude of the current applied to the primary coil of the filament transformer by a pulse width modulation method.

The X-ray imaging apparatus according to the present invention has the following various effects as compared with the conventional X-ray imaging apparatus.

First, the X-ray photographing apparatus according to the present invention controls the output current of the secondary coil side of the filament transformer by a constant current so that the size of the current output from the secondary coil side of the filament transformer is initially set It can be easily installed regardless of the structure or environment of the place where the actual X-ray imaging apparatus is installed.

Second, the X-ray imaging apparatus according to the present invention does not need to calibrate the current flowing in the X-ray tube during installation of the X-ray imaging apparatus or periodically by controlling the output current of the secondary coil side of the filament transformer with a constant current. Therefore, it is easy to manage / maintain the X-ray imaging apparatus.

Third, the X-ray imaging apparatus according to the present invention can accurately control the magnitude of the X-ray tube current by directly controlling the secondary coil side output current of the filament transformer.

Fourth, the X-ray imaging apparatus according to the present invention can accurately and quickly adjust the current flowing through the rotating anode type X-ray tube having a large-capacity counter-current cathode filament by adjusting the output current on the secondary coil side of the filament transformer.

1 is a functional block diagram for explaining a conventional X-ray imaging apparatus.
2 is a functional block diagram illustrating an X-ray imaging apparatus according to an embodiment of the present invention.
3 is a view for explaining an example of a current detector according to the present invention.
FIG. 4 is a functional block diagram for explaining an X-ray imaging apparatus according to another embodiment of the present invention.
5 is a functional block diagram for explaining a control unit of the X-ray imaging apparatus according to an embodiment of the present invention or more.

Hereinafter, an X-ray imaging apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a functional block diagram illustrating an X-ray imaging apparatus according to an embodiment of the present invention.

Referring to FIG. 2, the X-ray imaging apparatus includes a power source driving unit 100, a power source generating unit 200, and an X-ray tube 400. The power generator 200 and the X-ray tube 400 are separately manufactured. An X-ray tube 400 is installed in a place where an X-ray image of a real person or an animal is to be photographed. The power generating unit 200 and the X-ray tube 400 are electrically connected to the high-voltage cables 330 and 340 through the connectors 310, 320, 350 and 360.

The power supply driving unit 100 includes a voltage driving unit 110, a current driving unit 130, and a control unit 150. The voltage driving unit 110 and the current driving unit 130 respectively drive a high voltage supplied to the X-ray tube 400 from the power generating unit 200 and a power source required to generate a current provided by the negative filament.

The voltage generating unit 200 includes a high voltage generating unit 210, a filament transformer 230 and a current detecting unit 240. The high voltage generating unit 210, the filament transformer 230, It is sealed in a high-pressure tank filled with an insulating material such as insulating gas. The voltage driving unit 110 and the high voltage generating unit 210 are electrically connected to each other through the power line 160 and the connector 211. The current driving unit 130 and the filament transformer 230 are connected to the power line 170 and the connector 211, (Not shown). The controller 150 and the current detector 240 are electrically connected to the power supply line 180 through the connector 241.

The power source driven by the voltage driving unit 110 is supplied to the high voltage generating unit 210 through the power line 160 and the connector 211. The power source driven by the current driving unit 130 is connected to the power line 170 and the connector 231 to the filament transformer 230. The current detector 240 detects the output current on the secondary coil side of the filament transformer 230 and provides the detected current to the controller 150 through the connector 241 and the power line 180.

The X-ray tube 400 includes an X-ray tube housing 410 in which the inside of the X-ray tube 400 maintains a vacuum state, an anode 430 disposed inside the X-ray tube housing 410, And cathode filaments 450 arranged opposite to each other. The output terminal of the high voltage generating part 210 is connected to the anode 430 of the X-ray tube 400 through the connector 310, the high voltage cable 330 and the connector 350. The output terminal of the high voltage generating part 210 is connected to the secondary coil of the filament transformer 230 Side output terminal is connected to the cathode filament 450 of the X-ray tube 400 via the connector 320, the high-voltage cable 340 and the connector 360. [

The high voltage generated in the high voltage generating part 210 is supplied to the anode 430 and the cathode filament 450 and the filament current generated in the filament transformer 230 is supplied to the cathode filament 450. The filament current supplied to the cathode filament 450 generates heat electrons by heating the cathode filament 450. The generated hot electrons collide with the anode 430 due to a voltage difference between the anode 430 and the cathode filament 450, Line.

In order to obtain a high-quality clear X-ray image in radiographing an X-ray image of a patient or an animal, the dose of X-rays irradiated to a patient or an animal must be accurately controlled, Ray tube current flowing between the cathode filament 450 and the cathode filament 450. The X-ray tube current magnitude can be adjusted by controlling the magnitude of the filament current applied to the cathode filament 450. In one embodiment of the present invention, the magnitude of the current output from the secondary coil side of the filament transformer 230 is detected through the direct current detector 240, and based on the detected current magnitude, the secondary of the filament transformer 230 The current outputted from the coil side is always controlled to the constant current of the same magnitude.

The length of the high voltage cable 340 between the X-ray tube 400 and the filament transformer 230 is always equal to the length of the cathode filament 450 regardless of whether the length of the X-ray tube 400 is between several meters to several tens of meters Current is applied. Even when the connection resistance of the connectors 320 and 360 for electrically connecting the filament transformer 230 and the negative electrode filament via the high voltage cable 340 varies depending on the environment or the mounting conditions, the negative electrode filament 450 always has the same size Is applied. Therefore, when the X-ray photographing apparatus according to the embodiment of the present invention initially sets the magnitude of the current applied to the cathode filament 450 according to the X-ray irradiation amount, the length of the high- It is not necessary to reset the magnitude of the current applied to the cathode filament 450 even if the connection resistance is changed.

3 is a view for explaining an example of a current detector according to the present invention.

2 and 3, a power source driven by the current driving unit 130 is applied to the primary coil side of the filament transformer 230 through the power line 170 and the connector 231. [ A power source applied to the primary coil side of the filament transformer 230 is converted into a current applied to the negative electrode filament 430 according to the turns ratio of the primary coil and the secondary coil and is supplied from the secondary coil of the filament transformer 230 to the connector 320 The high voltage cable 340, and the connector 360 to the cathode filament 450. A current detector 240 for detecting the current output from the secondary coil of the filament transformer 230 is disposed on one side of the output terminal of the secondary coil of the filament transformer 230. The current detector 240 detects a current output to the secondary coil output terminal of the filament transformer 230 according to the winding ratio of the current transformer and the secondary coil output terminal of the filament transformer 230 using a current transformer do. The detected current is provided to the control unit 150 through the connector 241 and the power supply line 180.

FIG. 4 is a functional block diagram for explaining an X-ray imaging apparatus according to another embodiment of the present invention.

Referring to FIG. 4, an X-ray imaging apparatus according to another embodiment of the present invention includes a power source driving unit, a power generating unit, and an X-ray tube having a focusing anode filament, a focusing cathode filament, and a rotating anode. In the X-ray imaging apparatus according to another embodiment of the present invention, the power driver, the high voltage generator, and the like operate in the same manner as the power driver, the high voltage generator, and the like of the X-ray imaging apparatus according to the embodiment of the present invention described above. The configuration and operation of the X-ray imaging apparatus according to another embodiment of the present invention will be described with reference to an embodiment of the present invention.

The power generating unit 200 includes a high voltage generating unit 210, a filament transformer 230 and a current detecting unit 240. The high voltage generating unit 210, the filament transformer 230, It is sealed in a high-pressure tank filled with insulating material such as insulating oil. The X-ray tube 400 includes an X-ray tube housing 410 in which the inside of the X-ray tube 400 maintains a vacuum state, a rotating anode 430 disposed inside the X-ray tube housing 410 and rotating at high speed, And a negative electrode filament 450 disposed inside the rotating anode 430 facing the rotating anode 430. The cathode filament again has a focusing cathode filament (451) and a focusing filament (453).

The filament transformer 230 includes a focusing filament transformer 232 for generating a current applied to the subfocal cathode filament 451 and a focusing filament transformer 233 for generating a current applied to the focusing cathode filament 453 Respectively. On the other hand, the current detector 240 includes a first current detector 242 for detecting the current output from the secondary coil side of the focusing filament transformer 232 and a second current detector 242 for detecting the current output from the secondary coil side of the focusing filament transformer 233 And a second current detection unit 243 for detecting the current. Hereinafter, a method of controlling the magnitude of the current applied to the small-scaled negative filament 451 or the large-sized negative filament 453 in the X-ray imaging apparatus according to another embodiment of the present invention will be described in detail.

The power source driven by the current driving unit is selectively applied to the primary coil of the focusing filament transformer 232 or the primary coil of the focusing filament transformer 233 via the power line 170 and the connector 231. When driving power is applied to the primary coil side of the focusing filament transformer 232, a current applied to the sub-focusing cathode filament 451 according to the winding ratio of the primary coil and the secondary coil of the focusing filament transformer 232 And is output from the secondary coil of the focusing filament transformer 232 to the focusing cathode filament 451 through the connector 320, the high voltage cable 340 and the connector 360. [ A first current detector 242 for detecting the current output from the secondary coil of the focusing filament transformer 232 is disposed on one side of the output terminal of the secondary coil of the focusing filament transformer 232. Preferably, the first current detector 242 is a current transformer (CT) that converts the secondary coil output of the focusing filament transformer 232 and the secondary coil output of the focusing filament transformer 232 according to the winding ratio of the current converter. As shown in FIG. The detected current is provided to the control unit 150 through the connector 241 and the power supply line 180.

On the other hand, when driving power is applied to the primary coil side of the focusing filament transformer 233, the driving current is applied to the focusing cathode filament 453 according to the winding ratio of the primary coil and the secondary coil of the focusing filament transformer 233 And is output from the secondary coil of the focusing filament transformer 233 to the focusing cathode filament 453 through the connector 320, the high voltage cable 340 and the connector 360. [ A second current detection unit 243 for detecting the current output from the secondary coil of the focusing filament transformer 233 is disposed at one side of the output end of the secondary coil of the focusing filament transformer 233. Preferably, the second current detector 243 is connected to the secondary coil output terminal of the focusing filament transformer 233 according to the winding ratio of the current transformer and the secondary coil output terminal of the focusing filament transformer 233 to a current transformer (CT) As shown in FIG. The detected current is provided to the control unit 150 through the connector 241 and the power supply line 180.

The magnitude of the current output from the secondary coil side of the focusing filament transformer 232 or the focusing filament transformer 233 is directly detected by the first current detecting unit 242 or the second current detecting unit 243, And controls the current output from the secondary coil side of the focusing filament transformer 232 or the focusing filament transformer 243 to a constant current of the same magnitude on the basis of the detected current magnitude.

Therefore, depending on the place where the X-ray tube 400 is located, whether the length of the high voltage cable 340 between the X-ray tube 400 and the filament transformer 230 is from several meters to several tens of meters, The current of the same magnitude is always applied to the counter-current cathode filament 451. Even when the connection resistance of the connectors 320 and 360 that electrically connect the filament transformer 230 and the cathode filament 450 through the high voltage cable 340 varies depending on the environment or mounting conditions, A current of the same magnitude is always applied. Therefore, in the X-ray imaging apparatus according to another embodiment of the present invention, when the magnitude of the current applied to the small-focal-point negative filament 451 or the large-sized negative-electrode filament 453 is initially set according to the X- It is not necessary to reset the magnitude of the current applied to the small-focal-point negative filament 451 and the large-sized negative-electrode filament 453, respectively, even if the length of the high-voltage cable or the connection resistance of the connector changes.

Further, by directly detecting the current applied to the large-sized counter-current cathode filament 453 at the secondary coil output of the counter-filament transformer 233 to control the magnitude of the current applied to the counter-current cathode filament 453, The X-ray tube current flowing between the cathode filament 453 and the rotating anode 430 can be accurately and quickly adjusted.

5 is a functional block diagram for explaining a control unit of the X-ray imaging apparatus according to an embodiment of the present invention or more.

5, the current detected through the current detector 240 at the secondary coil side of the filament transformer 230 is detected by the resistor 151 provided at the input terminal of the controller 150 as an AC detection voltage value And a root mean square (RMS) rectifying unit 153 calculates the magnitude of the converted AC detection voltage value. The comparing unit 155 compares the magnitude of the detected voltage value with the magnitude of the reference voltage, and outputs a difference value between the magnitude of the detected voltage value and the magnitude of the reference voltage. The PWM (Pulse Width Modulation) controller 157 generates a signal for controlling the pulse width of the current driven by the current driver 130 based on the magnitude of the detected voltage value and the magnitude difference between the reference voltage value. For example, when the magnitude of the detected voltage value is larger than the magnitude of the reference voltage value, the PWM controller 157 controls the pulse width of the driving current to be reduced. When the magnitude of the detected voltage value is smaller than the magnitude of the reference voltage value, The control unit 157 controls to increase the pulse width of the driving current. The current driving unit 130 generates a driving current to be applied to the primary coil of the filament transformer 230 under the control of the PWM control unit 157. The PWM controller 157 is a current controller for controlling the magnitude of the current driven by the current driver 130 based on the difference between the magnitude of the detected voltage value and the magnitude of the reference voltage. A current control unit may be used, which is within the scope of the present invention.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: power supply driving unit 110: voltage driving unit
130: current driver 150:
200: Power generator 210: High voltage generator
230: filament transformer 250: current detector
310, 320, 350, 360: connectors 330, 340: high voltage cable
400: X-ray tube 410: X-ray tube housing
430: anode, rotating anode 450: cathode filament

Claims (12)

An X-ray tube having an anode and a cathode filament disposed opposite to the anode;
A high voltage generator for generating a high voltage to be applied to the anode and the cathode filament;
A filament transformer for generating a current applied to the negative filament;
A current detector for detecting an output current on the secondary coil side of the filament transformer applied to the negative filament; And
And a control unit for controlling the secondary coil side output current of the filament transformer to a constant current based on the detected magnitude of the output current. The apparatus of claim 1, wherein the control unit
A converting unit for converting the output current on the secondary coil side of the detected filament transformer into a detected voltage and outputting the magnitude of the converted detected voltage;
A comparison unit comparing the magnitude of the detection voltage and the magnitude of the reference voltage to calculate a difference between the magnitude of the detection voltage and the magnitude of the reference voltage; And
And a current controller for controlling a magnitude of a current applied to a primary coil of the filament transformer based on a magnitude of the detection voltage and a magnitude of a reference voltage. 3. The method of claim 2,
The high-voltage generating unit, the filament transformer, and the current detecting unit are sealed in a high-pressure tank filled with an insulating material,
Further comprising a connector for electrically connecting the current detector to the controller and a power supply line for transmitting the current detected by the current detector to the controller. The method of claim 3,
The anode is a rotating anode rotating at high speed,
Wherein the negative filament comprises a converging filament and a focusing filament. 5. The apparatus of claim 4, wherein the filament transformer
A focusing filament transformer for generating a current applied to the focusing filament; And
And a focusing filament transformer for generating a current to be applied to the focusing filament. The apparatus as claimed in claim 5, wherein the current detector
A first current detector for detecting an output current on the secondary coil side of the coaxial filament transformer; And
And a second current detector for detecting an output current on the secondary coil side of said focusing filament transformer. An apparatus for controlling the magnitude of a current applied from a filament transformer to a cathode filament of an X-ray tube,
A current detector for detecting the secondary coil side output current of the filament transformer;
A converter for converting the detected output current into a detection voltage and outputting the magnitude of the converted detection voltage;
A comparator for comparing the magnitude of the detection voltage and the magnitude of the reference voltage by comparing the magnitude of the detection voltage with the magnitude of the reference voltage; And
And a current controller for controlling a magnitude of a current applied to a primary coil of the filament transformer based on a magnitude of the detected voltage and a magnitude of a reference voltage, 8. The method of claim 7,
Wherein the cathode filament comprises a focusing filament and a focusing filament. 9. The apparatus of claim 8, wherein the filament transformer
A focusing filament transformer for generating a current applied to the focusing filament; And
And a focusing filament transformer for generating a current to be applied to the focusing filament. The apparatus as claimed in claim 9, wherein the current detector
A first current detector for detecting an output current on the secondary coil side of the coaxial filament transformer; And
And a second current detector for detecting an output current on the secondary coil side of said focusing filament transformer. 11. The apparatus according to any one of claims 7 to 10, wherein the converting unit
A resistor connected in parallel to an output terminal of the current detecting unit; And
And an RMS rectifier for converting the AC detection voltage measured at both ends of the resistor to the magnitude of the DC detection voltage. 11. The method according to any one of claims 7 to 10, wherein the current controller
Wherein a magnitude of a current applied to the primary coil of the filament transformer is controlled by a pulse width modulation method.

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