JP5414159B2 - X-ray high voltage device - Google Patents

Description

  The present invention relates to an inverter-type X-ray high voltage apparatus, and in particular, reduces a ripple of a DC high voltage (hereinafter referred to as tube voltage) applied between an anode and a cathode of an X-ray tube that generates X-ray as a load. In addition, the present invention relates to an inverter type X-ray high voltage device suitable for miniaturization and weight reduction.

  In an image diagnostic apparatus using X-rays such as an X-ray imaging apparatus (including fluoroscopy) and an X-ray CT apparatus, an X-ray generation apparatus that generates X-rays for irradiating a diagnostic part of a subject is necessary. . The X-ray generator includes an X-ray tube that generates X-rays, a high-voltage generator that applies a tube voltage between an anode and a cathode of the X-ray tube, the magnitude and application time of the tube voltage, and the X-ray It comprises an X-ray high voltage device equipped with an X-ray control device for controlling the current flowing between the anode and cathode of the tube (hereinafter referred to as tube current).

  The X-ray high voltage device has a fast tube voltage rise, small tube voltage ripple after the rise, has a high speed and high accuracy tube voltage and tube current control function, and is small and lightweight. It is desirable. As an apparatus that satisfies these requirements, an inverter type X-ray high voltage apparatus is utilized in all fields of diagnostic imaging apparatuses using the X-ray.

  The X-ray tube of the X-ray generator using this inverter type X-ray high-voltage device was mainly a neutral point grounding type that grounds the housing of the X-ray tube. With the need for higher capacity and higher load factor, anode-grounded X-ray tubes that ground the anode of the X-ray tube have come to be used.

In particular, in X-ray CT systems, in recent years, “a wide range of scanning is possible in a short time”, “continuous data in the body axis direction can be obtained, which enables the generation of a three-dimensional image”, and “X A spiral CT called a helical scan or a spiral scan having a multi-slice function having a feature such as “multiple rows of line detectors to capture a large number of tomographic images at once” has become the mainstream.
In this spiral CT, an X-ray generator and an X-ray detector are mounted on the scanner rotation unit, and the scanner rotation unit is continuously rotated, and at the same time, the table on which the subject is placed is oriented in the body axis direction of the subject. By continuously moving, the X-ray generator and the X-ray detector are rotated relative to the subject.

  With such a multi-slice imaging function, rotation CT must continuously expose X-rays for a long time from the X-ray tube mounted on the scanner rotation unit, which increases the load on the X-ray tube. An anode grounded X-ray tube, which is advantageous for increasing the capacity, is used. Recently, in order to take an image of the heart of a subject, it is indispensable to further increase the scanning speed, and the mounted object mounted on the scanner rotating unit is required to be further reduced in size and weight.

Under such circumstances, an X-ray high voltage apparatus using a Cockcroft-Walton circuit capable of multiple boosting is patented in order to reduce the size and weight of the high voltage generator of the inverter type X-ray high voltage apparatus. It is disclosed in Document 1.

International Publication Number WO2004 / 103033

  The high voltage generator of the inverter type X-ray high voltage device of Patent Document 1 includes a high voltage transformer that boosts a voltage obtained by converting a DC voltage into a high frequency AC voltage using an inverter circuit, and an output of the high voltage transformer. Consists of a Cockcroft-Walton circuit using a two-stage full-wave multiple booster circuit that further boosts the voltage. By using the Cockcroft-Walton circuit, the high-voltage transformer is downsized, and as a whole is a small and light inverter type An X-ray high voltage device can be constructed.

  The two-stage full-wave multiple booster circuit includes a voltage maintaining capacitor for boosting to a double voltage while maintaining a peak value of the output voltage of the high-voltage transformer for a period longer than the period of the operating frequency of the inverter circuit. The voltage maintenance capacitor is composed of two diode full bridge circuits connected in series to convert the voltage maintained to a DC voltage and a smoothing capacitor to smooth the output voltage of the two diode full bridge circuits. The smoothing capacitor includes two sets of capacitors connected in series corresponding to the two diode full bridge circuits, and the smoothing capacitor is connected between the anode and the cathode of the anode grounded X-ray tube.

In the X-ray high voltage apparatus having such a configuration, the ripple of the tube voltage applied between the anode and the cathode of the X-ray tube needs to be several percent or less in order to obtain a high quality captured image. .
The capacitance of the smoothing capacitor of the two-stage full-wave multiple booster circuit is determined by the required ripple value of the tube voltage, and the magnitude of this ripple is the load of the inverter type X-ray high voltage device X It is determined by the X-ray condition that minimizes the resistance between the anode and cathode of the tube.
This X-ray condition is an imaging condition in which the tube voltage is minimum and the tube current is maximum. In the case of an X-ray CT apparatus, for example, the tube voltage is 80 kV, the tube current is 800 mA, and the X-ray tube is connected between the anode and cathode. The equivalent load resistance is 100kΩ.

  Here, the operating frequency of the inverter circuit is 40 kHz, the equivalent load resistance between the anode and cathode of the X-ray tube as a load is 100 kΩ, and the capacitance of the smoothing capacitor connected in parallel with the equivalent load resistance is 10 nF ( (The smoothing capacitor consists of two sets of capacitors connected in series corresponding to two diode full-bridge circuits, and each of these smoothing capacitors has a capacitance of 20 nF.) The constant is 1ms (= 100kΩ × 10nF). When the output voltage of the Cockcroft-Walton circuit is simply considered to be discharged by the equivalent load resistance, the ripple of the voltage discharged at 25 μs, which is one cycle of the operating frequency of the Cockcroft-Walton circuit, that is, the tube The voltage ripple is 2.4% (= 1-exp (-25μs / 1ms).

On the other hand, the withstand voltage of the smoothing capacitor is determined by the voltage doubled by the Cockcroft-Walton circuit. For example, in the case of an anode ground type, the withstand voltage is a voltage obtained by dividing the maximum rated tube voltage by the voltage doubled.
That is, in the case of the two-stage full-wave multiple booster circuit that boosts twice as disclosed in Patent Document 1, the two smoothing capacitors connected in series with respect to the maximum rated tube voltage 150 kV are connected to both ends. In this case, a voltage of 75 kV is applied.

  In this way, when the rated voltage is 75 kV and a 20 nF capacitor, it becomes very large, and if this type of capacitor is used for all capacitors including the voltage maintaining capacitor of the Cockcroft-Walton circuit as in Patent Document 1, the above-mentioned high The voltage generator becomes large, and it is difficult to further reduce the size and weight.

  In addition, by increasing the voltage doubler of the Cockcroft-Walton circuit, the withstand voltage of the voltage maintaining capacitor and the smoothing capacitor can be reduced, resulting in a smaller size. For this reason, the number of voltage doublers cannot be increased unnecessarily.

  An object of the present invention is to provide an inverter type X-ray high voltage apparatus using a Cockcroft-Walton circuit that can rapidly increase the tube voltage, reduce the tube voltage ripple, and can be reduced in size and weight. It is in.

The above object is achieved by the following means. That is, a DC power supply, DC / AC conversion means for converting the output voltage of the DC power supply to an AC voltage of a predetermined frequency, a high voltage transformer for boosting the AC voltage converted by the DC / AC conversion means, in the inverter type X-ray high voltage apparatus having a Cockcroft-Foruton circuit for converting further boosted by the DC voltage the output voltage of the high voltage transformer, keep the peak value of the output voltage before Symbol high-voltage variable voltage divider The capacitance of the smoothing capacitor that smoothes the output voltage of the Cockcroft-Walton circuit is made larger than the capacitance of the voltage maintaining capacitor.

According to the present invention, since the required tube voltage ripple is satisfied, and the voltage maintaining capacitor and the smoothing capacitor of the Cockcroft-Walton circuit are set to appropriate rated voltage and electrostatic capacity corresponding to the respective purposes, An inverter type X-ray high voltage device that is lightweight can be provided.
By mounting this compact and lightweight inverter type X-ray high voltage device on the scanner of the X-ray CT device, it will contribute to further increase in scanning speed.

Hereinafter, preferred embodiments of an inverter type X-ray high voltage apparatus of the present invention will be described in detail with reference to the accompanying drawings.
Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiments of the present invention, and the repetitive description thereof will be omitted.

First Embodiment
FIG. 1 is a circuit configuration diagram of an inverter type X-ray high voltage apparatus according to a first embodiment of the present invention. This inverter type X-ray high-voltage device includes a DC power source 1, an inverter circuit (DC / AC converting means) 2 that converts the voltage of the DC power source 1 into an AC voltage of a predetermined frequency, and an AC voltage of the inverter circuit 2. And a two-stage full-wave multiple-type Cockcroft-Walton circuit 4 that boosts the voltage of the high-voltage transformer 3 to a double voltage and converts it to a DC voltage, The output voltage of the two-stage full wave multiple type Cockcroft-Walton circuit 4 is applied between the anode 5a and the cathode 5b of the anode grounded X-ray tube 5 to generate X-rays. Among these, the high voltage transformer 3 and the two-stage full wave multiple type Cockcroft-Walton circuit 4 constitute a high voltage generator 6.

  The inverter type X-ray high voltage device configured as described above is a tube voltage feedback control means for detecting a tube voltage of the anode grounded X-ray tube 5 and controlling it to a set tube voltage, and the anode grounded type It is common to control the tube voltage and the tube current so that they become set values by including a tube current feedback control means for detecting the tube current of the X-ray tube 5 and controlling it so that the tube current is set. However, these control means are omitted in FIG. 1 because they are not directly related to the constituent elements for achieving the object of the present invention.

  The DC power supply 1 may be in any form such as a circuit form for converting a commercial power supply voltage (not shown) into a DC voltage and outputting it, or a DC power supply using a battery. The circuit form for converting the commercial power supply voltage into a DC voltage is also a form in which the commercial power supply voltage is full-wave rectified by a full-wave rectifier circuit, or the DC voltage obtained by the full-wave rectification is adjusted by a chopper circuit. It is not limited to the conversion form, such as a form or a form in which the full-wave rectifier circuit has a voltage variable function.

The inverter circuit 2 receives a DC voltage output from the DC power supply 1, converts it to a high-frequency AC voltage, and outputs it. The inverter circuit 2 is controlled by an inverter control circuit (not shown) so that the tube voltage applied from the high voltage generator 6 to the X-ray tube becomes a target value.
The high voltage transformer 3 boosts the AC voltage output from the inverter circuit 2, and the primary winding is on the output side of the inverter circuit 2 and the secondary winding is a two-stage full-wave multiple type. It is connected to the input side of the Cockcroft-Walton circuit 4.

  The two-stage full-wave multiple-type Cockcroft-Walton circuit 4 has the same circuit configuration as FIG. 1 disclosed in Patent Document 1 (International Publication No.WO2004 / 103033), and uses a capacitor and a diode. The output voltage of the high voltage transformer 3 is converted to a double DC high voltage. The configuration includes a first full-wave rectification booster circuit 4a composed of capacitors 411a, 411b, 412 and diodes 413a, 413b, 414a, 414b, capacitors 421a, 421b, 422 and diodes 423a, 423b, 424a, 424b. The second full-wave rectification booster circuit 4b is configured to connect a negative DC output terminal of the first full-wave rectification booster circuit 4a and a positive DC output terminal of the second full-wave rectification booster circuit 4b. Configured.

  The first full-wave rectification booster circuit 4a configured in this way is configured to output the peak value of the output voltage of the high-voltage transformer 3 during the period longer than the period determined by the operating frequency of the inverter circuit 2 by the capacitors 411a and 411b. The voltage is maintained by the first voltage maintaining means, and the maintained voltage is full-wave rectified by the first full-wave rectifier circuit including the diodes 413a, 413b, 414a, and 414b. Smoothing is performed by the first smoothing means including the capacitor 412. Similarly, the second full-wave rectification booster circuit 4b is configured to convert the peak value of the output voltage of the high-voltage transformer 3 into capacitors 421a and 421b for a period longer than the period determined by the operating frequency of the inverter circuit 2. 2 is maintained by the second voltage maintaining means, and the maintained voltage is full-wave rectified by a second full-wave rectifier circuit including diodes 423a, 423b, 424a, and 424b, and the full-wave rectified DC voltage is supplied from the capacitor 422. Smoothing is performed by the second smoothing means.

Then, the direct current voltage smoothed by the first smoothing means and the direct current voltage smoothed by the second smoothing means are added, and this added voltage is used as a tube voltage for the anode 5a of the anode-grounded X-ray tube 5. And the cathode 5b.
That is, the tube voltage is a voltage boosted to a voltage twice the peak value of the output voltage of the high voltage transformer 3.

  Thus, the high voltage generator 3 is constituted by the high voltage transformer 3 and the two-stage full-wave multiple-type Cockcroft-Walton circuit 4. The high voltage generator 6 boosts the high frequency AC voltage converted by the inverter circuit 2 to obtain a rated tube voltage of 150 kV.

  In the inverter type X-ray high voltage apparatus configured as described above, the peak value of the output voltage of the high voltage transformer 3 is the first and second smoothing means every half cycle of the operating frequency of the inverter circuit 2. Since the smoothing capacitors 412 and 422 are charged, the value of the tube voltage ripple is determined by the capacitance of the smoothing capacitors 412 and 422. Accordingly, capacitors (hereinafter referred to as voltage maintaining capacitors) 411a, 411b, 421a, 421b as the voltage maintaining means are output voltages of the high voltage transformer 3 only for a period longer than a period determined by the operating frequency of the inverter circuit 2. Therefore, the electrostatic capacity of the voltage maintaining capacitors 411a, 411b, 421a, 421b is reduced by the static capacitors 412, 422 for reducing the tube voltage ripple below the target value as in the conventional case. It need not be the same value as the capacitance.

Therefore, a simulation was performed to obtain appropriate capacitance and withstand voltage of the voltage maintaining capacitors 411a, 411b, 421a, and 421b and the smoothing capacitors 412 and 422 for setting the tube voltage ripple to 1.5% or less of the target.
The software used for the simulation is a simulator of an electric circuit and an electronic circuit, and is software called SPICE (Simulation Program with Integrated Circuit Emphasis) that reproduces the analog operation of the circuit.

  The simulation is performed on the circuit shown in FIG. 1, and the elements of the circuit are a full-bridge inverter circuit 2 (40 kHz, voltage 700 V of DC power supply 1), a high voltage transformer 3, a grounded anode X-ray tube 5, and a diode 413a. 413b, 414a, 414b first full wave rectifier circuit and diodes 423a, 423b, 424a, 424b second full wave rectifier circuit, voltage maintaining capacitors 411a, 411b, 421a, 421b, smoothing capacitors 412, 422, anode The load resistance value of the grounded X-ray tube 5 is 100 kΩ at an imaging condition of 80 kV and 800 mA that is the minimum load resistance of the X-ray CT apparatus.

As a result of simulation based on these circuit elements and conditions, in order to reduce the tube voltage ripple to 1.5% or less, a two-stage full-wave multiple type connected in parallel to the anode grounded X-ray tube 5 is used. It has been found that the capacitance of the smoothing capacitors 412 and 422 on the output side of the Cockcroft-Walton circuit needs to be 10 nF or more.
That is, since the smoothing capacitors 412 and 422 are connected in series, when the maximum rated tube voltage value is 150 kV, the smoothing capacitors 412 and 422 have a rated voltage of 75 kV or more and a capacitance of 10 nF or more, respectively.

  Smoothing capacitors 412 and 422 of this specification can be realized, for example, by configuring two capacitors of rated voltage 40 kV and 10 nF as two series and two parallel, respectively, and the capacitor of this specification is voltage maintaining capacitors 411a, 411b, When used also for 421a and 421b, the two-stage full-wave multiple-type Cockcroft-Walton circuit 4 becomes very large.

  Therefore, when the electrostatic capacitances of the smoothing capacitors 412 and 422 are set to 1, the first voltage maintaining capacitors 411a and 411b, the second voltage maintaining capacitors 421a and 421b, and the smoothing capacitors 412 and 422 are normalized in the first case. FIG. 2 to FIG. 5 show the results obtained by simulation of the relationship between the second voltage maintaining capacitor, the smoothing capacitor, and the tube voltage ripple.

  FIG. 2 shows the relationship between the first voltage maintaining capacitors 411a and 411b and the tube voltage ripple. The first voltage maintaining capacitors 411a and 411b have smaller tube voltage ripples as their capacitances are smaller. However, when the normalized value of the first voltage maintaining capacitors 411a and 411b is 0.4 or less, the peak value of the output voltage of the high voltage transformer 3 can be maintained for a period longer than the period determined by the operating frequency of the inverter circuit 2. Become. In other words, since it becomes impossible to boost the voltage to the double voltage, the normalized value of the first voltage maintaining capacitors 411a, 411b is preferably 0.5 or more, the normalized value of the capacitance of the voltage maintaining capacitors 411a, 411b 0.5 is an appropriate value.

  FIG. 3 shows the relationship between the second voltage maintaining capacitors 421a and 421b and the tube voltage ripple. The second voltage maintaining capacitors 421a and 421b have smaller tube voltage ripples as their capacitance increases, and can be boosted to a double voltage, but this is not preferable in terms of miniaturization. In this case, although omitted in FIG. 3, if the normalized value is 0.1 or more, voltage doubler is possible, so the normalized values of the second voltage maintaining capacitors 421a and 421b have a margin from the viewpoint of miniaturization. 0.2 is desirable, and 0.2 is an appropriate value for the normalized capacitance value of the voltage maintaining capacitors 421a and 421b.

4 shows the capacitances of the smoothing capacitors 412 and 422 when the normalized value of the capacitance of the first voltage maintaining capacitor is 0.5 and the normalized value of the capacitance of the second voltage maintaining capacitor is 0.2. And tube voltage ripple.
Since the normalized value of the smoothing capacitors 412 and 422 for setting the tube voltage ripple to 1.5% or less of the target is 1.0 or more, the normalized value of the capacitance of the smoothing capacitors 412 and 422 is taken into consideration for downsizing. 1.0 is an appropriate value.

The first voltage maintaining capacitor and the second voltage maintaining capacitor maintain the peak value of the output voltage of the high voltage transformer 3 only for a period longer than the operation cycle determined by the operation frequency of the inverter circuit 2. In addition, charge and discharge are repeated every half cycle of the operation cycle of the inverter circuit 2.
For this reason, it is required to make it possible to use a capacitor with a small allowable loss by reducing the ripple voltage of the capacitor as much as possible.

FIG. 5 shows the relationship between the capacitances of the first and second voltage maintaining capacitors and the ripple voltage of the capacitors.
From this simulation result, the ripple voltage of the first voltage maintaining capacitor has a normalized value of the capacitance of the capacitor of 0.5 or more, and the ripple voltage of the second voltage maintaining capacitor has the normalized value of the capacitance of the capacitor. From the point of view of ripple voltage, it can be seen that the value of the capacitance is appropriate from 0.2 or more.

From the above simulation results, the following was found.
(1) The charge / discharge current of the smoothing capacitors 412 and 422 on the output side of the Cockcroft-Walton circuit connected in parallel between the anode and the cathode of the X-ray tube 5, that is, the tube voltage ripple, is the tube voltage, tube, which is the imaging condition It depends on the current and is not affected by the other first and second voltage maintaining capacitors 411a, 411b, 421a, 421b.

  (2) Even if the capacitances of the second voltage maintaining capacitors 421a and 421b are set to 1/5 of the capacitance of the smoothing capacitor, the voltage doubler boosting function can be sufficiently exhibited.

  (3) For the first voltage maintaining capacitors 411a and 411b, only half the voltage of the smoothing capacitors 412 and 422 and the second voltage maintaining capacitors 421a and 421b are applied, so the first voltage maintaining capacitors 411a and 411b The rated voltage of 411b may be ½ of the rated voltage of the smoothing capacitors 412 and 422 and the second voltage maintaining capacitors 421a and 421b.

  (4) Since the smoothing capacitors 412 and 422 require a relatively large capacitance in order to reduce the tube voltage ripple, the capacitors are connected in parallel to ensure the necessary capacitance. On the other hand, when the number of capacitors connected in parallel increases, the charge / discharge current share per capacitor decreases, and a large-capacity capacitor with relatively large loss can be used.

  (5) Further, the second voltage maintaining capacitors 421a and 421b do not need to be connected in parallel because the capacitance is small. For this reason, sharing of charge / discharge current is increased, but it is not necessary to have a large capacitance, so it is possible to use a small capacitor using a low-loss film.

  (6) Furthermore, for the first voltage maintaining capacitors 411a and 411b, the rated voltage can be set to 40 kV, which is 1/2 of the rated voltage 80 kV of the other capacitors 412, 422, 421a, and 421b.

Summarizing the above simulation results, the rated voltage and capacitance of the voltage maintaining capacitor for voltage doubler of the Cockcroft-Walton circuit and the smoothing capacitor for smoothing the tube voltage are not the same as in the past, but appropriate values respectively. Therefore, it can be said that further miniaturization of the high-voltage device is possible.
Specifically, the smoothing capacitors 412 and 422 have a rated voltage V and a capacitance C, whereas the first voltage maintaining capacitors 411a and 411b have a rated voltage V / 2, a capacitance C / 2, a first capacitance The voltage maintaining capacitors 421a and 421b of 2 have the rated voltage V and the capacitance C / 5, so that the first voltage maintaining capacitors 411a and 411b have a rated voltage of 1/2 and the smoothing capacitors 412 and 422, The capacitance can be reduced to 1/2 and the second voltage maintaining capacitors 421a and 421b can be reduced in size by reducing the capacitance to 1/5.

As described above, according to the first embodiment of the present invention, the tube voltage ripple required is satisfied, and the voltage maintaining capacitor and the smoothing capacitor of the Cockcroft-Walton circuit are appropriately rated for each purpose. Since the capacitance is used, a small and lightweight inverter type X-ray high voltage device can be provided.
By mounting this compact and lightweight inverter type X-ray high voltage device on the scanner of the X-ray CT device, it will contribute to further increase in scanning speed.

<< Second Embodiment >>
FIG. 6 is a circuit configuration diagram of an inverter type X-ray high voltage apparatus according to the second embodiment of the present invention.
This inverter type X-ray high voltage apparatus is the same as the circuit of FIG. 1 except for the Cockcroft-Walton circuit 7 that boosts the output voltage of the high voltage transformer 3 by n times. A voltage maintaining capacitor for maintaining the peak value of the output voltage of the high voltage transformer 3 and a smoothing capacitor for smoothing the tube voltage for a period longer than the operation cycle determined by the configuration of the Walton circuit 7 and the operation frequency of the inverter circuit 2 Will be described.

  The Cockcroft-Walton circuit 7 includes diodes 713, 723,... 7n3 and 714 for rectifying the peak value of the output voltage of the high voltage transformer 3 for each cycle of the output voltage of the high voltage transformer 3. 7n4 and capacitors 711, 712, 721, 722,... 7n1, 7n2 for maintaining the peak value of the output voltage of the high voltage transformer 3, and the capacitors 712, 722 , 7n2 is connected in parallel between the anode 5a and the cathode 5b of the anode grounded X-ray tube 5 as a load and has a function as a smoothing capacitor for smoothing the tube voltage.

  If the voltage doubler number of the Cockcroft-Walton circuit 7 is increased, the response of the tube voltage is slowed down.

As for the inverter type X-ray high voltage apparatus configured in this way, as in the circuit of FIG. 1, in order to keep the tube voltage ripple below the target value, the anode 5a of the anode grounded X-ray tube 5 is connected between the anode 5a and the cathode 5b. .., 7n2 connected in parallel to the capacitors 712, 722,... 7n2 must be larger than the capacitances of the capacitors 711, 721,.
Further, the rated voltage of the first-stage capacitor 711 may be ½ of the rated voltage of the other capacitors 712, 721, 722, 7n1, and 7n2.

  Thus, according to the second embodiment, even if a half-wave n-fold type cockcroft-Walton circuit is used for the cockcroft-Walton circuit, the voltage maintaining capacitor and the smoothing capacitor of the cockcroft-Walton circuit correspond to the respective purposes. Therefore, it is possible to provide a small and light inverter type X-ray high voltage device that satisfies the required tube voltage ripple.

<< Third Embodiment >>
The inverter type X-ray high voltage apparatus according to the present invention is not only applied to an X-ray generator using an anode grounded X-ray tube as an X-ray tube, but an X-ray using a neutral point grounded X-ray tube. It can also be applied to a generator.

FIG. 7 is a circuit configuration diagram of an X-ray generator using an inverter type X-ray high voltage apparatus according to a third embodiment of the present invention for a neutral grounded X-ray tube.
This inverter type X-ray high-voltage device divides the secondary winding of the high-voltage transformer 3 ′ into two, 3a ′ and 3b ′, and one of the secondary windings 3a ′ has the half-wave type shown in FIG. The same configuration as the cockcroft-Walton circuit 7 is connected to the first cockcroft-Walton circuit 9a whose polarity is inverted, and the other secondary winding 3b ′ has the same configuration as the half-wave type cockcroft-Walton circuit 7 in FIG. The second cockcroft-Walton circuit 9b is connected to form the cockcroft-Walton circuit 9.
Then, the negative output terminal of the first cockcroft-Walton circuit 9a and the positive output terminal of the second cockcroft-Walton circuit 9b are connected to ground the connection point, and the first cockcroft-Walton circuit 9a The positive output terminal of the X-ray tube 8 and the anode 8a of the X-ray tube 8, and the negative output terminal of the second cockcroft-Walton circuit 9b and the cathode 8b of the X-ray tube 8 are connected to the neutral point grounding type. Configure X-ray generator.

  In the neutral-point grounded X-ray generator configured in this way, as in the second embodiment, since the response of the tube voltage is delayed when the number of double voltages of the Cockcroft-Walton circuit 9 is increased, this Increase the number of voltage doublers within the allowable range of response performance.

As for the inverter type X-ray high voltage apparatus configured as described above, in order to keep the tube voltage ripple below the target value as in the circuit of FIG. 1, the anode 8a of the X-ray tube 8 is connected to the ground. Capacitors 912a, 922a, ..., 9n2a connected in parallel and capacitors 912b, 922b, ..., 9n2b connected in parallel between the cathode 8b and the ground
, 9n1a and 911b, 921b,..., 9n1b need to be larger than the other capacitors 911a, 921a,.
In addition, the rated voltages of the first stage capacitors 911a and 911b are the other capacitors 912a, 922a, ..., 9n2a, 912b, 922b, ..., 9n2b and 921a, ..., 9n1a and 921b, ..., 1/2 of the rated voltage of 9n1b is sufficient.

  Thus, according to the third embodiment, the cockcroft-Walton circuit is also used in the neutral-point grounded X-ray generator configured using two half-wave cockcroft-Walton circuits in the cockcroft-Walton circuit. The voltage maintaining capacitor and the smoothing capacitor are made to have the appropriate rated voltage and capacitance corresponding to their respective purposes, so that a compact and lightweight inverter-type X-ray high-voltage device that satisfies the required tube voltage ripple is achieved. Can be provided.

The inverter type X-ray high voltage apparatus of the present invention is not limited to the Cockcroft-Walton circuit used in the above embodiment.
The Cockcroft-Walton circuit has various circuit forms, and the capacitance of the Cockcroft-Walton circuit capacitor connected in parallel between the anode and cathode of the X-ray tube is made larger than that of other capacitors. Modifications can be made as appropriate within the scope of the technical idea of the present invention.
Further, the grounding method of the X-ray generator using the inverter type X-ray high-voltage device according to the present invention is not limited, and can be applied to any grounding method of anode grounding type and neutral grounding type. .

  Furthermore, the inverter type X-ray high voltage apparatus of the present invention is not limited to the X-ray CT apparatus, and can be applied to any X-ray imaging apparatus (including fluoroscopy), especially moving. By using the small and lightweight inverter X-ray high-voltage device of the present invention for the round-trip car that goes around the hospital and the in-vehicle examination car that is installed in the car and performs group examination, the installation space is reduced and the weight is reduced by downsizing. It contributes to the improvement of mobility by the conversion.

1 is a circuit configuration diagram of an inverter type X-ray high voltage apparatus according to a first embodiment of the present invention. The figure which shows the relationship between the electrostatic capacitance of the 1st voltage maintenance capacitor | condenser and tube voltage ripple by the simulation in the circuit of FIG. The figure which shows the relationship between the electrostatic capacitance of the 2nd voltage maintenance capacitor | condenser and tube voltage ripple by the simulation in the circuit of FIG. FIG. 2 is a diagram showing the relationship between the capacitance of a smoothing capacitor and tube voltage ripple by simulation in the circuit of FIG. FIG. 3 is a diagram showing the relationship between the capacitances of the first and second voltage maintaining capacitors and the ripple voltage of the capacitors by simulation in the circuit of FIG. The circuit block diagram of the inverter type | mold X-ray high voltage apparatus by the 2nd Embodiment of this invention. The circuit block diagram of the inverter type | mold X-ray high voltage apparatus by the 3rd Embodiment of this invention.

Explanation of symbols

  1 DC power supply, 2 Inverter circuit (DC / AC conversion means), 3 High voltage transformer, 3 ′ High voltage transformer with two secondary windings, 4 Two-stage full-wave multiple-type Cockcroft-Walton circuit, 4a 1st full-wave rectifier booster circuit, 4b 2nd full-wave rectifier booster circuit, 5 anode grounded X-ray tube, 6 high voltage generator, 7 half-wave n-fold Cockcroft-Walton circuit, 8 neutral point grounded type X-ray tube, 9 half-wave n-fold Cockcroft-Walton circuit using a Cockcroft-Walton circuit, 411a and 411b capacitors as first voltage maintaining means, 421a and 421b capacitors as second voltage maintaining means, 412 Capacitor as first smoothing means, 422 Capacitor as second smoothing means

Claims (1)

A DC power supply, DC / AC conversion means for converting the output voltage of the DC power supply into AC voltage of a predetermined frequency, a high-voltage transformer for boosting the AC voltage converted by the DC / AC conversion means, In an inverter type X-ray high-voltage apparatus comprising a Cockcroft-Walton circuit that further boosts the output voltage of the voltage transformer and converts it to a DC voltage,
Before Symbol capacitance of the smoothing capacitor for smoothing an output voltage of the Cockcroft-Walton circuit is C, and when the rated voltage is V,
Among the voltage maintaining capacitors that maintain the peak value of the output voltage of the high voltage transformer, the capacitance of the first voltage maintaining capacitor connected to the output winding of the high voltage transformer is C / 2, the rated voltage Is V / 2,
An inverter type X-ray high-voltage apparatus characterized in that a capacitance of other voltage maintenance capacitors excluding the first voltage maintenance capacitor among the voltage maintenance capacitors is C / 5 and a rated voltage is V.

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