JP2016038965A - X-ray device and control method for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable reduction of a load of an X-ray tube device.SOLUTION: An X-ray device has an X-ray tube device having a motor for rotating a rotational anode, an X-ray detector for detecting X-ray transmitted through a subject, a display unit for displaying an X-ray image, an input unit for inputting a schedule of X-ray imaging, or tube voltage and tube current to be supplied to the X-ray tube device, a control device for controlling the rotational speed of the motor, and a rotational driving unit for supplying AC power to the motor. The control device calculates a target rotational speed or a target torque according to the schedule of the X-ray imaging or the tube voltage and tube current to be supplied to the X-ray tube device, calculates d-axis current and q-axis current according to the target rotational speed or the target toque, and outputs a control signal for controlling the rotational driving unit based on the vector calculation output and the rotational speed of the motor. The rotational driving unit drives the motor according to the control signal from the control device.SELECTED DRAWING: Figure 5

Description

  The present invention relates to an X-ray apparatus that obtains an X-ray image of a subject by irradiating the subject with X-rays.

  An X-ray apparatus is an apparatus that obtains a tomographic image of a subject by irradiating the subject with X-rays, and has an X-ray source for irradiating the subject with X-rays. The X-ray source is provided with an X-ray tube for generating X-rays. There are various types of X-ray tubes, and one of them is a rotary anode type X-ray tube having a rotary anode.

  In a rotating anode type X-ray tube, an electron beam generated by a cathode collides with a rotating anode and generates X-rays. However, the actual condition is that the kinetic energy of the electron beam is not only converted to X-rays but also converted to heat, and the rate of conversion to heat is much higher than the rate of conversion to X-rays. When the electron beam continues to be concentrated on one point of the anode, the concentrated point of the anode is melted by heat, and thus the anode is rotated so that the position where the electron beam collides gradually moves. Such a technique is described in Patent Document 1, for example.

JP 2013-182664 A

In the rotary anode type X-ray tube (hereinafter referred to as an X-ray tube device), as described above, the anode is rotatably supported for the purpose of moving the electron beam collision position, and the electron beam collision position moves. The anode is rotated. As described above, since the anode is heated to a high temperature and disposed in a vacuum, the rotation support mechanism and the like operate under extremely severe conditions. For this reason, it is desirable to reduce the burden of the rotation support mechanism as much as possible, which leads to a long life of the X-ray tube apparatus. In addition, there is a great need for extending the life of X-ray tube devices. Note that Patent Document 1 does not mention reduction of the burden on the rotary anode X-ray tube.
The objective of this invention is providing the X-ray apparatus which can reduce the burden of the X-ray tube apparatus which an X-ray apparatus has more, and its control method.

  An X-ray apparatus according to the present invention includes an X-ray tube apparatus that has a rotary anode and a motor that rotationally drives the rotary anode and generates X-rays to be irradiated to the subject, and X-rays that have passed through the subject. An X-ray detector to be detected, a display unit for displaying an image based on image information detected by the X-ray detector, an X-ray imaging schedule, or a tube voltage or tube current to be supplied to the X-ray tube device is input. An input unit that controls the rotational speed of the motor, and a rotation drive unit that supplies AC power to the motor. The control device includes the X-ray imaging schedule or the X-ray tube device. A vector calculation unit that calculates a target rotation speed or target torque according to a tube voltage or a tube current supplied to the power supply, and calculates a d-axis current and a q-axis current according to the target rotation speed or the target torque. A control signal for controlling the rotation drive unit is output based on the output of the vector calculation unit and the rotation speed of the motor, and the rotation drive unit drives the motor according to the control signal from the control device. And

  ADVANTAGE OF THE INVENTION According to this invention, the X-ray apparatus which can further reduce the burden of an X-ray tube apparatus, and its control method can be obtained.

It is explanatory drawing for demonstrating the structure of the X-ray apparatus which is one Example of this invention. It is explanatory drawing explaining the outline | summary of the X-ray control apparatus and X-ray tube apparatus which are one Example of this invention. It is explanatory drawing explaining an example of the structure of an X-ray tube apparatus. It is explanatory drawing explaining an example of the structure of the rotation support part of an X-ray tube apparatus. It is a control block diagram explaining the structure of the X-ray control part of an X-ray control apparatus. It is a flowchart explaining the procedure of X-ray imaging. It is a flowchart explaining the procedure of the X-ray imaging which improved the responsiveness.

  An embodiment of an X-ray apparatus to which the present invention is applied (hereinafter referred to as an example) will be described below with reference to the drawings. In addition, about the structure and procedure described in drawing, the same code | symbol is attached | subjected with respect to the structure and procedure which perform the substantially same effect | action, and the description of the same code | symbol and procedure may be abbreviate | omitted. . The problems to be solved and typical effects related to the present invention are described in the column of problems to be solved by the invention and the effect of the invention, but the embodiments described below are to be solved by the invention. However, the present invention is not limited to the contents of the problem column and the effect column of the invention, but can be solved even with other problems, and can be achieved with effects other than those described above. These problems solved by the embodiments and the effects achieved by the embodiments will be described in the following description of the embodiments.

  In the present specification, the term “operation” includes not only algebraic calculation but also a method of obtaining a preferable value by storing data in advance as a database and searching the database according to a parameter, for example.

1. Description of the overall configuration of an embodiment of an X-ray apparatus to which the present invention is applied The present invention examines not only an X-ray apparatus in medical equipment such as an X-ray computed tomography (hereinafter referred to as X-ray CT) but also industrial products. Therefore, the present invention can be applied to an X-ray apparatus other than a medical device. When the present invention is applied to an X-ray apparatus for medical equipment, a greater effect can be obtained, and further, the market needs for the X-ray apparatus for medical equipment are so great that the present invention is applied to an X-ray apparatus for medical equipment, particularly X-ray CT. Is described below.

  FIG. 1 is an explanatory view for explaining the configuration of an X-ray CT apparatus 100 as an embodiment to which the present invention is applied. The X-ray CT apparatus 100 is an apparatus that generates X-ray images of the subject 102 by irradiating the subject 102 with X-rays, detecting the intensity of the X-ray transmitted through the subject 102. The X-ray CT apparatus 100 irradiates the subject 102 with X-rays and detects the X-rays transmitted through the subject 102, and performs operations on the entire X-ray CT apparatus 100 including the gantry 120. And a control table 200 having a system control device 212 for performing various processes and controls for performing X-ray imaging, and a bed on which the subject 102 is placed and the subject 102 is moved according to the X-ray imaging schedule 150. The detection result detected by the X-ray detector 140 provided in the gantry 120 is sent as image information 348 to the image processing unit 214 provided in the control console 200 and processed by the image processing unit 214, and the X-ray image is converted into an X-ray image. Generated. The X-ray image is displayed on the display unit 224 of the input / output device 218, for example.

  The gantry 120 has a turntable 124 in which an opening 122 for placing the subject 102 placed on the bed 150 is formed. The rotating disk 124 has an X-ray tube device 400 for generating X-rays to be irradiated to the subject 102 and the X-rays generated by the X-ray tube device 400 in the state of a fan-shaped X-ray beam having an angle α. A collimator 130 for irradiating the subject 102 and an X-ray detector 140 for detecting X-rays transmitted through the subject 102 are provided. The X-ray detector 140 is fixed at a position opposite to the X-ray tube device 400 and the collimator 130 with the subject 102 interposed therebetween. When the turntable 124 rotates, the angle and position of the X-ray beam applied to the subject 102 change. A three-dimensional X-ray image can be generated by irradiating an X-ray beam while moving the subject 102 in the body axis direction at a predetermined speed and rotating the rotating disk 124. In FIG. 1, since each configuration is schematically described, the entire X-ray control device 302 is described as if it is disposed not on the rotating platen 124 but on a portion where the gantry 120 does not rotate. It is desirable that the drive unit related to the X-ray tube apparatus 400 in the control device 302 is disposed in the vicinity of the X-ray tube apparatus 400. For this reason, the drive unit is provided on the rotating disk 124.

When the operator sets parameters of the tube current and tube voltage of the X-ray tube apparatus 400 related to the imaging schedule and the X-ray intensity irradiated to the subject 102 from the input unit 222 of the input / output device 218 of the control console 200, Are stored in the storage device or storage device 216 of the system control device 212. A system control device 212 provided in the control console 200 sends control information 342 of the X-ray tube device 400 to the X-ray control device 302 based on the imaging schedule, tube current, and tube voltage parameters. The X-ray control device 302 follows the control information 342 from the system control device 212, and the tube current and tube voltage of the X-ray tube device 400, the filament current of the X-ray tube device 400, and the rotary anode 432 of the X-ray tube device 400. Control the rotation speed, etc.
The system control device 212 sends control information 344 for controlling the rotation position and rotation speed of the turntable 124 to the gantry control device 126 according to the shooting schedule and the operation by the operator, and the gantry control device 126 rotates the rotation position of the turntable 124. And control the rotation speed. Further, the system control device 212 sends control information 346 for moving the subject 102 to the bed control device 152 according to the imaging schedule. The bed control device 152 controls the position of the bed 150 so that the subject 102 moves at a speed instructed in the body axis direction, for example. The movement speed of the subject 102 and the rotation speed of the turntable 124 are controlled, and the X-ray tube device 400 is further controlled, so that the subject 102 is irradiated with X-rays on the spiral, and the subject is examined. Three-dimensional image information 348 can be obtained for 102, and a three-dimensional X-ray image can be generated.

  The X-rays irradiated to the subject 102 and transmitted through the subject 102 are detected by the X-ray detector 140, and the detection result is sent to the data collection device 142, and the control table as image information 348 is sent from the data collection device 142. 200 is sent to an image processing unit 214 provided in 200, and an image is generated in the image processing unit 214 and displayed on, for example, the display unit 224 of the input / output device 218 provided in the control console 200 or stored in the storage device 216. Or

  The control console 200 has an input / output device 218. The input / output device 218 has an input unit 222 for inputting a shooting schedule, shooting conditions, etc., or for giving various instructions, and further displays an input result. And a display unit 224 for displaying an input operation and displaying an X-ray image such as an imaging result. The control console 200 also includes a system control device 212, an image processing unit 214, and a storage device 216. The system control device 212 supports input to the input / output device 218, processing such as necessary display, and the X-ray control device 302, gantry control device 126, bed control device 152, bed control device 152 according to the input imaging schedule and imaging conditions, etc. Processing and instructions for controlling the data collection device 142, the image processing unit 214, the storage device 216, and the like are performed. By performing such processing, the system control device 212 controls the operation of the entire X-ray CT apparatus 100 based on various instructions and settings given by the operator on the control console 200, and performs X-ray imaging work. Carry out.

2. X-ray Irradiation and X-ray Detection When an operator inputs an imaging schedule and imaging conditions for performing X-ray imaging to the control console 200, the system controller 212 determines from the input imaging schedule and imaging conditions. An instruction for controlling the X-ray tube apparatus 400 is sent to the X-ray control apparatus 302, and a high voltage and current for generating X-rays are supplied to the X-ray tube apparatus 400 by the X-ray control apparatus 302. X-rays are generated by the tube device 400. The X-ray generated by the X-ray tube device 400 is irradiated from the collimator 130 to the subject 102 placed on the bed 150 in the state of an X-ray beam having a predetermined irradiation angle α. The X-ray transmitted through the subject 102 is detected by the X-ray detector 140, converted into an electric signal corresponding to the intensity of the X-ray, and sent to the data collection device 142 as X-ray transmission image data. The data collection device 142 collects transmission image data, converts it into a digital signal, and supplies it as image information 348 to the image processing unit 214 of the control console 200. The image processing unit 214 generates an X-ray image such as a tomographic image or a three-dimensional image of the subject 102 based on the image information 348 and is displayed on the input / output device 218 as image data by the system control device 212 and stored. Stored in device 216.

3. Description of X-ray Control Device 302 FIG. 2 is an explanatory diagram for explaining the outline of the X-ray control device 302 and the X-ray tube device 400. FIG. 3 is an explanatory view for explaining the structure of the X-ray tube apparatus 400, and FIG. 4 is an explanatory view for explaining an example of the structure of the rotation support portion 462 of the X-ray tube apparatus 400. Hereinafter, the configuration and operation of the X-ray control apparatus 302 will be described with reference to these drawings.

  The X-ray control device 302 includes a high voltage generator 320 for supplying a tube voltage 334 and a tube current 336 to the X-ray tube device 400, a filament driving unit 360 for controlling the filament current 362 of the X-ray tube device 400, A rotation drive unit 350 that controls the rotation speed of the rotary anode 432, and an X-ray control unit 600 that controls the high voltage generator 320, the filament drive unit 360, and the rotation drive unit 350 are provided. The high voltage generator 320 includes a converter 324, an inverter 326, and a high voltage generator 332 in order to supply the required tube voltage and flow the requested tube current.

  The high voltage generator 320 is supplied with a commercial AC voltage from a commercial AC power supply 322, and the converter 324 rectifies and boosts the supplied AC voltage to generate a boosted DC voltage. Inverter 326 receives the boosted DC voltage generated by converter 324 as an input in accordance with an instruction from X-ray control unit 600 and generates a high-frequency AC voltage. The high voltage generator 332 receives a high-frequency AC voltage from the inverter 326 and generates a high DC voltage. The high voltage positive voltage is applied to the rotating anode 432 and the negative voltage is applied to the cathode 416. A high DC voltage is supplied from the high voltage generator 332 to the X-ray tube apparatus 400. In order to maintain the voltage and current supplied from the high voltage generator 332 to the X-ray tube apparatus 400 at a set value, the tube voltage 334 and the tube current 336 are always detected and taken into the X-ray controller 600. It is. The X-ray control unit 600 performs feedback control so as to obtain a set value according to the detection result.

  The filament driving unit 360 supplies a filament current 362 to the filament for supplying thermoelectrons to the cathode 416 of the X-ray tube device 400 based on the power supplied from the AC power source 322. The filament current 362 output from the filament driving unit 360 is always detected and taken into the X-ray control unit 600, and feedback controlled. When the filament (not shown) of the X-ray tube apparatus 400 is heated by the filament current 362, thermoelectrons are emitted from the filament (not shown). The emitted thermoelectrons are accelerated by the tube voltage by the high voltage generator 332 applied between the cathode 416 and the rotating anode 432, become an electron beam having high kinetic energy, and the X-ray of the target 434 of the rotating anode 432. Collide with focus. The X-ray 414 is emitted from the target 434 by this collision. An extremely small amount, for example, about 1% of the kinetic energy of the electron beam accelerated by the tube voltage becomes X-ray generation energy, and the subject 102 is irradiated with X-rays from the X-ray tube device 400. The remaining kinetic energy of the electron beam is converted to heat. For this reason, the X-ray focal point where the electron beam of the target 434 of the rotating anode 432 collides becomes high temperature. It is necessary to prevent the X-ray focal point of the target 434 from being damaged by heat. As described in the following examples, for example, an HU value indicating the accumulated heat amount of the anode is calculated, and the temperature of the X-ray focal point is increased. Is calculated, and the rotational speed of the rotary anode 432 is calculated so that the temperature of the X-ray focal point where the electron beam collides does not exceed a prescribed temperature. The rotary anode 432 is rotationally driven by the rotational drive unit 350 at the calculated rotational speed. Since the rotation sensor is not provided, the rotation speed of the rotating anode 432 is not directly measured, but the current value supplied from the rotating anode 432 to the stator winding 452 is measured and the induction of the stator winding 452 is induced. The voltage is measured, the rotation speed of the rotary anode 432 is obtained by calculation, and feedback control is performed in the rotation drive unit 350 so that the rotation speed of the rotation anode 432 becomes the command speed by calculation. There are various methods for calculating the rotational speed of the rotary anode 432, and the present invention is not limited to this.

  Although the envelope 404 in the X-ray tube apparatus 400 is maintained in a vacuum, the outside of the X-ray tube apparatus 400 is filled with a cooling liquid. The cooling liquid circulates outside the X-ray tube apparatus 400, is guided to the cooling apparatus 500, cools the cooling liquid itself, and circulates outside the X-ray tube apparatus 400 again. For example, insulating oil is used as the cooling liquid, but in order to increase the cooling efficiency, it is preferable to use a liquid having a large specific heat, and water having a large specific heat may be used.

4). Description of X-ray tube device 400 As shown in FIGS. 2 and 3, the X-ray tube device 400 is an envelope in which the inside is maintained in a vacuum inside an X-ray tube container 402 filled with insulating oil or cooling water. 404 is provided. A cathode 416 is provided in an envelope 404 maintained in a vacuum, and the cathode 416 has a filament (not shown), and a filament current 362 is supplied from the filament driver 360 to a filament (not shown) via a connection terminal 418. The filament is heated and emits thermoelectrons. Note that many electrons can be emitted when the cathode 416 has a filament, but a cold cathode type that emits electrons by applying a strong electric field other than the generation of thermal electrons by heating may be used.

  Electrons emitted by heating or field emission are supplied via the connection terminal 418 or the like, and become an electron beam 412 accelerated by the tube voltage applied between the cathode 416 and the target 434, and are accelerated by the tube voltage. An electron beam 412 having a large kinetic energy collides with a target 434 provided on the rotating anode 432. X-rays 414 are generated by this collision. This X-ray is irradiated to the outside of the X-ray tube apparatus 400 from the radiation window 406 and the radiation window 408. In addition, in the application of the present invention, the basic configuration and the basic operation are the same regardless of whether electrons are emitted by heating or electrons are emitted by an electric field. In this specification, a configuration in which electrons are emitted by heating is a representative example. Explains.

  Since the tube voltage described above is applied between the cathode 416 and the target 434 of the rotating anode 432 with a polarity that makes the cathode 416 negative, the emitted electrons are accelerated into an electron beam 412. The electron beam 412 is focused by the focusing electric field and collides with the X-ray focal point of the target 434 of the rotating anode 432. X-rays 414 are generated from the X-ray focal point by the collision of the electron beam 412. The energy of the generated X-ray is determined by the tube voltage applied between the cathode 416 and the rotating anode 432. The X-ray dose generated also depends on the amount of electrons emitted from the cathode 416, and the amount of electrons emitted from the cathode 416 can be detected as a tube current 336. In order to control the X-ray dose, the tube current 336 and the tube voltage 334 are controlled to be set values.

  As described above, of the energy of the electron beam 412 that collides with the target 434, the rate of conversion to X-rays is only about 1%, and most of the remaining energy is heat. The X-ray focal point of the target 434 is heated by the energy of the electron beam 412. In order to prevent the X-ray focal point of the target 434 from overheating and melting, the rotating anode 432 rotates, and the X-ray focal point where the electron beam 412 collides always moves. The rotating anode 432 is fixed to a rotating shaft 424, and the rotating shaft 424 is rotatably held by a rotation support portion 462. Further, the rotation support portion 462 operates as a rotor of the motor, and a rotating magnetic field is generated by the stator winding 452 wound around the stator iron core 454, and the rotating cylinder of the rotation support portion 462 is generated by the rotating magnetic field generated by the stator winding 452. A rotational torque is generated in the portion 478, the rotating shaft 424 connected to the rotating cylindrical portion 478 rotates, and the rotating anode 432 fixed to the rotating shaft 424 by the fixing screw 482 rotates.

  An example of the rotation support portion 462 is shown in FIG. The fixed bearing 474 is fixed to the X-ray tube container 402 by fixing the fixing portion 472 to the X-ray tube container 402. The fixed bearing 474 has a cylindrical shape, and a rotary bearing portion 476 is provided therein. The cylindrical portion of the fixed bearing 474 and the rotary bearing portion 476 have a concentric arrangement relationship, and a rolling bearing 484 is provided between the inside of the fixed bearing 474 and the outside of the rotary bearing portion 476. A rotary bearing portion 476 is rotatably supported with respect to the fixed bearing 474. The rotary bearing portion 476 further has a rotary cylindrical portion 478. The rotating cylindrical portion 478 has a cylindrical shape and is disposed so as to face the stator core 454 so as to act as a rotor of the motor.

  When a three-phase alternating current is supplied from the rotation driving unit 350 (see FIG. 2) to the stator winding 452 wound around the stator core 454, a rotating magnetic field is generated. The rotation speed of the rotating magnetic field is determined by the frequency of the three-phase alternating current supplied from the rotation driving unit 350 and the number of poles of the stator winding 452. When the frequency of the supplied three-phase alternating current is increased, the rotation speed of the rotating magnetic field generated is increased according to the frequency. The rotating cylindrical portion 478 operates as a rotor, and a rotating torque is generated in the rotor by the rotating magnetic field. The rotating cylindrical portion 478 may act as an induction motor, or may be another type. However, it is desirable that the rotor has a simple shape from the viewpoint of the space of the rotating cylindrical portion 478 and the temperature environment.

  The rotating cylindrical portion 478 is made of an iron core, and, for example, the position of the q-axis among the d-axis and q-axis of the rotor, for example, every 90 degrees of electrical angle of the rotating cylindrical portion 478 so that reluctance torque is generated. A notch 480 is formed. With such a shape, a notch 480 is formed every 90 degrees of the electrical angle of the rotating cylindrical portion 478 acting as a rotor. By providing the notch 480, the magnetic resistance in the d-axis of the rotor and the magnetic resistance in the q-axis of the rotor are different. When a difference in magnetic resistance occurs between the d-axis and q-axis of the rotor, reluctance torque is generated with respect to the rotating magnetic field. In the above description, the notch is formed in the q-axis of the rotor. However, since the reluctance torque is generated according to the difference in magnetic resistance between the d-axis and the q-axis, the notch 480 is provided at a position corresponding to the d-axis. Even if formed, the same effect can be obtained.

  For example, a magnet torque can be generated by providing a permanent magnet corresponding to the d-axis of the rotating cylindrical portion 478. However, the permanent magnet has a problem that the holding force is lost when the temperature rises. By using a structure that rotates and generates rotational torque by the shape of the iron core without using a permanent magnet as in this embodiment, a motor having extremely strong characteristics against high temperatures can be configured. In addition, the shape is simple and it has the advantage that it is difficult to break down.

  The rotating cylindrical portion 478 that generates rotational torque as a rotor is fixed to and supported by the rotating bearing portion 476 and is connected to the rotating shaft 424 to which the rotating anode 432 is attached. The rotating anode 432 is rotated by the torque. The rotational speed of the rotating anode 432 can be controlled by the rotational speed of the rotating magnetic field generated by the stator core 454, and the rotational speed of the rotating magnetic field can be controlled by controlling the AC frequency of the stator core 454.

5. Description of motor driving operation The X-ray image capturing schedule and the set values of tube voltage and tube current related to the X-ray intensity input by the operator are set as control information 342 from the system controller 212 to the rotational speed calculation of the X-ray controller 600. Part 612. Further, in order to calculate the temperature and accumulated heat amount of the X-ray tube device 400, the elapsed time of X-ray irradiation, the elapsed time of X-ray irradiation stop, and the like are also sent from the system control device 212 to the rotation speed calculation unit 612. From these pieces of information, the rotation speed calculation unit 612 calculates the accumulated heat amount HU of the rotating anode 432 by calculation, and further calculates the temperature of the X-ray focal point of the target 434 by calculation. The rotational speed of the rotary anode 432 is calculated so that the temperature of the X-ray focal point of the target 434 does not exceed a predetermined temperature. The rotation speed is calculated by, for example, storing in the database 622 in advance the rotation speed using the stored heat amount HU, the set value of the tube voltage and tube current, the shooting schedule, and the like as parameters, and searching the database 622. May be. By doing so, it is possible to reduce the calculation load and realize accurate control.

  The calculated rotation speed of the rotary anode 432 is output from the rotation speed calculation unit 612 as a rotation speed command for rotating the rotation anode 432 or as a torque command for obtaining the calculated rotation speed, and the vector control unit 640. Is sent to the current vector calculation unit 642. The current vector calculation unit 642 calculates the d-axis current Id and the q-axis current Iq by calculation, and sends these calculation results to the voltage vector calculation unit 642. The rotating cylindrical portion 478 that operates as the stator winding 452 and the rotor operates as a motor 604 for rotating the rotating anode 432, and operates by three-phase AC power generated by the rotation driving unit 350. Both the current vector calculation unit 642 and the voltage vector calculation unit 648 perform vector calculations as vector calculation units, but the calculation unit 642 is referred to as a current vector calculation unit 642 in order to distinguish between the current vector calculation unit 642 and the voltage vector calculation unit 648. The calculation unit 648 will be referred to as a voltage vector calculation unit 648.

  The motor 604 has a high temperature and it is difficult to use a rotation angle sensor or the like, and the motor 604 is controlled by sensorless vector control. For example, a current supplied to the motor 604 in order to indirectly determine the rotation speed of the motor 604 is detected by the current sensor 658, converted into a rotation coordinate by the coordinate conversion unit 652, and the d-axis current Id and the q-axis current Iq are obtained. Desired. The rotational speed of the motor 604 can be obtained by the rotational speed computing unit 654 by a method such as obtaining a deviation between the obtained q-axis current Iq and the q-axis current Iq that is the computation result of the current vector computing unit 642. Note that the rotation speed calculation unit 654 may obtain the rotation speed by other methods, for example, from the voltage at the input end of the motor 604 and the detection result of the current sensor 658.

  The motor 604 may be a synchronous motor, but is controlled by slip control in this embodiment. The slip frequency calculation unit 644 calculates the slip frequency and adds the calculated slip frequency to the rotation speed calculated by the rotation speed calculation unit 654. The frequency is added by the device 656 and the added frequency is sent to the voltage vector calculation unit 648. The voltage vector calculation unit 648 generates a command signal to the rotation drive unit 350 that is an inverter based on the calculation result of the current vector calculation unit 642 and the frequency added by the adder 656, and the rotation drive unit 350 receives the command signal. Operates to convert the DC power supplied from the converter 324 into AC power and drive the motor 604. Note that a portion surrounded by a broken line in the vector control unit 640 in FIG. 5 shows a configuration for performing a vector operation for controlling the motor 604.

  In sensorless vector control, calculation errors are likely to occur during low-speed rotation, but the motor 604 that rotates the rotating anode 432 operates at a high rotational speed, such as several thousand to 10,000 revolutions per minute, and the motor load is relatively small. Suitable for sensorless vector control. The X-ray tube apparatus 400 is in a state where it is difficult to provide a rotation angle sensor. However, the sensorless vector control does not require a rotation angle sensor and is suitable for controlling the X-ray tube apparatus 400 in this respect.

  The bearing 484 illustrated in FIG. 4 is placed in a harsh environment such as being placed in a vacuum and being placed in a high temperature environment, and it is preferable to reduce the load on the bearing 484 as much as possible. Since the X-ray control unit 600 can appropriately control the rotation speed of the motor 604, there is no need to increase the safety factor and rotate the motor 604 at a speed higher than necessary as in the prior art, and the bearing 484. Can be reduced. In addition, the total number of revolutions during X-ray imaging can be reduced, which leads to a longer life of the X-ray tube apparatus 400.

In the calculation of the rotation speed by the rotation speed calculation unit 654, for a simple motor approximation model such as a DC motor, for example, the counter electromotive force is calculated based on the following formula, and the rotation speed is obtained from the counter electromotive force. Can do.
Vs = R · Is + L · dIs / dt + Es

Here, Is is a motor current vector, Vs is an input voltage, Es is a counter electromotive force vector, R is a winding resistance, and L is a winding inductance. Based on the above formula, the counter electromotive force vector Es may be obtained from the detected value of the input voltage Vs and the motor current vector Is to obtain the rotational speed. Alternatively, the rotation θ 350 may be controlled by calculating the angle θ of the counter electromotive force vector Es to obtain the rotor position and calculating the phase of the rotating magnetic field from the rotor position. The angle θ of the back electromotive force vector Es is as follows.
θ = arctan (ratio of X-axis component and Y-axis component of back electromotive force vector Es)

  Furthermore, in addition to the above control, a method may be used in which the same voltage is input to and output from the motor model and the actual motor, and correction is performed to increase the control accuracy. In the above embodiment, the X-ray control apparatus 302 is described as including the X-ray control unit 600. However, the entire X-ray CT apparatus 100 only needs to have the configuration and functions of the X-ray control unit 600, and the system control device 212 provided in the control console 200 has the configuration and functions of the X-ray control unit 600. You may have.

6). Description of Imaging Operation of X-ray CT Apparatus 100 An outline of operations and operations related to X-ray imaging of the X-ray CT apparatus 100 is shown in FIG. When the work is started, an X-ray imaging schedule is input from the input unit 222 of the input / output device 218 in step S102. Further, the setting parameters of the tube voltage, tube current, and filament current 362 of the X-ray tube apparatus 400 in the imaging schedule are input. A scan speed, an X-ray image capturing range, a focus size, a slice thickness, and the like are set. In addition to setting the operation schedule and various conditions of the X-ray tube apparatus 400, for example, the control conditions of the gantry 120 such as the turntable 124 and the control conditions of the bed 150 are input. Depending on the imaging method, the rotary anode 432 is temporarily raised to a predetermined rotational speed, and at the moment of X-ray imaging, the operation of the rotation drive unit 350 is stopped, and the motor 604 is rotated by inertial operation to generate noise in the rotation drive unit 350. It is also possible to perform an operation that suppresses the above. The operation schedule and set values of the gantry 120 including the operation schedule of the X-ray tube apparatus 400 are input from the input unit 222 while referring to the display on the display unit 224. The input schedule and setting values are stored and held in the storage device or storage device 216 in the system control device 212.

  After the process of step S102, a series of operation procedures from step S104 to step S124 are repeatedly executed in a very short time period. Control information is sent from the system control device 212 to the X-ray control device 302, the gantry control device 126, and the bed control device 152 in accordance with the respective schedules and setting values input in step S104. Before the operation of the X-ray tube apparatus 400 starts, the rotational speed of the motor 604 is calculated in step S106 and step S108 described below according to the schedule to be imaged, and the calculated rotational speed is set as the target rotational speed. The control unit 600 operates. Note that the calculation of the target rotation speed in step S106 or step S108 can be obtained by searching the database 622 from the set conditions as described using, for example, the rotation speed calculation unit 612 of FIG. The vector controller 640 calculates the operating conditions of the rotation drive unit 350 so as to achieve the target rotation speed, and AC current is supplied from the rotation drive unit 350 to the stator winding 452 of the motor 604, and the motor 604 starts rotating operation. . In this embodiment, since the DC power boosted from the converter 324 is supplied to the rotation drive unit 350, a large amount of power can be supplied from the rotation drive unit 350 to the stator winding 452, and the motor 604 can be turned on in a short time. The target rotation speed can be increased.

  A series of steps from Step S104 to Step S124 are repeatedly executed at short time intervals. When the motor 604 reaches the target rotational speed, the X-ray tube apparatus 400 is controlled to start X-ray irradiation by the control of Step S104. A tube voltage 334 and a tube current 336 are supplied, and a filament current 362 is supplied. In step S <b> 106, the accumulated heat amount HU of the rotary anode 432 is calculated, and the calculation result is used to determine the rotation speed of the rotary anode 432. Factors that increase the amount of accumulated heat HU include tube voltage, tube current, passage of X-ray irradiation time, and the like. On the other hand, factors that reduce the stored heat quantity HU include cooling capacity and the passage of X-ray irradiation stop time. The stored heat quantity HU can be obtained by calculating these as parameters.

  As a calculation method, it may be calculated like a direct algebra calculation, but the stored heat quantity HU based on the above parameters is obtained by experiment or calculation in advance and stored in a storage device as a database, and the database search based on the parameters is performed. Thus, the accumulated heat amount HU based on the parameters may be obtained. By calculating the stored heat quantity HU by calculation based on such a database search, an accurate calculation result can be obtained in a short time.

  In order to prevent the X-ray focal point of the target 434 colliding with the electron beam 412 irradiated from the cathode 416 of the X-ray tube apparatus 400 from being melted by heat, the rotating anode 432 is rotated by the motor 604. If the rotation of the rotary anode 432 is made faster, an increase in the temperature of the X-ray focal point can be suppressed, but the bearing 484 shown in FIG. Therefore, rather than unnecessarily increasing the rotational speed of the rotary anode 432, the rotational speed of the motor 604 is controlled under the condition that the temperature of the X-ray focal point of the target 434 is maintained so as not to melt in the X-ray irradiation state. Is desirable. As described above, the total number of rotations can be suppressed.

  The temperature of the X-ray focal point of the target 434 greatly depends on the accumulated heat amount HU accumulated so far, and further depends on the tube voltage and tube current to be supplied to the X-ray tube device 400. For this reason, it is preferable to predict and calculate the temperature rise of the X-ray focal point using the accumulated heat amount HU, the tube voltage, and the tube current as parameters to determine the target rotational speed of the motor 604. As described above, a database may be prepared in advance using the accumulated heat quantity HU, tube voltage, and tube current as parameters, and the target rotation speed of the motor 604 may be determined by searching the database.

  When the target rotational speed of the motor 604 is calculated in step S108, the calculation result is sent to the current vector calculation unit 642 in FIG. As described above, the calculation in step S108 is not only algebraic calculation, but also stored in advance as a rotation speed database of the motor 604 using the stored heat quantity HU, tube voltage, and tube current as parameters, and the stored database is searched. There may be. Further, the target rotation speed may be searched as a calculation result, but the current vectors Id and Iq may be searched instead of the target rotation speed. In this case, the calculation result of step S108 can be used in place of the output of the current vector calculation unit 642.

  The temperature environment of the X-ray tube apparatus 400 is severe and easily deteriorates. In particular, the bearing structure of the rotation support portion 462 is likely to deteriorate and break down. By accurately predicting the temperature rise of the X-ray focal point of the target 434 and keeping the rotational speed of the motor 604 as low as possible, the bearing structure of the rotation support portion 462 can be reduced and the failure can be reduced. Further, in order to predict the life, the operation characteristic of the motor 604 is calculated in step S112. For example, when a decrease in acceleration characteristics is observed or a decrease in rotation speed becomes large, it is possible to determine whether the bearing 484 of the rotation support portion 462 has been deteriorated or has broken down. As described with reference to FIG. 5, the rotation speed calculation unit 654 can calculate the rotation speed without having an angle sensor, and the bearing of the motor 604 can be calculated from the relationship between the change in the rotation speed and the output of the rotation drive unit 350. The magnitude of 484 frictional resistance can be determined.

  By storing the operation characteristic calculated in step S112, for example, the change in the friction coefficient of the bearing 484, and determining the directionality, the operation characteristic, for example, the friction coefficient of the bearing 484 deviates from the usable range. Can be predicted. It is important to store the calculation result of step S112 as a history.

  During operation of the motor 604, the process returns from step S114 to step 104 again, and the processing from step 104 to step 114 is repeated in a very short time. The operation of the motor 604 is stopped while the X-ray imaging is completed and the next X-ray imaging is started. This operation stop state is determined in step S114, and step S122 is executed in this operation stop state. In step S122, abnormality diagnosis and life prediction of the X-ray tube apparatus 400 are performed. The stored history is read out, and it is determined whether or not it has deviated from the predetermined allowable range. Even if the deviation does not deviate from the allowable range, it is determined from the history of the change in characteristics whether the deviation from the allowable range is imminent.

  Although the description is omitted in step S122, when the operation characteristic of the X-ray tube apparatus 400 has already deviated from the allowable range, an alarm is displayed, and after the next step turntable 124, forced The operation ends. Further, when it is determined that the operating characteristic does not deviate from the allowable range but the deviation is close, an alarm is also displayed and it is informed that the life of the X-ray tube apparatus 400 is short.

  The calculation result or detection result in step S112 is stored in the memory, and history data is created. Further, if it is determined in step S122 that the current calculation result has changed significantly with respect to the past history, it is also determined as abnormal. The degree of change is determined as abnormal, predicted in advance through experiments and the like, stored as data, and determined using this data.

  In X-ray imaging, even if X-ray irradiation is temporarily stopped between each imaging, X-ray imaging is resumed by operating the X-ray tube device 400 again according to the next imaging schedule. In step S124, it is determined whether or not all of the shooting work has been completed. If the shooting work has not been completed, execution returns to step S104. If it is determined in step S122 that an abnormality has occurred because the degree of deterioration exceeds a predetermined range, the shooting operation is stopped in step S124, and the shooting operation is forcibly terminated. The information obtained in step S112 can be held as a history in the storage device, and data held from outside can be taken out. By analyzing this data, it is possible to analyze deterioration and occurrence of abnormality.

7). 6. Description of Extending Life of X-ray Tube Device 400 In the flowchart of FIG. 6, the stored heat amount HU is calculated in step S106, and based on the stored heat amount HU, the tube voltage, the tube current, and the current stored heat amount HU are used as parameters. The temperature increase of the X-ray focal point 434 is predicted, the accumulated heat amount HU and the rotation speed of the motor 604 corresponding to the temperature increase of the X-ray focus are obtained, and the motor 604 is controlled using this rotation speed as a target value. In the conventional control, the target value of the rotational speed of the motor 604 is simply set to a very high value, and the motor 604 is operated at a higher speed than necessary. The bearings and the like of the X-ray tube device 400 are easily deteriorated due to a very severe environment, and a high-speed rotation more than necessary is a heavy burden, and is easily deteriorated and easily broken. According to the configuration and operation of the present embodiment, the rotation speed of the rotary anode 432 can be controlled at an appropriate rotation speed, and the total number of rotations of the rotary anode 432 can be reduced. This makes it possible to extend the life.

  In the present embodiment, step S106 and step S108 are repeatedly executed at a short cycle, and the rotation target of the motor 604 is immediately corrected according to the tube voltage and tube current. Therefore, the rotation speed of the rotary anode 432 can be increased in real time. It can be controlled with accuracy.

  Although the rotational speed of the motor 604 can be accurately controlled according to the state of the X-ray tube apparatus 400 according to the flowchart of FIG. 6, the margin for the required rotational speed of the rotating anode 432 is reduced. This has the merit of reducing the total number of rotations of the rotating anode 432 and extending the service life. However, since the margin is small, the response when the operating condition of the X-ray tube apparatus 400 is suddenly changed is further improved. Is desirable. An embodiment capable of further improving the responsiveness is shown in FIG. FIG. 7 differs from the flowchart shown in FIG. 6 in that step S110 is added. The other steps are the same as those in FIG. 6, and the description for the similar steps is omitted.

  In the flowchart illustrated in FIG. 6, the target rotational speed is calculated in step S108 according to the accumulated heat amount HU calculated in step S106 and the temperature prediction of the X-ray focal point, and the motor 604 is controlled according to the target rotational speed. In FIG. 7, it is detected in step S110 whether or not the operating condition of the X-ray tube apparatus 400 has been suddenly changed. If the operating condition has been suddenly changed, attention is paid to the change in the operating condition, The change in the rotation speed of the motor 604 corresponding to the change is added to the target rotation speed in step S108 to correct the target rotation speed, and the motor 604 is controlled at the corrected target rotation speed.

  For example, when the tube voltage or tube current suddenly increases, the increase in the rotation speed corresponding to these increases is calculated, and the calculated increase in the rotation speed is added to the previous target rotation speed to create a new one. Use the target rotation speed. Conversely, when the tube voltage or tube current suddenly decreases, the decrease in rotation speed corresponding to the decrease is calculated, and the calculated decrease is subtracted from the previous target rotation speed to obtain a new target rotation speed. To do. Responsiveness can be improved by making corrections corresponding to the sudden change in operating conditions of the X-ray tube apparatus 400 to the target rotational speed of the motor 604. Since the processing from step S104 to step S114 and the processing from step S104 to step S124 are repeatedly executed at very short time intervals, high responsiveness can be obtained.

  DESCRIPTION OF SYMBOLS 100 ... X-ray CT apparatus, 102 ... Examinee, Gantry 120 ... Gantry, 122 ... Opening, 124 ... Rotary table, 126 ... Gantry control device, 130 ... Collimator, 140 ... X-ray detector, 142 ... Data acquisition device, DESCRIPTION OF SYMBOLS 152 ... Bed control apparatus, 200 ... Control console, 212 ... System control apparatus, 214 ... Image processing part, 216 ... Memory | storage device, 218 ... Input / output device, 222 ... Input part, 224 ... Display part, 320 ... High voltage generator 322 ... AC power source, 324 ... converter, 326 ... inverter, 334 ... tube voltage, 336 ... tube current, 342 ... control information, 344 ... control information, 346 ... control information, 348 ... image information, 350 ... rotation drive unit, 400 ... X-ray tube device, 404 ... Envelope, 406 ... Radiation window, 408 ... Radiation window, 412 ... Electron beam, 414 ... X-ray, 416 ... Cathode, 418 ... Contact Terminals, 424 ... Rotating shaft, 432 ... Rotating anode, 434 ... Target, 452 ... Stator winding, 454 ... Stator core, 462 ... Rotating support part, 472 ... Fixed part, 474 ... Fixed bearing, 476 ... Rotating bearing part, 478 Rotating cylindrical part, 480 ... notch, 484 ... bearing, 604 ... motor, 612 ... rotational speed calculation part, 614 ... rotational speed command, 622 ... database, 640 ... vector control part, 642 ... current vector calculation part, 644 ... Slip frequency calculation unit, 648 ... voltage vector calculation unit, 652 ... coordinate conversion unit, 654 ... rotation speed calculation unit, 656 ... adder.

Claims (10)

An X-ray tube device that has a rotating anode and a motor that rotationally drives the rotating anode and generates X-rays to be irradiated to a subject;
An X-ray detector for detecting X-rays transmitted through the subject;
A display unit for displaying an image based on the image information detected by the X-ray detector;
An input unit for inputting a schedule of X-ray imaging or a tube voltage and a tube current supplied to the X-ray tube device;
A control device for controlling the rotational speed of the motor;
A rotation drive unit for supplying AC power to the motor,
The control device calculates a target rotation speed or target torque according to the X-ray imaging schedule or a tube voltage or a tube current supplied to the X-ray tube device, and d-axis current and q according to the target rotation speed or the target torque. It has a vector calculation part that calculates the shaft current,
The control device outputs a control signal for controlling the rotation drive unit based on the output of the vector calculation unit and the rotation speed of the motor,
The X-ray apparatus, wherein the rotation driving unit drives the motor in accordance with the control signal from the control apparatus.   2. The X-ray apparatus according to claim 1, wherein the control device includes a rotation speed calculation unit that calculates a rotation speed of the motor by calculation, and the control device calculates the output calculated from the output of the vector calculation unit. An X-ray apparatus characterized by outputting the control signal for controlling the rotation drive unit based on a rotation speed.   3. The X-ray apparatus according to claim 2, wherein an alternating current supplied to the motor from the rotational drive unit is measured, a measured value of the measured alternating current is subjected to coordinate conversion, and a coordinate conversion result of the measured value of the alternating current is measured. An X-ray apparatus characterized in that the rotational speed of the motor is obtained from   4. The X-ray apparatus according to claim 1, wherein the control device is configured to store a stored heat amount HU based on a schedule of the X-ray imaging or a tube voltage or a tube current supplied to the X-ray tube device. And calculating the target rotational speed or the target torque of the motor from the stored heat quantity HU determined by the calculation.   4. The X-ray apparatus according to claim 1, wherein the control device is configured to control the rotation anode based on the X-ray imaging schedule or the tube voltage or tube current supplied to the X-ray tube device. An X-ray apparatus characterized by calculating a temperature of a target X-ray focal point and calculating the target rotational speed or the target torque of the motor from the X-ray focal point temperature obtained by the calculation.   6. The X-ray apparatus according to claim 1, wherein the control device is based on a change in operating characteristics of the motor obtained in the control based on the target rotational speed or the target torque of the motor. An X-ray apparatus characterized by detecting an abnormality in the X-ray tube apparatus.   7. The X-ray apparatus according to claim 6, wherein the control device has a change in operating characteristics of the motor obtained in the control based on the target rotational speed or the target torque of the motor exceeding a predetermined range. An X-ray apparatus characterized in that when it has changed, it is determined that there is an abnormality and the operation of the X-ray tube apparatus is stopped.   6. The X-ray apparatus according to claim 1, wherein the control device is based on a change in operating characteristics of the motor obtained in the control based on the target rotational speed or the target torque of the motor. An X-ray apparatus characterized by performing an operation for predicting a life in which the X-ray tube apparatus is abnormal.   9. The X-ray apparatus according to claim 1, wherein the control device controls the X-ray tube in the control based on the target rotational speed or the target torque of the motor of the X-ray tube device. It is detected whether or not the operating condition of the apparatus has changed, and when the operating condition of the X-ray tube apparatus changes, the target rotational speed is corrected by the amount of change in the rotational speed corresponding to the amount of change. X-ray device. An X-ray tube device that has a rotating anode and a motor that rotationally drives the rotating anode and generates X-rays to be irradiated to a subject;
An X-ray detector for detecting X-rays transmitted through the subject;
A display unit for displaying an image based on the image information detected by the X-ray detector;
An input unit for inputting a schedule of X-ray imaging or a tube voltage and a tube current supplied to the X-ray tube device;
A control device for controlling the rotational speed of the motor;
A rotation drive unit for supplying AC power to the motor,
A first step of calculating a target rotational speed or a target torque in accordance with the X-ray imaging schedule or a tube voltage or a tube current supplied to the X-ray tube device;
A second step of calculating a vector of the d-axis current and the q-axis current according to the target rotational speed or the target torque;
A third step of calculating the rotational speed of the motor;
Executing a calculation result of the second step and a fourth step of outputting a control signal for controlling the rotation drive unit based on the calculation result of the third step;
The X-ray apparatus control method, wherein the rotation drive unit executes a fifth step of driving the motor in accordance with the control signal from the control apparatus.

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