JP6058406B2 - X-ray diagnostic imaging system - Google Patents

Description

  Embodiments described herein relate generally to an X-ray image diagnosis system including a plurality of X-ray image diagnosis apparatuses that generate image data by irradiating a subject with X-rays.

  X-ray image diagnostic apparatuses such as an X-ray apparatus and an X-ray CT apparatus provide image data obtained by irradiating a subject with X-rays, and play an important role in medical practices such as diagnosis and treatment. Yes. This X-ray diagnostic imaging apparatus includes an X-ray tube that generates X-rays and a high-voltage generator that applies a high voltage to the X-ray tube. A commercial power supply is used as the power supply for the high voltage generator.

  The X-ray diagnostic imaging apparatus consumes a large amount of power for X-ray irradiation in a short time, and therefore requires a large-capacity power supply facility. And in the facility provided with the several X-ray image diagnostic apparatus, since the capacity | capacitance for a number is required, there exists a problem that the power supply equipment of a commercial power source enlarges. In response to this problem, the use of a secondary battery with higher performance and longer life as a result of recent technological progress can be used as a power source for X-ray irradiation, thereby reducing the size of the power supply facility for the commercial power source.

JP 2012-129087 A

  However, when secondary batteries that supply power to a plurality of X-ray diagnostic imaging apparatuses cannot be used due to insufficient capacity, the power supply equipment that has been downsized cannot supply power for X-ray irradiation to the plurality of X-ray diagnostic imaging apparatuses. There is a problem that inspection with any of the devices is hindered.

  Embodiments have been made to solve the above-described problems, and an object of the present invention is to provide an X-ray image diagnostic system capable of reducing the obstacles to examinations performed by a plurality of X-ray image diagnostic apparatuses.

  In order to solve the above problem, the X-ray diagnostic imaging system according to the embodiment inputs first examination information that enables the first examination to be started, and starts X-ray irradiation based on the first examination information. A first X-ray diagnostic imaging apparatus having a first operation unit capable of inputting an examination start enabling the examination, and an input for starting X-ray irradiation after the examination start input is performed; Input of the second inspection information that enables the start of the inspection, input of the inspection start that enables the start of X-ray irradiation based on the second inspection information, and X after the input of the start of the inspection is performed A second X-ray image diagnostic apparatus having a second operation unit capable of input to start X-ray irradiation, and a first power supply for supplying X-ray irradiation power to the first X-ray image diagnostic apparatus, A second power source for supplying X-ray irradiation power to the second X-ray diagnostic imaging apparatus; An auxiliary power source that supplies power for X-ray irradiation to at least one of the first or second X-ray diagnostic imaging apparatus, and power to the first X-ray diagnostic imaging apparatus A first switching unit that switches the power source to the first power source or the auxiliary power source, and a second power source that switches the power source that supplies power to the second X-ray diagnostic imaging apparatus to the second power source or the auxiliary power source When power from the auxiliary power source is supplied to the switching unit and the first and second X-ray diagnostic imaging apparatuses, an input to start an examination is received from one of the first or second operation units. An inspection management device for determining whether or not to enable an input of an inspection start from the one operation unit based on the first and second inspection information and a preset determination criterion, It is provided with.

1 is a block diagram showing a configuration of an X-ray image diagnostic system according to an embodiment. 1 is a block diagram showing a configuration of a first X-ray apparatus according to an embodiment. The figure for demonstrating the waiting, the test | inspection, and the irradiation based on embodiment. The block diagram which shows the structure of the power supply device which concerns on embodiment. The figure which shows an example of the criteria used for determination of the test | inspection management apparatus which concerns on embodiment. The flowchart which shows operation | movement of the X-ray image diagnostic system which concerns on embodiment. The figure which shows an example of the stepping DSA imaging | photography concerning embodiment. The figure which shows an example which X-ray irradiation avoids the timing of X-ray irradiation of the other X-ray apparatus by one X-ray apparatus which concerns on embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. The embodiment can be applied to an X-ray image diagnosis system including a plurality of X-ray image diagnosis apparatuses such as an X-ray apparatus and an X-ray CT apparatus that generate image data by irradiating a subject with X-rays. However, in the embodiment described below, an example of an X-ray image diagnostic system including a plurality of circulatory X-ray apparatuses will be described.

FIG. 1 is a block diagram showing a configuration of an X-ray image diagnostic system.
The X-ray diagnostic imaging system 600 includes at least first and second X-ray apparatuses 100 and 200, and a power supply apparatus 300 that supplies X-ray irradiation power to the first and second X-ray apparatuses 100 and 200. And an inspection management device 400 that manages the inspection of the first and second X-ray apparatuses 100 and 200. The first X-ray apparatus 100, the second X-ray apparatus 200, the power supply apparatus 300, and the inspection management apparatus 400 are connected via a network 500 so that they can communicate with each other.

FIG. 2 is a block diagram showing the configuration of the first X-ray apparatus 100.
The first X-ray apparatus 100 includes a bed unit 10 on which a subject P1 is placed, an X-ray irradiation unit 20 that irradiates the subject P1 placed on the bed unit 10 with X-rays, and a subject. And an X-ray detector 30 for detecting X-rays transmitted through P1. Further, the arm 40 that supports the X-ray irradiation unit 20 and the X-ray detection unit 30 movably, the bed unit 10, the movement mechanism unit 50 that moves the X-ray irradiation unit 20 and the X-ray detection unit 30, and the power supply device 300. And a high voltage generation unit 60 that generates a high voltage necessary for X-ray irradiation of the X-ray irradiation unit 20 by the electric power supplied from

  In addition, the first X-ray apparatus 100 displays the image data generation unit 70 that generates image data based on the detection signal detected by the X-ray detection unit 30 and the image data generated by the image data generation unit 70. A display unit 71 that performs input of various commands, a communication unit 81 that performs communication via the network 500, and a system control unit 90 that controls each unit. .

  The bed unit 10 includes a top plate 11 on which the subject P1 is placed and a top plate support 12 that supports the top plate 11 so as to be movable. The X-ray irradiation unit 20 generates an X-ray to be irradiated to the subject P1 placed on the top plate 11 and the X-ray irradiation range for limiting the X-ray irradiation range from the X-ray tube 21. A diaphragm 22 is provided. The X-ray detector 30 processes the detection signal detected by the X-ray detector 31 and the X-ray detector 31 that detects the X-ray transmitted through the subject P1 placed on the top plate 11. A signal processing unit 32 for generating X-ray projection data is provided.

  The moving mechanism unit 50 moves the table 11 of the bed unit 10 up and down, in the longitudinal direction, etc., and the subject P1 placed on the table 11 from a desired angle. An arm moving mechanism 52 that moves the X-ray irradiation unit 20 and the X-ray detection unit 30 by driving the arm 40 so as to enable fluoroscopy and imaging.

  The high voltage generator 60 includes a transformer that boosts the voltage. Then, X-ray irradiation conditions including the tube voltage, tube current, and pulse width for fluoroscopy input from the first operation unit 80, tube voltage, tube current, and tube for imaging that require higher power than for fluoroscopy Based on X-ray irradiation conditions including a pulse width, a high voltage is applied to the X-ray tube 21 of the X-ray irradiation unit 20 to continuously irradiate weak X-rays, or strong X-rays are irradiated in a short time. X-rays for photographing are generated.

  The image data generation unit 70 generates image data based on the X-ray projection data generated by the signal processing unit 32 of the X-ray detection unit 30. In addition, DA (digital angiography) image data generated after the contrast medium is injected into the subject P1 by the angiographic examination is generated. Further, DSA (digital subtraction angiography) image data in which only blood vessels are extracted is generated by subtracting the mask image data generated before injection of the contrast agent and the contrast image data generated after injection of the contrast agent on the subject P1. .

  The display unit 71 includes a liquid crystal panel or a CRT monitor. Then, image data such as DA image data and DSA image data generated by the image data generation unit 70 is displayed.

  The first operation unit 80 includes input devices such as a keyboard, a trackball, a joystick, a mouse, and a switch. Then, the input of the first examination information such as the name, ID, age, weight, examination site, X-ray irradiation condition, irradiation plan, etc. of the subject P1 that allows the examination (first examination) of the subject P1 to be started. An input for starting an examination enabling X-ray irradiation, an input for starting an X-ray irradiation, an input for stopping an X-ray irradiation, an input for ending an examination impossible for X-ray irradiation, the top plate 11 of the bed unit 10 and the X-rays Input for moving the irradiation unit 20 and the X-ray detection unit 30 is performed.

  Then, as shown in FIG. 3, the state before the start of the inspection is input from the first operation unit 80 or after the end of the inspection is input is referred to as waiting. In addition, after the first inspection information is input from the first operation unit 80, the period from the input of the inspection start to the input of the end of the inspection is referred to as in-progress. Also, after the input for starting the examination is performed from the first operation unit 80, the period from the input for starting the X-ray irradiation to the input for stopping the X-ray irradiation is referred to as irradiation.

  The communication unit 81 includes first examination information input from the first operation unit 80, examination start operation information, X-ray irradiation start operation information, X-ray irradiation stop operation information, examination end operation information, and the like. Input information is transmitted to the inspection management apparatus 400. Also, operation information for starting and ending inspection is transmitted to the power supply apparatus 300. In addition, input information input by the second X-ray apparatus 200 is received.

  The system control unit 90 includes a CPU and a storage circuit, and based on input information input from the first operation unit 80, the X-ray irradiation unit 20, the X-ray detection unit 30, the movement mechanism unit 50, and the high voltage generation unit 60. The units of the image data generation unit 70 and the communication unit 81 are controlled in an integrated manner. In addition, the timing of X-ray irradiation and the like are controlled based on input information input by the second X-ray apparatus 200.

  The second X-ray apparatus 200 is configured in the same manner as the first X-ray apparatus 100 and has a second operation unit 180. Then, the second operation unit 180 includes the name, ID, age, weight, examination site, X-ray irradiation condition, irradiation plan, etc. of the subject P2 that can start the examination of the subject P2 (second examination). The second inspection information is input, the inspection start input enabling X-ray irradiation, the X-ray irradiation start input, the X-ray irradiation stop input, the inspection end input disabling X-ray irradiation, and the like are performed. .

  In addition, the second X-ray apparatus 200 includes second inspection information input from the second operation unit 180, operation information for starting inspection, operation information for starting X-ray irradiation, operation information for stopping X-ray irradiation, and inspection. Input information such as operation information for termination is transmitted to the inspection management apparatus 400. Also, operation information for starting and ending inspection is transmitted to the power supply apparatus 300. In addition, the first examination information input by the first X-ray apparatus 100 returned from the examination management apparatus 400 in response to the transmission of the input information inputted from the second operation unit 180 is received. And the timing of X-ray irradiation is controlled based on 1st test | inspection information.

  The state before the start of inspection is input from the second operation unit 180 or after the end of inspection is input is referred to as waiting. In addition, after the second inspection information is input from the second operation unit 180, the period from when the start of the inspection is input to when the end of the inspection is input is referred to as “under inspection”. In addition, after an input for starting examination is performed from the second operation unit 180, a period from when an input for starting X-ray irradiation is performed until an input for stopping X-ray irradiation is performed is referred to as irradiation in progress.

FIG. 4 is a block diagram showing the configuration of the power supply apparatus 300.
The power supply apparatus 300 includes a first power supply 310 that supplies power for X-ray irradiation to the first X-ray apparatus 100 and a second power supply that supplies power for X-ray irradiation to the second X-ray apparatus 200. And a power source 320. Further, an auxiliary power source 330 is provided as a commercial power source for supplying X-ray irradiation power to at least one of the first or second X-ray devices 100 and 200. In addition, a first switching unit 340 is provided that switches a power source that supplies power to the first X-ray apparatus 100 from one power source of the first power source 310 or the auxiliary power source 330 to the other power source.

  The power supply apparatus 300 also includes a second switching unit 350 that switches the power supply for supplying power to the second X-ray apparatus 200 from one power supply of the second power supply 320 or the auxiliary power supply 330 to the other power supply. . In addition, a communication unit 360 that performs communication via the network 500 and a power supply control unit 370 that drives and controls the first and second switching units 340 and 350 are provided.

  The first power supply 310 includes a secondary battery 311 that supplies power for X-ray irradiation to the first X-ray apparatus 100 and a charging unit 312 that charges the secondary battery 311. Then, when the first X-ray apparatus 100 is connected to the first X-ray apparatus 100 by the first switching unit 340, electric power is supplied to the first X-ray apparatus 100. Further, when the first X-ray apparatus 100 is interrupted by the first switching unit 340, the supply of power to the first X-ray apparatus 100 is stopped.

  The charging unit 312 monitors the remaining amount of the secondary battery 311, and the capacity of the secondary battery 311 has decreased to the first warning capacity that may be insufficient during one inspection of the first X-ray device 100. At this time, it is determined that the capacity of the secondary battery 311 is insufficient, and information on insufficient capacity is output to the power supply control unit 370. Then, when the first X-ray apparatus 100 is disconnected from the first X-ray apparatus 100, the secondary battery 311 is charged by supplying power from the auxiliary power supply 330.

  In addition, the charging unit 312 receives the power from the auxiliary power source 330, and when the capacity of the secondary battery 311 reaches the first usable capacity that can be used in one or more inspections for X-ray irradiation, The supply of power to 311 is stopped, and charging end information is output to the power control unit 370. Further, when the secondary battery 311 is connected to the first X-ray apparatus 100 by the first switching unit 340 in a state where the secondary battery 311 can be supplied by one or more inspections, the charging of the secondary battery 311 is stopped. doing.

  The second power source 320 includes a secondary battery 321 that supplies power for X-ray irradiation to the second X-ray apparatus 200 and a charging unit 322 that charges the secondary battery 321. Then, when the second X-ray apparatus 200 is connected to the second X-ray apparatus 200 by the second switching unit 350, power is supplied to the second X-ray apparatus 200. When the second X-ray apparatus 200 is interrupted by the second switching unit 350, the supply of power to the second X-ray apparatus 200 is stopped.

  The charging unit 322 monitors the remaining amount of the secondary battery 321, and the capacity of the secondary battery 321 has dropped to a second warning capacity that may be insufficient during one inspection of the second X-ray device 200. At this time, it is determined that the capacity of the secondary battery 321 is insufficient, and information indicating insufficient capacity is output to the power supply control unit 370. Then, when the second X-ray apparatus 200 is disconnected from the second X-ray apparatus 200, the secondary battery 321 is charged by supplying power from the auxiliary power source 330.

  In addition, the charging unit 322 supplies the secondary battery when the capacity of the secondary battery 321 reaches the second usable capacity that can be used in one or more inspections for X-ray irradiation by supplying power from the auxiliary power source 330. The supply of power to 321 is stopped, and charging end information is output to the power supply control unit 370. When the secondary battery 321 is connected to the second X-ray apparatus 200 by the second switching unit 350 in a state in which the secondary battery 321 can be supplied for X-ray irradiation by one or more inspections, the secondary battery 321 321 charging is stopped.

  The auxiliary power supply 330 includes a converter that converts electric power from alternating current to direct current, and supplies the converted electric power to the first power supply 310 and the second power supply 320. Further, when the capacity of the secondary battery 311 of the first power supply 310 is insufficient and the first X-ray device 100 is connected to the first X-ray device 100 by the first switching unit 340, Supply power for X-ray irradiation. In addition, when the capacity of the secondary battery 321 of the second power source 320 is insufficient and the second X-ray apparatus 200 is connected to the second X-ray apparatus 200 by the second switching unit 350, Supply power for X-ray irradiation.

  Note that a condition when the first X-ray apparatus 100 emits the strongest X-ray when power is supplied from the first power supply 310 is a first X-ray irradiation condition, and the second power supply A condition when the second X-ray apparatus 200 emits the strongest X-ray when power is supplied from 320 is a second X-ray irradiation condition. The auxiliary power supply 330 has a capacity capable of supplying electric power that enables the first X-ray apparatus 100 to perform X-ray irradiation under the first X-ray irradiation condition. Capacity capable of supplying power that enables X-ray irradiation under two X-ray irradiation conditions, and the first and second X-ray apparatuses 100 and 200 can simultaneously perform X under the first and second X-ray irradiation conditions. It has an upper limit capacity, which is a capacity that cannot supply power that enables irradiation.

  The first switching unit 340 is disposed between the first power source 310 and the auxiliary power source 330 and the first X-ray device 100, and the power source that supplies power to the first X-ray device 100 is the first power source. A changeover switch for switching from one power source of the power source 310 or the auxiliary power source 330 to the other power source, and a conversion circuit for converting electric power from the other power source switched by the changeover switch from DC to AC. When the first X-ray apparatus 100 is connected to one power source of the first power source 310 or the auxiliary power source 330, the power source is disconnected from the other power source.

  The second switching unit 350 is disposed between the second power source 320 and the auxiliary power source 330 and the second X-ray device 200, and the second power source supplies power to the second X-ray device 200. 320 or the auxiliary power source 330 is provided with a selector switch for switching from one power source to the other power source, and a conversion circuit for converting electric power from the other power source switched by the selector switch from direct current to alternating current. When the second X-ray apparatus 200 is connected to one power source of the second power source 320 or the auxiliary power source 330, the second power source is disconnected from the other power source.

  When the first switching unit 340 switches the power source that supplies power to the first X-ray apparatus 100 from one power source of the first power source 310 or the auxiliary power source 330 to the other power source, the communication unit 360 Information on the power source is transmitted to the first X-ray apparatus 100 and the inspection management apparatus 400. Further, when the second switching unit 350 switches the power source that supplies power to the second X-ray apparatus 200 from one power source of the second power source 320 or the auxiliary power source 330 to the other power source, information on the other power source Is transmitted to the second X-ray apparatus 200 and the inspection management apparatus 400.

  The power supply control unit 370 performs the first switching based on the capacity shortage and the charge end information output from the first power supply 310, the inspection start and inspection end operation information transmitted from the first X-ray apparatus 100, and the like. The unit 340 is driven and controlled. Then, when the first X-ray apparatus 100 is on standby before input of inspection start is performed from the first operation unit 80 or after input of inspection end is performed, to the first X-ray apparatus 100 The power source for supplying power is switched from the first power source 310 to the auxiliary power source 330 in response to the capacity shortage of the first power source 310, and from the auxiliary power source 330 to the first power source in response to the end of charging of the first power source 310. Switch to 310.

  In addition, the power supply control unit 370 performs the second operation based on the shortage of capacity output from the second power supply 320 and the information on the end of charging, the operation information on the start and end of inspection transmitted from the second X-ray apparatus 200, and the like. The switching unit 350 is driven and controlled. When the second X-ray apparatus 200 is on standby, a power supply for supplying power to the second X-ray apparatus 200 is supplied from the second power supply 320 to the auxiliary power supply according to the capacity shortage of the second power supply 320. 330, and the auxiliary power source 330 is switched to the second power source 320 in response to the end of charging of the second power source 320.

  In this way, power for X-ray irradiation of the first and second X-ray apparatuses 100 and 200 is supplied from the first and second power sources 310 and 320, and When the capacity of at least one of the power supplies is insufficient, power can be supplied from the auxiliary power supply 330 instead of the power supply having the insufficient capacity.

  When power is supplied from the auxiliary power supply 330 to the first and second X-ray apparatuses 100 and 200 based on the power supply information from the power supply apparatus 300, the inspection management apparatus 400 sets the first determination criterion and the first Based on the input information such as the first and second inspection information input from the second operation units 80 and 180, the inspection start from one operation unit of the first or second operation unit 80 or 180 is started. Determine whether to validate the input.

  When the examination management apparatus 400 determines that the examination start input from one operation unit is valid, the examination management apparatus 400 transmits the valid information to the X-ray apparatus (one X-ray apparatus) having the one operation unit. An X-ray apparatus that permits X-ray irradiation at a normal timing in accordance with an input of the start of X-ray irradiation from one operation unit after being determined to be valid, or has the other operation unit (the other X-ray apparatus) X-ray irradiation is allowed while avoiding duplication. Next, when X-ray irradiation at a normal timing is permitted, permission information at the normal timing is transmitted to one X-ray apparatus. In addition, when X-ray irradiation is permitted while avoiding duplication with the other X-ray apparatus, permission information for avoiding duplication, time when X irradiation start is input from the other operation unit, and the other The inspection information input from the operation unit is transmitted to one X-ray apparatus.

  When the examination management apparatus 400 determines that the examination start input from one operation unit is invalid, the examination management apparatus 400 transmits the invalid information to one X-ray apparatus. The system control unit of one X-ray apparatus makes the inspection start input from one operation unit invalid based on invalid information from the inspection management device 400 and maintains the standby state of each unit, and displays the invalid information on the display unit. Display output.

  Hereinafter, an example of the operation of the X-ray image diagnostic system 600 will be described with reference to FIGS. 1 to 8. FIG. 5 is a diagram illustrating an example of a determination criterion used for determination by the inspection management apparatus 400. FIG. 6 is a flowchart showing the operation of the X-ray image diagnostic system 600.

  In FIG. 5, when the first and second X-ray apparatuses 100 and 200 are supplied with power from the auxiliary power supply 330 of the power supply apparatus 300, the inspection management apparatus 400 has the first or second operation unit 80, When the inspection start input is performed from one operation unit 180, it is determined whether or not the inspection start input from one operation unit is validated according to, for example, eight patterns of determination criteria S1 to S8.

  In FIG. 6, when an inspection start input is performed from one operation unit, the inspection management apparatus 400 starts an inspection from one operation unit when the other X-ray apparatus is on standby (Yes in step S1). Is valid (step S2). If the other X-ray apparatus is being inspected (No in step S1), the process proceeds to step S4.

  After step S2, when the X-ray irradiation start input is performed from one operation unit, the inspection management apparatus 400 performs X-ray irradiation at a normal timing according to the X-ray irradiation start input to one X-ray apparatus. Is permitted (step S3).

  After step S3, one X-ray apparatus receives the normal timing permission information from the examination management apparatus 400. Then, X-ray irradiation is started at a timing set in advance according to an input of X-ray irradiation start from one operation unit.

  As described above, when the other X-ray apparatus is on standby, the examination start input from one operation unit is validated, and the X-ray irradiation start input from one operation unit is made at a normal timing. By permitting X-ray irradiation, it is possible to prevent the inspection of one X-ray apparatus from being hindered.

  When the other X-ray apparatus is being inspected (No in step S1), the inspection management apparatus 400 determines the first and second X-rays based on the X-ray irradiation conditions included in the first and second inspection information. Total power required when the X-ray irradiation is simultaneously performed by the X-ray apparatuses 100 and 200 is calculated (Step S4).

  If the total power is within the allowable range that can be simultaneously supplied from the auxiliary power source 330 to the first and second X-ray apparatuses 100 and 200 (Yes in step S5), the process proceeds to step S2. . If the total power exceeds the upper limit capacity that cannot be simultaneously supplied from the auxiliary power source 330 to the first and second X-ray apparatuses 100 and 200 and is outside the allowable range (No in step S5), the process proceeds to step S6. To do.

  As described above, when the other X-ray apparatus is being inspected and the total power required when X-ray irradiation is simultaneously performed by the first and second X-ray apparatuses 100 and 200 is within an allowable range, The first and second X-ray apparatuses are made effective by inputting the start of inspection from the operation unit and permitting X-ray irradiation at normal timing according to the input of X-ray irradiation start from one of the operation units. The hindrance to 100, 200 inspections can be prevented.

  After “No” in step S5, when the other X-ray apparatus is being inspected and it has not been irradiated before the input of the X-ray irradiation start is performed from the other operation unit (Yes in step S6), step S7 Migrate to If it is not X-ray non-irradiation (No in step S6), the process proceeds to step S8.

  If there is no irradiation plan in the inspection information (the other inspection information) input from the other operation unit after “Yes” in Step S6, the process proceeds to Step S9. If the other examination information includes an irradiation plan (Yes in step S7), the process proceeds to step S10.

  Here, the irradiation plan is a plan including information indicating the timing and irradiation time of X-ray irradiation in accordance with the input of X-ray irradiation start. The irradiation plan includes stepping DA (digital angiography) imaging, stepping DSA (digital subtraction angiography) imaging, rotational DA imaging, and rotational DSA imaging. If there is no irradiation plan in each of the first and second examination information, an input for starting X-ray irradiation or an input for stopping X-ray irradiation at an arbitrary timing according to the progress of the operation of an operator such as a doctor during the examination. Will be done.

  FIG. 7 is a diagram illustrating an example of stepping DSA imaging. This stepping DSA imaging can be performed by operating in the same manner in the first and second X-ray apparatuses 100 and 200. An example of stepping DSA imaging performed in the first X-ray apparatus 100 will be described below. .

  From the first operation unit 80, the imaging start position, the imaging end position, the number of steps, the linear movement speed of the top plate 11 or the X-ray irradiation unit 20 and the X-ray detection unit 30, the X-ray irradiation conditions, the injection timing of the contrast agent, etc. Input the irradiation plan for setting. Then, at a normal timing in accordance with the input of the start of X-ray irradiation, the tabletop 11 is moved stepwise in the direction of the arrow L1 that is the longitudinal direction between the imaging start position and the imaging end position of the subject P1, or The X-ray irradiation unit 20 and the X-ray detection unit 30 are moved stepwise in the other direction of the L1 direction. Then, for example, until the top plate 11 is moved stepwise and stopped at the imaging end position, X-ray irradiation is performed every time the top plate 11 is stopped, and a mask image is generated by the image data generation unit 70.

  After stopping at the imaging end position and injecting the contrast medium into the subject P1, the tabletop 11 is moved stepwise in the other direction. Then, X-ray irradiation is performed every time the top plate 11 moving in steps is stopped, and the image data generation unit 70 generates contrast image data. Next, DSA image data is generated from the mask image data and contrast image data.

  In rotation DSA imaging, an irradiation plan for setting an imaging start angle, an imaging end angle, a rotational movement speed of the X-ray irradiation unit 20 and the X-ray detection unit 30, an X-ray irradiation condition, a contrast agent injection timing, and the like. Make input. Next, when an X-ray irradiation start input is performed, the X-ray irradiation unit 20 and the X-ray detection unit 30 are located around the subject P1 between the imaging start angle and the imaging end angle of the subject P1. Rotate around the axis. Then, X-ray irradiation is performed every time the X-ray irradiation unit 20 and the X-ray detection unit 30 are stopped.

  After “No” in step S7 of FIG. 6, if there is an irradiation plan in the examination information (one examination information) input from one operation unit (Yes in step S9), the process proceeds to step S2. If there is no irradiation plan in one inspection information (No in step S9), the input of inspection start from one operation unit is invalidated (step S11).

  After “Yes” in Step S7, if one of the examination information includes an irradiation plan (Yes in Step S10), the process proceeds to Step S2. Moreover, when there is no irradiation plan in one test | inspection information (No of step S10), it transfers to step S11.

  In this way, the other X-ray apparatus is under inspection, the total power is outside the allowable range, and before the X-ray irradiation start input is performed from the other operation unit, the irradiation plan is included in one inspection information. By enabling the input of the examination start from one operation unit, giving priority to the input of the X-ray irradiation start from one operation unit and permitting X-ray irradiation at a normal timing, The hindrance to the inspection of the first and second X-ray apparatuses 100 and 200 can be reduced.

  In addition, the other X-ray apparatus is being inspected, the total power is outside the allowable range, the other X-ray apparatus is being inspected, and before the start of X-ray irradiation is performed. When there is no irradiation plan, priority is given to the inspection start input from the other operation unit and the inspection start input from one operation unit is invalidated, thereby avoiding the shortage of the capacity of the auxiliary power source 330 and the other. Can prevent the inspection of the X-ray apparatus.

  After “No” in step S6, when the other X-ray apparatus is irradiating (Yes in step S8), the process proceeds to step S14. Further, when the X-ray irradiation stop is input from the other operation unit and the X-ray irradiation is stopped (No in step S8), the process proceeds to step S15.

  If there is no irradiation plan in the other examination information after “Yes” in Step S8 (No in Step S14), the process proceeds to Step S11. If the other examination information includes an irradiation plan (Yes in step S14), the process proceeds to step S12.

  Thus, the other X-ray apparatus is under examination, the total power is outside the allowable range, and the X-ray irradiation stop input is performed after the X-ray irradiation start input is performed from the other operation unit. If there is no irradiation plan in the other inspection information, the capacity of the auxiliary power source 330 is given by giving priority to the inspection of the other X-ray apparatus and invalidating the input of the inspection start from one operation unit. The shortage can be avoided and the inspection of the other X-ray apparatus can be prevented from being hindered.

  After “No” in Step S8, when there is no irradiation plan in the other examination information (No in Step S15), the process proceeds to Step S16. If the other examination information includes an irradiation plan (Yes in step S15), the process proceeds to step S17.

  After “No” in step S15, if there is an irradiation plan in one inspection information (Yes in step S16), the process proceeds to step S2. Moreover, when there is no irradiation plan in one test | inspection information (No of step S16), it transfers to step S11.

  If there is an irradiation plan in one of the examination information after “Yes” in Step S15 (Yes in Step S17), the process proceeds to Step S2. Moreover, when there is no irradiation plan in one test | inspection information (No of step S17), it transfers to step S11.

  In this way, the other X-ray apparatus is under inspection, the total power is outside the allowable range, and after the input of the X-ray irradiation stop is performed from the other operation unit, the one inspection information is irradiated. When there is a plan, by enabling the input of examination start from one operation unit, giving priority to the input of starting X-ray irradiation from one operation unit and allowing X-ray irradiation at normal timing The hindrance to the inspection of the first and second X-ray apparatuses 100 and 200 can be reduced.

  In addition, the other X-ray apparatus is being inspected, the total power is outside the allowable range, and after the input of the X-ray irradiation stop is performed from the other operation unit, the irradiation plan is included in one inspection information. If there is not, the priority of the inspection of the other X-ray apparatus is given and the inspection start input from one operation unit is invalidated, thereby avoiding the shortage of the capacity of the auxiliary power source 330 and the inspection of the other X-ray apparatus. Can be prevented.

  After “Yes” in Step S14, the inspection management apparatus 400 validates the input of the inspection start from one operation unit (Step S12).

  When an input of X-ray irradiation start is performed from one operation unit after step S12, the inspection management apparatus 400 permits X-ray irradiation while avoiding duplication with the other X-ray apparatus (step S13). .

  After step S13, the inspection management apparatus 400 sends the permission information avoiding duplication, the time when the X irradiation start input is performed from the other operation unit, and the other inspection information to one X-ray apparatus. Send. One X-ray apparatus performs X-ray irradiation while avoiding the X-ray irradiation timing of the other X-ray apparatus based on each information received from the inspection management apparatus 400.

  In this way, the other X-ray apparatus is under examination, the total power is outside the allowable range, and the X-ray irradiation stop input is performed after the other X-ray apparatus is input to start X-ray irradiation. If there is an irradiation plan in the other examination information, the X-ray irradiation priority is given to the other X-ray apparatus that is quickly input to start X-ray irradiation, and X-ray irradiation starts from one operation unit. By permitting X-ray irradiation while avoiding duplication with the other X-ray apparatus with respect to the input, the interference with the inspection of one X-ray apparatus is reduced without interfering with the inspection of the other X-ray apparatus. be able to.

FIG. 8 is a diagram illustrating an example in which one X-ray apparatus performs X-ray irradiation while avoiding the X-ray irradiation timing of the other X-ray apparatus.
In the irradiation plan A1 of the other X-ray apparatus, X-ray irradiation is performed, for example, three times after an input of X-ray irradiation start is performed at time ta. Assume that the first X-ray irradiation is performed between time t11 and time t12. Further, it is assumed that the second X-ray irradiation is performed between time t13 and time t14. Further, it is assumed that the third X-ray irradiation is performed between time t15 and time t16.

  In the irradiation plan B1 of one X-ray apparatus, X-ray irradiation is performed twice after input of X-ray irradiation start is performed at time tb later than time ta. When X-ray irradiation is performed at a normal timing, the first X-ray irradiation is after time t12 and before time t13, after time t21 and after time t13. This is performed between the previous time t22. In addition, the second X-ray irradiation is performed between time 23 after time t14 and before time t15, and time t24 after time t23 and before time t15. Become.

  In the case of this irradiation plan B1, the X-ray irradiation of one X-ray apparatus and the X-ray irradiation of the other X-ray apparatus do not overlap. Therefore, in one X-ray apparatus, X-ray irradiation from one operation unit By starting the X-ray irradiation at a normal timing in response to the start input, the X-ray irradiation can be started while avoiding the X-ray irradiation timing of the other X-ray apparatus.

  In addition, in the irradiation plan B2 of one X-ray apparatus, X-ray irradiation is performed twice after input of X-ray irradiation start is performed at time tb. When X-ray irradiation is performed at a normal timing, the first X-ray irradiation is after time t12 and before time t13, after time t13 and after time t14. This is performed between the previous time t26. In addition, the second X-ray irradiation is performed between time t27 after time t14 and before time t15, and time t28 after time t15 and before time t16. Become.

  In the case of this irradiation plan B2, the second X-ray irradiation of the other X-ray apparatus and the first X-ray irradiation of one X-ray apparatus overlap, and the third X-ray irradiation of the other X-ray apparatus and The second X-ray irradiation of one X-ray apparatus overlaps. Therefore, by delaying the timing of X-ray irradiation in one X-ray apparatus by time T1, the first X-ray irradiation is after time t14 and before time t15, and from time t29. Will be performed later and at time t30 before time t15. In addition, the second X-ray irradiation is performed between time t31 after time t16 and time t32 after time t31. Thus, one X-ray apparatus can start X-ray irradiation while avoiding the X-ray irradiation timing of the other X-ray apparatus.

  As shown in the irradiation plan B2a, the X-ray irradiation timing in one X-ray apparatus is delayed by a time T2 longer than the time T1, and the third X-ray irradiation of the other X-ray apparatus is completed. By starting X-ray irradiation of one X-ray apparatus, the X-ray irradiation timing of the other X-ray apparatus may be avoided and X-ray irradiation may be started.

  When one X-ray apparatus is performing X-ray irradiation based on the irradiation plan after step S3 after “Yes” in steps S9, S10, S16, and S17 shown in FIG. 6, the other operation unit When the X-ray irradiation start input is performed, the inspection management device 400 receives permission information for avoiding duplication, the time when the X irradiation start is performed from one X-ray device, and each information of one inspection information. Transmit to the other X-ray device. The other X-ray apparatus performs X-ray irradiation while avoiding the X-ray irradiation timing of one X-ray apparatus based on each information received from the inspection management apparatus 400.

  Thus, when the total power is outside the allowable range and one X-ray apparatus is performing X-ray irradiation according to the irradiation plan, when the X-ray irradiation start input is performed from the other operation unit, X X-ray irradiation priority is given to one X-ray apparatus whose start of X-ray irradiation start is quick, and duplication with one X-ray apparatus is avoided for the X-ray irradiation start input from the other operation unit By permitting the X-ray irradiation, it is possible to reduce the hindrance to the inspection of the other X-ray device without hindering the inspection of the other X-ray device.

  According to the embodiment described above, power for X-ray irradiation of the first and second X-ray apparatuses 100 and 200 is supplied from the first and second power sources 310 and 320, and the first or second power source is supplied. When the capacity of at least one of the power supplies 310 and 320 is insufficient, the power for X-ray irradiation is supplied from the auxiliary power supply 330 instead of the power supply having the insufficient capacity. When power is supplied from the auxiliary power source 330 to the first and second X-ray apparatuses 100 and 200, the power is input from preset determination criteria and the first and second operation units 80 and 180. Determining whether or not the input of the inspection start from one of the first or second operation units 80 and 180 is valid based on the input information such as the first and second inspection information. Can do.

  When the other X-ray apparatus is on standby, the examination start input from one operation unit is validated, and X-rays at the normal timing according to the X-ray irradiation start input from one operation unit By permitting the irradiation, it is possible to prevent the inspection of one X-ray apparatus from being hindered.

  When the other X-ray apparatus is under examination, the total power required for X-ray irradiation of the first and second X-ray apparatuses 100 and 200 is calculated, and the total power is within the allowable range. By enabling the input of the start of examination from one operation unit and allowing the X-ray irradiation at the normal timing according to the input of the X-ray irradiation start from one operation unit, the first and second Interference with inspection of the X-ray apparatuses 100 and 200 can be reduced.

  In addition, the other X-ray apparatus is being inspected, the total power is outside the allowable range, and before the X-ray irradiation start input is performed or the X-ray irradiation stop input is performed from the other operation unit. If there is an irradiation plan in the examination information input from one operation unit, the examination start input from one operation unit is validated, and the X-ray irradiation start input from one operation unit is normal. By permitting X-ray irradiation at this timing, it is possible to reduce the hindrance to the inspection of the first and second X-ray apparatuses 100 and 200.

  In addition, the other X-ray apparatus is being inspected, the total power is outside the allowable range, the other X-ray apparatus is being inspected, and the X-ray irradiation start input is performed or the X-ray irradiation stop input is If there is no irradiation plan in one inspection information, the input of the inspection start from one operation unit is invalidated to avoid a shortage of capacity of the auxiliary power source 330 and the other X-ray apparatus Can prevent the hindrance of inspection.

  In addition, the other X-ray apparatus is being inspected, the total power is outside the allowable range, and before the X-ray irradiation stop input is performed after the X-ray irradiation start input is performed from the other operation unit. Yes, if there is no irradiation plan in the other examination information, the input of the examination start from one operation unit is invalidated, thereby avoiding the shortage of the capacity of the auxiliary power source 330 and hindering the examination of the other X-ray apparatus. Can be prevented.

  In addition, the other X-ray apparatus is being inspected, the total power is outside the allowable range, and before the X-ray irradiation stop input is performed after the X-ray irradiation start input is performed from the other operation unit. Yes, if there is an irradiation plan in the examination information input from the other operation unit, the examination start input from one operation unit is validated, and the other X-ray irradiation start input from one operation unit is valid for the other By permitting X-ray irradiation while avoiding duplication with the X-ray apparatus, it is possible to reduce the interference with the inspection of one X-ray apparatus without interfering with the inspection of the other X-ray apparatus.

  As described above, it is possible to reduce the hindrance to the inspection of the first and second X-ray apparatuses 100 and 200 without increasing the size of the power supply facility of the auxiliary power supply 330.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

80 First operation unit 100 First X-ray device 180 Second operation unit 200 Second X-ray device 300 Power supply device 310 First power supply 311, 321 Secondary battery 320 Second power supply 330 Auxiliary power supply 340 First 1 switching unit 350 second switching unit 360 communication unit 370 power supply control unit 400 inspection management device 500 network

Claims (7)

The input of the first inspection information that enables the start of the first inspection, the input of the inspection start that enables the start of X-ray irradiation based on the first inspection information, and the input of the start of the inspection are performed. A first X-ray diagnostic imaging apparatus having a first operation unit capable of inputting to start X-ray irradiation after
Input of second inspection information that enables the start of the second inspection, input of inspection start that enables the start of X-ray irradiation based on the second inspection information, and input of this inspection start are performed. A second X-ray diagnostic imaging apparatus having a second operation unit capable of inputting to start X-ray irradiation after
A first power source for supplying power for X-ray irradiation to the first X-ray diagnostic imaging apparatus; a second power source for supplying power for X-ray irradiation to the second X-ray diagnostic imaging apparatus; and An auxiliary power source that supplies power for X-ray irradiation to at least one of the first or second X-ray diagnostic imaging apparatus;
A first switching unit that switches a power source that supplies power to the first X-ray diagnostic imaging apparatus to the first power source or the auxiliary power source, and a power source that supplies power to the second X-ray diagnostic imaging apparatus A second switching unit for switching to the second power source or the auxiliary power source;
When power from the auxiliary power source is supplied to the first and second X-ray diagnostic imaging apparatuses, when an inspection start input is performed from one of the first or second operation units , An inspection management device for determining whether or not to enable an input of an inspection start from the one operation unit based on the first and second inspection information and a predetermined determination criterion;
An X-ray diagnostic imaging system comprising:   The inspection management apparatus performs an inspection that makes it impossible to start X-ray irradiation after the other X-ray diagnostic imaging apparatus having the other operation unit of the first or second operation unit receives an input to start an inspection. X-ray irradiation is simultaneously performed by the first and second X-ray diagnostic imaging apparatuses based on the X-ray irradiation conditions included in the first and second inspection information when the inspection is being performed before the end is input. The sum of the power required when it is performed is calculated, and when the calculated total power is within an allowable range, the inspection start input from the one operation unit is validated. The X-ray image diagnostic system according to 1. The inspection management device comprises:
The other X-ray diagnostic apparatus is under examination, the total power is out of an allowable range, and before the X-ray irradiation start input is performed or the X-ray irradiation stop input is performed from the other operation unit. After that, if there is an irradiation plan indicating the X-ray irradiation timing and X-ray irradiation time in one of the inspection information input from the one operation unit, the input of the inspection start from the one operation unit is valid. age,
The other X-ray diagnostic apparatus is under examination, the total power is out of an allowable range, and before the X-ray irradiation start input is performed or the X-ray irradiation stop input is performed from the other operation unit. 3. The X-ray image diagnosis system according to claim 2, further comprising: invalidating an examination start input from the one operation unit when the irradiation plan is not included in the one examination information. 4.   One X-ray diagnostic imaging apparatus having the one operation unit inputs an X-ray irradiation start from the one operation unit after it is determined that an examination start input from the one operation unit is valid. The X-ray image diagnosis system according to claim 2 or 3, wherein X-ray irradiation is performed at a normal timing according to the above. The inspection management device comprises:
The other X-ray diagnostic apparatus is under examination, the total power is out of the allowable range, and the X-ray irradiation start input is performed after the X-ray irradiation start input is performed from the other operation unit. If there is an irradiation plan indicating the X-ray irradiation timing and X-ray irradiation time in the other inspection information input from the other operation unit, the inspection start input from the one operation unit is validated. ,
The other X-ray diagnostic apparatus is under examination, the total power is out of the allowable range, and the X-ray irradiation start input is performed after the X-ray irradiation start input is performed from the other operation unit. The inspection start input from the one operation unit is invalidated when the irradiation plan is not included in the other inspection information. 5. The X-ray image diagnostic system described.   The X-ray image diagnostic apparatus having the one operation unit responds to an input of X-ray irradiation start from the one operation unit after it is determined that an examination start input from the one operation unit is valid. Thus, based on the examination information input from the other operation unit and the time when the X irradiation start is input from the other operation unit, the timing overlapping with the X-ray irradiation of the other X-ray apparatus is avoided. The X-ray image diagnosis system according to claim 5, wherein X-ray irradiation is performed.   The inspection management apparatus is configured to input an inspection start from the other operation unit of the first or second operation unit or after an input of an inspection end that makes it impossible to start X-ray irradiation. The X-ray image diagnosis system according to any one of claims 1 to 6, wherein when waiting, an input of an examination start from the one operation unit is validated.

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