JP6132572B2 - X-ray diagnostic equipment - Google Patents

Description

  Embodiments described herein relate generally to an X-ray diagnostic apparatus.

  An X-ray diagnostic apparatus arranges an X-ray tube and an X-ray detector so as to face each other, irradiates the subject with X-rays generated by the X-ray tube, and transmits X-rays transmitted through the subject to X-rays It is an apparatus that performs an examination to image an internal form of a subject by detecting with a detector.

  In order to operate the X-ray diagnostic apparatus, a main power source that stably supplies power necessary for the operation to the X-ray diagnostic apparatus is required. A commercial power source was used as the main power source. In addition, there is an X-ray diagnostic apparatus that uses a commercial power source and a battery as a power source for a medical institution in an area where power supply by the main power source is unstable.

JP 2012-129087 A

  Conventionally, a battery of an X-ray diagnostic apparatus that switches between a commercial power source and a battery as a power source reduces the amount of stored electricity due to free discharge while the X-ray diagnostic apparatus is not used. Therefore, in order to prevent the power supplied from the battery from being insufficient, the battery is charged to a fully charged state every time the X-ray diagnostic apparatus is used. As a result, the battery was charged and discharged many times, and the battery life was short. In addition, the battery required a capacity capable of performing a desired test only by supplying power from the battery. In other words, the conventional X-ray diagnostic apparatus includes a large-capacity battery and further has a short battery life. Therefore, the conventional X-ray diagnostic apparatus has high introduction cost and battery replacement cost.

  The problem to be solved by the present invention is to provide an X-ray diagnostic apparatus that can be used in a situation where the power supply from the main power supply is unstable and is low in cost.

The X-ray diagnostic apparatus according to the embodiment includes a main power supply, a battery unit , a high voltage generation unit that applies a high voltage to the X-ray tube, and the main power supply to the high voltage generation unit by monitoring the main power supply. Based on the main power supply monitoring unit that calculates the first power that is possible, and the specified inspection item, it calculates the planned use power that is the power used in the high voltage generation unit, and is supplied from the battery unit A first calculation unit that calculates a second power that is a first power, a first test unit that tests a subject, a calculated value of the first power calculated by the main power supply monitoring unit, and the first power The total power value that is the sum of the calculated power values of 2 is sequentially monitored for the first inspection unit, and when the total power value falls below a specified threshold, the battery unit of the second inspection unit The second test is performed so that power is supplied to the high voltage generation unit of the first test unit. Has a central control unit for controlling said first inspection unit and parts, the.

A block diagram showing composition of an X-ray diagnostic apparatus of an embodiment. The schematic diagram showing the outline of the X-ray diagnostic apparatus of embodiment. The schematic diagram showing the outline of the X-ray diagnostic apparatus of embodiment. The schematic diagram showing the outline of the X-ray diagnostic apparatus of embodiment. The flowchart showing operation | movement of the X-ray diagnostic apparatus of embodiment. A block diagram showing composition of an X-ray diagnostic apparatus of an embodiment. The schematic diagram showing the outline of the X-ray diagnostic apparatus of embodiment. The schematic diagram showing the outline of the X-ray diagnostic apparatus of embodiment. The schematic diagram showing the outline of the X-ray diagnostic apparatus of embodiment. The flowchart showing operation | movement of the X-ray diagnostic apparatus of embodiment.

<First Embodiment>
FIG. 1 is a block diagram showing the configuration of the X-ray diagnostic apparatus 1 of this embodiment. In FIG. 1, a thick line represents a power supply line.

[Constitution]
The X-ray diagnostic apparatus 1 includes a power supply unit 10 and an image diagnostic unit 11.

(Power supply unit 10)
The power supply unit 10 includes a main power supply 100, a main power supply monitoring unit 101, a battery unit 102, and a switching unit 103. The main power supply 100 supplies the first power to the high voltage generator 110. Here, the first power is power supplied from the main power supply 100 to the high voltage generation unit 110. The main power supply 100 includes, for example, an AC commercial power supply. The main power supply 100 may include an emergency generator such as a private power generation facility.

  The main power supply monitoring unit 101 monitors the main power supply 100. The main power supply monitoring unit 101 includes a measurement unit 1010, a first power calculation unit 1011, and an AC / DC conversion unit 1012. The measurement unit 1010 measures the voltage applied from the main power supply 100. The first power calculation unit 1011 receives the voltage measured by the measurement unit 1010 and calculates the first power that can be supplied to the high voltage generation unit 110. The main power supply monitoring unit 101 receives the calculated value of the first power from the first power calculation unit 1011 and outputs it to the power information unit 1100. AC / DC conversion unit 1012 converts AC power from main power supply 100 into DC power and outputs the DC power to high voltage generation unit 110. The main power monitoring unit 101 may directly output the calculated value of the first power to the determination unit 113 without using the power information unit 1100.

  The battery unit 102 supplies the second power to the high voltage generation unit 110. Here, the second power is power supplied from the battery unit 102 to the high voltage generation unit 110. The battery unit 102 includes a secondary battery 1020 and a charge / discharge control unit 1021. The secondary battery 1020 is a battery that can be repeatedly discharged by charging after being discharged, such as a lithium ion battery or a nickel metal hydride battery. The secondary battery 1020 may be configured as an assembled battery in which a plurality of secondary batteries 1020 are combined in series and / or in parallel. The charge / discharge control unit 1021 charges the secondary battery 1020 based on the control signal from the image diagnostic unit 11 and discharges the secondary battery 1020.

  The switching unit 103 receives a control signal from the switching control unit 1101 and switches on / off of the first power and the second power. 2A to 2D are schematic diagrams illustrating an outline of the switching unit 103. FIG. The switching unit 103 includes a first switch SW1 and a second switch SW2. FIG. 2A shows a state in which the first switch SW1 and the second switch SW2 are off. This state is defined as a first supply state. In the first supply state, the first power is supplied to the high voltage generator 110. FIG. 2B shows a state in which the first switch SW1 is on and the second switch SW2 is off. This state is referred to as a second supply state. In the second supply state, the first power is supplied to the high voltage generation unit 110, the first power is supplied to the battery unit 102, and the battery unit 102 is charged. FIG. 2C shows a state in which the first switch SW1 is off and the second switch SW2 is on. This state is referred to as a third supply state. In the third supply state, the second power is discharged from the battery unit 102, and the second power is supplied to the high voltage generation unit 110 together with the first power.

(Image diagnosis unit 11)
The image diagnosis unit 11 includes a high voltage generation unit 110, an X-ray tube 111, a calculation unit 112, a determination unit 113, a control unit 114, an operation unit 115, a display unit 116, a detection unit 117, an image And a generation unit 118. The high voltage generator 110 applies a high voltage to the X-ray tube 111. In addition, the high voltage generation unit 110 includes a power information unit 1100 and a switching control unit 1101. The power information unit 1100 receives the calculated value of the first power from the main power supply monitoring unit 101 and outputs it to the control unit 114. The switching control unit 1101 outputs a control signal to the switching unit 103 based on an instruction from the control unit 114. The X-ray tube 111 generates X-rays based on the voltage applied from the high voltage generator 110.

  The calculation unit 112 calculates planned use power, which is power used by the high voltage generation unit 110, based on the designated inspection item. The inspection item is designated by the user via the operation unit 115 and the control unit 114, for example. The calculation unit 112 reads the inspection condition associated with the designated inspection item from the storage unit 1123, and calculates the scheduled power usage based on the read inspection condition. The inspection conditions are, for example, the number of X-ray images, the fluoroscopy time, the tube voltage and the tube current of the X-ray tube 111. The calculation unit 112 calculates the scheduled power usage by, for example, multiplying the tube current and tube voltage by the number of shots, or multiplying the tube current and tube voltage by the fluoroscopy time. The calculation unit 112 outputs the calculated value of the planned usage power to the determination unit 113.

  In addition, the calculation unit 112 includes a storage amount calculation unit 1120, a second power calculation unit 1121, a time calculation unit 1122, and a storage unit 1123. The storage amount calculation unit 1120 calculates the storage amount of the battery unit 102. For example, the storage amount calculation unit 1120 stores in advance the capacity and charging characteristics of the secondary battery 1020 of the battery unit 102. Here, the charging characteristics represent the correlation between the terminal voltage of the secondary battery 1020 and the charging rate. The storage amount calculation unit 1120 measures the terminal voltage of the secondary battery 1020, and calculates the charging rate of the secondary battery 1020 by referring to the measured battery voltage and charging characteristics. The stored electricity amount calculation unit 1120 calculates the stored electricity amount by multiplying the calculated charging rate by a previously stored capacity. The power storage amount calculation unit 1120 outputs the calculated power storage amount to the second power calculation unit 1121.

  The second power calculation unit 1121 calculates second power that is power supplied from the battery unit 102 to the high voltage generation unit 110 based on the storage amount by the storage amount calculation unit 1120. For example, the second power calculation unit 1121 stores in advance the capacity and discharge characteristics of the secondary battery 1020. Here, the discharge characteristics represent the correlation between the discharge capacity of the secondary battery 1020 and the terminal voltage. The second power calculator 1121 calculates the second power by referring to the amount of stored electricity and the discharge capacity. Second power calculation unit 1121 outputs the calculated calculated value of the second power to determination unit 113.

  The time calculation unit 1122 calculates a charging time that is a time for charging the battery unit 102. At this time, the time calculation unit 1122 obtains the difference between the calculated value of the planned use power by the calculation unit 112 and the total power value by the determination unit 113 as the charge amount. In addition, the time calculation unit 1122 calculates the charging time based on the obtained charge amount, the charging condition, and the capacity of the secondary battery 1020. For example, when the charging current value is constant, the time calculation unit 1122 starts charging from the start of charging until the amount of charge stored in the secondary battery 1020 reaches the determined charging amount based on the charging current value and the capacity of the secondary battery 1020. Is calculated as the charging time. Time calculation unit 1122 outputs the obtained charging time to display control unit 1140.

  The storage unit 1123 stores the inspection item and the inspection condition in association with each other in advance. The inspection conditions are, for example, the number of X-ray images, the fluoroscopy time, the tube voltage and the tube current of the X-ray tube 111.

  The determination unit 113 receives the calculated value of the first power calculated by the main power supply monitoring unit 101 and the calculated value of the planned use power calculated by the calculation unit 112, and calculates the calculated value of the first power and the planned use power. It is determined whether or not the calculated value of the first power is smaller than the calculated value of the planned power usage. Further, when the determination unit 113 determines that the calculated value of the first power is smaller than the calculated value of the planned power usage, the calculated value of the first power and the second power of the second power calculation unit 1121 A total power value that is the sum of the calculated values is obtained, and it is determined whether or not the obtained total power value is smaller than the calculated value of the planned use power. Determination unit 113 outputs the determination result to control unit 114.

  Based on the input from the determination unit 113, the control unit 114 sends a control signal to the switching unit 103 via the switching control unit 1101, and controls the first switch SW1 and the second switch SW2. When the determination unit 113 determines that the calculated value of the first power is smaller than the calculated value of the scheduled power usage, the control unit 114 causes the high voltage generation unit 110 to supply the second power together with the first power. When the control unit 114 supplies the second power to the high voltage generation unit 110, the control unit 114 outputs a control signal to the switching unit 103 via the switching control unit 1101, and the switching unit 103 is in the third supply state. Let me. In addition, when the determination unit 113 determines that the total power value is less than the calculated use power, the control unit 114 supplies the second power to the high voltage generation unit 110 after charging the battery unit 102. Let When the control unit 114 charges the battery unit 102, the control unit 114 receives a test start instruction from the user from the operation unit 115, outputs a control signal to the switching unit 103 via the switching control unit 1101, and switches the switching unit 103. The second supply state is set. That is, the control unit 114 causes the switching unit 103 to be in the second supply state using the inspection start instruction as a trigger, and starts charging the battery unit 102. Then, when the control unit 114 supplies the second power to the high voltage generation unit 110, the control unit 114 controls the switching unit 103 to be in the third supply state as described above. Note that the control unit 114 outputs a control signal to the switching unit 103 via the switching control unit 1101 when the determining unit 113 determines that the calculated value of the first power is not smaller than the calculated value of the planned usage power. The switching unit 103 is set to the first supply state. In addition, when the determination unit 113 determines that the total power value is not less than the calculated use power, the control unit 114 controls the switching unit 103 to be in the third supply state as described above. Note that the control unit 114 may directly output a control signal to the switching unit 103 without using the switching control unit 1101.

  Further, the control unit 114 includes a display control unit 1140. Display control unit 1140 causes display unit 116 to display the charging time received from time calculation unit 1122. Further, the display control unit 1140 causes the display unit 116 to display the image received from the image generation unit 118.

  In response to an operation by the user, the operation unit 115 inputs signals and information corresponding to the contents of the operation to each unit of the apparatus. The operation unit 115 includes, for example, a keyboard, a mouse, various switches, and the like.

  The display unit 116 includes a display device such as an LCD (Liquid Crystal Display) or a CRT (Cathode Ray Tube).

  The detection unit 117 detects X-rays and outputs detection data. The detection unit 117 includes, for example, an image intensifier or an X-ray flat panel detector.

  The image generation unit 118 forms an image based on the detection data from the detection unit 117. The image generation unit 118 is configured to include a computer that functions to convert the detection data received from the detection unit 117 into a digital signal and perform various image processing and the like to generate an image (image data). The image generation unit 118 outputs the generated image to the display control unit 1140.

[Operation]
FIG. 3 is a flowchart showing the operation of the X-ray diagnostic apparatus 1 of this embodiment.

(S01)
The calculation unit 112 calculates planned use power, which is power used by the high voltage generation unit 110, based on the designated inspection item. In addition, the calculation unit 112 outputs the calculated value of the planned usage power to the determination unit 113.

(S02)
The main power supply monitoring unit 101 calculates the first power that can be supplied to the high voltage generation unit 110 by monitoring the first power from the main power supply 100. The main power supply monitoring unit 101 outputs the calculated value of the first power to the power information unit 1100. The power information unit 1100 outputs the calculated value of the first power to the determination unit 113.

(S03)
The determination unit 113 receives the calculated value of the first power calculated by the main power supply monitoring unit 101 and the calculated value of the planned use power calculated by the calculation unit 112, and calculates the calculated value of the first power and the planned use power. It is determined whether or not the calculated value of the first power is smaller than the calculated value of the planned power usage. When the calculated value of the first power is not less than the calculated value of the scheduled power usage, the process proceeds to step S04. When the calculated value of the first power is smaller than the calculated value of the planned usage power, the process proceeds to step S06.

(S04)
The control unit 114 outputs a control signal to the switching unit 103 via the switching control unit 1101 to cause the switching unit 103 to be in the first supply state.

(S05)
The high voltage generator 110 receives the first power and applies a high voltage to the X-ray tube 111. The X-ray tube 111 generates X-rays based on the voltage applied from the high voltage generator 110.

(S06)
The storage amount calculation unit 1120 calculates the storage amount of the battery unit 102. The second power calculation unit 1121 calculates second power that is power supplied from the battery unit 102 to the high voltage generation unit 110 based on the storage amount by the storage amount calculation unit 1120. Second power calculation unit 1121 outputs the calculated calculated value of the second power to determination unit 113.

(S07)
The determining unit 113 obtains a total power value that is the sum of the calculated value of the first power and the calculated value of the second power by the second power calculating unit 1121, and the calculated total power value is a calculated value of the planned power to be used. Determine if it is less. When the total power value is less than the used power value, the process proceeds to step S08. When the total power value is not less than the used power value, the process proceeds to step S10.

(S08)
The control unit 114 receives an inspection start instruction from the user from the operation unit 115, outputs a control signal to the switching unit 103 via the switching control unit 1101, and causes the switching unit 103 to be in the second supply state.

(S09)
Battery unit 102 is charged by receiving first power from main power supply 100. At this time, the time calculation unit 1122 may calculate a charging time that is a time for charging the battery unit 102. Display control unit 1140 causes display unit 116 to display the charging time received from time calculation unit 1122.

(S10)
The control unit 114 outputs a control signal to the switching unit 103 via the switching control unit 1101 to cause the switching unit 103 to be in the third supply state.

(S11)
The high voltage generation unit 110 receives the first power and the second power and applies a high voltage to the X-ray tube 111. The X-ray tube 111 generates X-rays based on the voltage applied from the high voltage generator 110. The operation shown in the flowchart of FIG.

[effect]
The effect of the X-ray diagnostic apparatus 1 of this embodiment will be described.

  The X-ray diagnostic apparatus 1 includes a high voltage generation unit 110, a main power supply 100, a battery unit 102, a main power supply monitoring unit 101, a calculation unit 112, a determination unit 113, and a control unit 114. The high voltage generator 110 applies a high voltage to the X-ray tube 111. The main power supply monitoring unit 101 monitors the main power supply 100 to calculate first power that is the amount of first power that the main power supply 100 can supply to the high voltage generation unit 110. The calculation unit 112 calculates planned use power, which is power used by the high voltage generation unit 110, based on the designated inspection item. The determination unit 113 receives the calculated value of the first power calculated by the main power supply monitoring unit 101 and the calculated value of the planned use power calculated by the calculation unit 112, and calculates the calculated value of the first power and the planned use power. It is determined whether or not the calculated value of the first power is smaller than the calculated value of the planned power usage. When the determination unit 113 determines that the first power amount is less than the scheduled power amount, the control unit 114 generates the second power that is the power supplied from the battery unit 102 together with the first power. To the unit 110. As described above, in a situation where the power supply from the main power supply 100 is unstable, the high voltage generation unit 110 receives power supply from both the main power supply 100 and the battery unit 102 and applies a high voltage to the X-ray tube 111. To do. Thereby, since it is not necessary to cover the planned power usage with only the second power, the capacity of the battery unit 102 mounted on the X-ray diagnostic apparatus 1 can be reduced, and the cost is reduced. In addition, the battery unit 102 does not discharge when the planned use power can be covered only by the first power, and discharges when the planned use power cannot be covered only by the first power. As a result, the number of discharges of the battery unit 102 decreases and the life of the battery unit 102 increases, so that the replacement cost of the battery unit 102 can be reduced. Therefore, it is possible to provide the X-ray diagnostic apparatus 1 that can be used in a situation where the power supply from the main power supply 100 is unstable and is low in cost.

  In addition, the calculation unit 112 may include a power storage amount calculation unit 1120 and a second power calculation unit 1121. The storage amount calculation unit 1120 calculates the storage amount of the battery unit 102. The second power calculation unit 1121 calculates the second power based on the amount of stored electricity. When the determination unit 113 determines that the calculated value of the first power is smaller than the calculated value of the scheduled power usage, the total power value that is the sum of the calculated value of the first power and the calculated value of the second power is further calculated. It is determined whether it is less than the calculated value of the planned power usage. When the determination unit 113 determines that the total power value is smaller than the calculated value of the planned use power, the control unit 114 charges the battery unit 102 and then supplies the second power to the high voltage generation unit 110. In this way, the battery unit 102 is charged only when the total power value is smaller than the calculated value of the planned use power. Thereby, the number of times of charging / discharging of the battery unit 102 is reduced and the life of the battery unit 102 is increased, so that the replacement cost of the battery unit 102 can be reduced. Therefore, it is possible to provide the X-ray diagnostic apparatus 1 that can be used in a situation where the power supply from the main power supply 100 is unstable and is low in cost. Note that the calculation unit 112 may include a time calculation unit 1122. The time calculation unit 1122 calculates a charging time that is a time for charging the battery unit 102. The control unit 114 includes a display control unit 1140, and the display control unit 1140 displays the charging time on the display unit 116. Thereby, the user can grasp | ascertain charging time simply and can perform X-ray diagnostic work smoothly.

  Further, the calculation unit 112 includes a storage unit 1123 that stores the inspection items and the inspection conditions in association with each other in advance, reads out the inspection conditions associated with the designated inspection item from the storage unit 1123, and reads the inspection conditions read out. The planned use power may be calculated based on Thereby, the calculation unit 112 can calculate the scheduled power usage with high accuracy.

<Second Embodiment>
[Constitution]
FIG. 4 is a block diagram showing the configuration of the X-ray diagnostic apparatus 2 of this embodiment. In FIG. 4, a thick line represents a power supply line. Note that in the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, description thereof is omitted, and different components are mainly described.

  The X-ray diagnostic apparatus 2 includes a main power supply 100, a central control unit 20, a central display unit 21, and a plurality of inspection units 22. The inspection unit 22 inspects the subject. The inspection unit 22 includes a main power supply monitoring unit 101, a battery unit 102, a switching unit 220, and the image diagnosis unit 11.

  The central control unit 20 controls the switching unit of each inspection unit so as to supply power from the battery unit 102 of one inspection unit 22 to the image diagnosis unit 11 of the other inspection unit 22. Here, the inspection unit that receives power supply is the first inspection unit 22A, and the inspection unit that supplies power to the first inspection unit 22A is the second inspection unit 22B. The central control unit 20 includes a central storage unit 200 and a central switching control unit 201. The central storage unit 200 receives the inspection item of each inspection unit, the calculated value of the planned power usage, the calculated value of the first power, the calculated value of the second power, and the storage amount from each inspection unit, Remember. The central switching control unit 201 sequentially monitors the total power value of the first inspection unit 22A during the inspection by the first inspection unit 22A, and when the total power value of the first inspection unit 22A falls below the threshold value, The switching unit 220B of the second inspection unit 22B is controlled so that the battery unit 102B of the second inspection unit 22B is charged. The central switching control unit 201 controls the switching unit of each inspection unit so that power is supplied from the battery unit 102B of the second inspection unit 22B to the image diagnosis unit 11A of the first inspection unit 22A.

  For example, when the first inspection unit 22A captures a plurality of X-ray images, the amount of power stored in the battery unit 102A of the first inspection unit 22A decreases each time an X-ray image is captured. In order to prevent the total power of the first inspection unit 22A from becoming insufficient during imaging of a plurality of X-ray images, the central switching control unit 201 sets the total power value of the first inspection unit 22A at a constant time interval. Monitoring, when the total power value of the first inspection unit 22A falls below a threshold value, charging of the battery unit 102B of the second inspection unit 22B is started, and after the charging, the first inspection unit 22B starts the first inspection. Power is supplied to the unit 22A. The threshold value is designated in advance by the user so that charging of the battery unit 102B of the second inspection unit 22B is completed before the total power of the first inspection unit 22A is insufficient. In addition, the central control unit 20 stores the calculated value of the planned use power of each inspection unit, the calculated value of the first power, the calculated value of the second power, and the storage amount stored in the central storage unit 200. The threshold value may be specified by reading and calculating.

  5A to 5C are schematic diagrams illustrating an outline of the switching unit. FIG. 5A shows that the first switch SW1A of the first inspection unit 22A is off, the second switch SW2A is on, the third switch SW3A is off, and the first switch of the second test unit 22B This represents a state in which the switch SW1B, the second switch SW2B, and the third switch SW3B are off. This state is referred to as a fourth supply state. In the fourth supply state, the first power from the main power supply 100 and the second power from the battery unit 102A of the first inspection unit 22A are supplied to the image diagnostic unit 11A of the first inspection unit 22A. The FIG. 5B shows that the first switch SW1A of the first inspection unit 22A is off, the second switch SW2A is on, the third switch SW3A is off, and the first switch of the second test unit 22B This represents a state in which the switch SW1B is on and the second switch SW2B and the third switch SW3B are off. This state is referred to as a fifth supply state. In the fifth supply state, the first power from the main power supply 100 and the second power from the battery unit 102A of the first inspection unit 22A are supplied to the image diagnostic unit 11A of the first inspection unit 22A. In addition, the battery unit 102B of the second inspection unit 22B is charged. FIG. 5C shows that the first switch SW1A of the first inspection unit 22A is off, the second switch SW2A and the third switch SW3A are on, and the first switch of the second inspection unit 22B. The switch SW1B and the second switch SW2B are turned off, and the third switch SW3B is turned on. This state is defined as a sixth supply state. In the sixth supply state, the first power from the main power supply 100, the second power from the battery unit 102A of the first inspection unit 22A, and the power from the battery unit 102B of the second inspection unit 22B Is supplied to the image diagnostic unit 11A of the first inspection unit 22A.

  The central display unit 21 displays the inspection items of each inspection unit stored in the central storage unit 200, the planned power consumption, the first power amount, the second power amount, and the storage amount.

[Operation]
FIG. 6 is a flowchart showing the operation of the X-ray diagnostic apparatus 2 of this embodiment.

(S21)
The central switching control unit 201 controls the switching unit of each inspection unit to be in the fourth supply state.

(S22)
The first inspection unit 22A receives the first power from the main power supply 100 and the second power from the battery unit 102A of the first inspection unit 22A, and performs the inspection.

(S23)
The central switching control unit 201 monitors the total power value of the first inspection unit 22A and compares it with a threshold value. When the total power value does not fall below the threshold value, the process proceeds to step S24. When the total power value falls below the threshold value, the process proceeds to step S25.

(S24)
When the inspection is continued, the process returns to step S22. When the inspection is not continued, the operation is terminated.

(S25)
The central switching control unit 201 controls the switching unit of each inspection unit to be in the fifth supply state.

(S26)
The battery unit 102B of the second inspection unit 22B receives power from the main power supply 100 and is charged.

(S27)
The central switching control unit 201 controls the switching unit of each inspection unit to be in the sixth supply state.

(S28)
The first inspection unit 22A includes a first electric power from the main power supply 100, a second electric power from the battery unit 102A of the first inspection unit 22A, and an electric power from the battery unit 102B of the second inspection unit 22B. And carry out the inspection.

(S29)
When the inspection is continued, the process returns to step S28. When the inspection is not continued, the operation is terminated. The operation shown in the flowchart of FIG.

[effect]
The effect of the X-ray diagnostic apparatus 2 of this embodiment will be described.

  The X-ray diagnostic apparatus 2 has a central control unit 20. The central control unit 20 controls the switching unit of each inspection unit so as to supply power from the battery unit 102B of the second inspection unit 22B to the image diagnosis unit 11A of the first inspection unit 22A. The central control unit 20 includes a central storage unit 200 and a central switching control unit 201. The central storage unit 200 receives the inspection item of each inspection unit, the calculated value of the planned power usage, the calculated value of the first power, the calculated value of the second power, and the storage amount from each inspection unit, Remember. The central switching control unit 201 sequentially monitors the total power value of the first inspection unit 22A during the inspection by the first inspection unit 22A, and the total power amount value of the first inspection unit 22A falls below the threshold value The switching unit 220B of the second inspection unit 22B is controlled so that the battery unit 102B of the second inspection unit 22B is charged. The central switching control unit 201 controls the switching unit of each inspection unit so that power is supplied from the battery unit 102B of the second inspection unit 22B to the image diagnosis unit 11A of the first inspection unit 22A. Thus, the X-ray diagnostic apparatus 2 charges the battery unit 102B of the second inspection unit 22B only when the total power of the first inspection unit 22A can be insufficient during the inspection, and after the charging, Power is supplied from the battery unit 102B of the first inspection unit 22B to the image diagnosis unit 11A of the first inspection unit 22A. As a result, the number of discharges of the battery unit 102 decreases and the life of the battery unit 102 increases, so that the replacement cost of the battery unit 102 can be reduced. Accordingly, it is possible to provide the X-ray diagnostic apparatus 2 that can be used in a situation where the power supply from the main power supply 100 is unstable, and that is low in cost.

  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 embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1, 2 X-ray diagnostic apparatus 10 Power supply part 11 Image diagnostic part 20 Central control part 21 Central display part 22 Inspection part 100 Main power supply 101 Main power supply monitoring part 102 Battery part 103,220 Switching part 110 High voltage generation part 111 X-ray Tube 112 Calculation unit 113 Judgment unit 114 Control unit 115 Operation unit 116 Display unit 117 Detection unit 118 Image generation unit 200 Central storage unit 201 Central switching control unit 1010 Measurement unit 1011 First power calculation unit 1012 AC / DC conversion unit 1020 Two Secondary battery 1021 Charge / discharge control unit 1100 Power information unit 1101 Switching control unit 1120 Power storage amount calculation unit 1121 Second power calculation unit 1122 Time calculation unit 1123 Storage unit 1140 Display control unit

Claims (2)

A main power supply,
Electrostatic Ikebe, high voltage generator for applying a high voltage to the X-ray tube by monitoring the main power supply, the main power source is a main power source monitoring unit for calculating a first power that can be supplied to the high voltage generating unit And based on the designated inspection item, a calculation unit that calculates a planned use power that is a power used in the high voltage generation unit and calculates a second power that is a power supplied from the battery unit Including first and second inspection units for inspecting a subject ;
The total power value that is the sum of the calculated value of the first power and the calculated value of the second power calculated by the main power supply monitoring unit is sequentially monitored for the first inspection unit, and the total power value is designated. The second inspection unit and the first inspection unit are configured to supply power from the battery unit of the second inspection unit to the high voltage generation unit of the first inspection unit when the threshold value is lower than the threshold value. a central control unit for controlling the bets,
An X-ray diagnostic apparatus comprising: The calculation unit includes a storage unit that stores an inspection item and an inspection condition in association with each other, reads the inspection condition associated with the designated inspection item from the storage unit, and reads the inspection condition The X-ray diagnostic apparatus according to claim 1 , wherein the planned use power is calculated based on the calculation result.

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