JP2018042593A - Radiographic imaging device, method for controlling rechargeable battery for radiographic imaging device and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To regulate a charging upper limit of a rechargeable battery within a predetermined range even when a deterioration state of the rechargeable battery proceeds.SOLUTION: A device for controlling a rechargeable battery includes setting means for setting a charging upper limit of a rechargeable battery for feeding a load. The setting means raises the charging upper limit of the rechargeable battery as the rechargeable battery deteriorates.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a charging battery control device, a charging battery control method, and a program, and more particularly, to a charging battery control device, a charging battery control method, and a program used for a radiation imaging apparatus.

  Storage batteries (secondary batteries) are generally widely used. For example, in the medical field, radiography that obtains a radiographic image from the intensity distribution of radiation that has been irradiated and transmitted to a subject is widely performed, and a power source is required for the operation of the radiographic apparatus that receives the radiation. In this case, there is a method of supplying power by connecting to an external power supply or other precision equipment by wire, but there is also a method of supplying power from the battery by attaching a secondary battery (hereinafter referred to as a battery) to the radiation imaging apparatus. .

  As the battery, a lead storage battery, a nickel metal hydride battery, a lithium ion battery, and the like are generally known. However, as described in Patent Document 1, Patent Document 2, and Patent Document 3, these generally have a battery capacity depending on use. Is known to deteriorate. In order to prevent battery deterioration, various measures have been taken, including the above-mentioned patent document, but the easiest way to prevent deterioration is to set a charging upper limit without charging the battery fully and set the charging limit. There is known a method of stopping charging when charging is performed up to the upper limit.

Japanese Patent Laid-Open No. 06-302338 Japanese Patent Laid-Open No. 06-310177 JP 2008-159315 A

  However, in the method of setting the charging upper limit, the charging upper limit decreases as the battery deteriorates, and a sufficient charging capacity may not be obtained. For example, the operating time and the number of storable images are designed for the radiography device, but due to insufficient charging capacity, the designed performance cannot be demonstrated, and the radiography device cannot shoot the predetermined number of storable images. The power may be cut off.

  The radiographic apparatus according to the present invention is a radiographic apparatus including a charging battery that supplies power to a load, and a setting unit that sets an upper limit of charging of the charging battery, wherein the setting unit is configured as the charging battery deteriorates. , Raising the charging upper limit of the charging battery.

  According to the present invention, even if the deterioration state of the charging battery progresses, the charging upper limit of the charging battery can be kept within a predetermined range.

It is a block diagram which shows an example of a function structure of the radiography system which concerns on embodiment of this invention. It is a block diagram which shows an example of a function structure of the radiography apparatus which concerns on this embodiment. It is a figure which shows the example of the battery information table which concerns on this embodiment. It is a figure which shows the other example of the battery information table which concerns on this embodiment. It is a flowchart which shows the sequence regarding the setting of the charge upper limit which concerns on this embodiment, and charge of a charge battery. It is a flowchart which shows the count sequence of the count part which concerns on this embodiment. It is a flowchart which shows the sequence of the new charge upper limit setting which concerns on this embodiment. It is a graph of a battery usable capacity | capacitance at the time of using a battery usable capacity | capacitance at the time of using a charge upper limit ratio, and a new charge upper limit ratio. It is a graph of a new charge upper limit ratio.

  The present invention will be described in detail based on the embodiment shown in FIGS. FIG. 1 is a block diagram illustrating an example of a functional configuration of a radiation imaging system according to an embodiment of the present invention.

  An X-ray imaging apparatus (radiography apparatus) 106 controls an X-ray tube 102 that emits X-rays, an X-ray control unit 103 that controls the X-ray tube 102, a sensor unit 101 including a sensor 100, and X-ray imaging. A shooting control unit 104 and an operation display unit 105. The X-ray imaging apparatus (radiation imaging apparatus) 106 captures a radiographic image.

  The operation display unit 105 is a display unit of the X-ray imaging apparatus 106 and displays examination information and a captured image. The operation display unit 105 is an operation input unit of the X-ray imaging apparatus 106, and inputs inspection information, an image processing operation, an inspection progress instruction, and the like. Further, the operation display unit 105 includes an input from an external device such as a magnetic card or a barcode reader.

  The imaging control unit 104 displays the inspection order received from the RIS 108 or the inspection order input by the operator through the operation input unit 105 on the operation display unit 105, and the tube current, the tube voltage, and the irradiation are selected according to the selected imaging protocol. The imaging conditions such as time are sent to the X-ray control unit 103. When the irradiation button is pressed, the X-ray control unit 103 applies a high voltage to the X-ray tube 102 according to the imaging conditions to generate X-rays.

  The sensor unit 101 performs A / D conversion on the electric charge corresponding to the transmitted X-ray dose of the subject detected by the sensor 100 and transfers it to the imaging control unit 104 as an X-ray digital image. The imaging control unit 104 performs various correction processes and image processing on the received X-ray digital image based on the image processing parameters associated with the imaging protocol selected by the operator. The imaging control unit 104 stores the X-ray digital image after image processing in the PACS 109 and outputs it to the viewer 110 or the printer 111 for diagnosis.

  The present invention is applied to an X-ray imaging system as shown in FIG. This X-ray imaging system includes an X-ray imaging apparatus 106 that captures an X-ray digital image. Furthermore, it includes an RIS 108 that is an information system in the radiation department, a PACS 109 that stores and manages an X-ray digital image captured by the X-ray imaging apparatus 106, a viewer 110 that displays a diagnostic X-ray digital image, and a printer 111. These are electrically connected by the network 107.

  FIG. 2 is a diagram illustrating the communication between the sensor 100 and the imaging control unit 104 in detail. As shown in FIG. 2, a portable sensor (radiation detection unit) 202, a charging battery 201 built in the portable sensor 202, and a battery control unit (charging battery control device) 203 perform communication via a network. The battery control unit 203 is a configuration serving as an application example of the information processing apparatus.

  First, the configuration of the rechargeable battery 201 that supplies power to the load will be described. A rechargeable battery 201 is a rechargeable battery having a portable sensor 202 that detects radiation as a load, and includes a transmission / reception unit 204 and a charge information management unit 205. The transmission / reception unit 204 is configured to communicate with the transmission / reception unit 206 of the portable sensor 202, and in particular, transmits battery information of the rechargeable battery 201.

  Here, the battery information is information specific to the charging battery 201, such as a serial number that can uniquely identify the charging battery 201, a manufacturer of the charging battery 201, and a size of the charging battery 201. In addition, the battery information includes the date and time of completion of charging and the remaining amount of charge, which are the latest date information (last charging date and time) when the charging battery 201 is charged. The remaining charge amount is indicated by a ratio between the maximum charge amount and the current charge amount, for example, as in Expression (1).

  (Current charge [wh] ÷ maximum charge [wh]) × 100 = remaining charge [%] (1)

  The transmission / reception unit 204 includes a built-in communication device and firmware for controlling the communication device.

  The charge information management unit 205 mainly measures the remaining charge amount in the rechargeable battery 201 and manages charge date information (charge date and time). The battery information is transmitted to the portable sensor 202 by the transmission / reception unit 204. The remaining charge is measured mainly at the timing when the rechargeable battery 201 is attached to the portable sensor 202, but at other timings when the portable sensor 202 is turned on. The timing of measurement is not particularly limited.

  In addition, by holding the remaining charge information in the memory area in the charge information management unit 205, the remaining charge information can be notified to the transmission / reception unit 204 later even if it is not immediately after the measurement of the remaining charge. Is possible.

  Next, the configuration of the portable sensor 202 will be described. The portable sensor 202 includes a transmission / reception unit 206, a battery information acquisition unit 207, and an image data management unit 208. The transmission / reception unit 206 is configured to communicate with the transmission / reception unit 204 of the charging battery 201 and the transmission / reception unit 209 of the battery control unit 203, and mainly transmits / receives battery information and inspection execution information for each charging battery. The transmission / reception unit 206 includes a built-in communication device and firmware for controlling the communication device.

  The image data management unit 208 stores and manages image data taken by the portable sensor 202. The image data captured by the portable sensor 202 is subjected to correction processing and the like in the image data management unit 208 and transmitted to the battery control unit 203 via the transmission / reception unit 206. At this time, there are cases where the wireless network is not connected well due to noise in the band, and transmission of image data fails. Therefore, the image data management unit 208 stores the image data until the next shooting is performed even after the image data is transmitted, and reliably performs the retransmission when the retransmission request is received.

  The battery information acquisition unit 207 acquires and holds the remaining charge information of the charging battery 201 attached to the portable sensor 202. That is, when the portable sensor 202 is turned on, the battery information acquisition unit 207 instructs the transmission / reception unit 206 to make a battery information notification request.

  However, the timing at which the battery information notification request is made is not limited to this. For example, when a battery information notification is requested from the battery control unit 203, a battery information notification request may be made in response to an external instruction. When the battery information acquisition unit 207 receives the battery information, the battery information acquisition unit 207 stores the battery information in the internal memory.

  The configuration of the battery control unit (charging battery control device) 203 will be described. The battery control unit 203 includes a transmission / reception unit 209, a battery information management unit 210, a count unit 211, and a battery information table. The transmission / reception unit 209 is configured to communicate with the transmission / reception unit 206 of the portable sensor 202. The transmission / reception unit 209 mainly receives battery information and inspection execution information for each charged battery, and transmits a notification request for each information.

The transmission / reception unit 209 is realized by various networks such as Ethernet (registered trademark). The operation display unit 213 is a display device on which image data acquired by the portable sensor 202 is displayed. In addition, the operation display unit 213 displays a control graphic user interface (hereinafter referred to as GUI) for operating the battery control unit 203. Various operations such as image inspection after image data acquisition, image processing, and external image data transmission can be performed by an operation on the GUI by the operator.
The battery information management unit 210 centrally manages battery information using the battery information table 212.

  FIG. 3 is a diagram illustrating an example of the battery information table 212. As shown in FIG. 3, the battery information table 212 stores battery information such as the serial number, remaining charge information, manufacturer, upper limit of charge, and deterioration state of each charged battery. The battery information table 212 also includes the standby power consumption (standby power) of the portable sensor 202, the power consumption during imaging (power consumption per one X-ray imaging), and the power on since the previous charging. The time, the number of images taken since the previous charging, and the battery consumption since the previous charging are held. From these, the deterioration state of the rechargeable battery 201 is determined.

  It should be noted that other information such as the total power-on time, the total number of shots, and the load power consumption since the previous charging can be stored in the battery information table 212 (FIG. 4). In this embodiment, the rechargeable battery is managed by a serial number. Thereby, it is possible to uniquely specify all the rechargeable batteries used in the facility.

  FIG. 5 shows a sequence related to setting of the upper limit of charging and charging of the charging battery. In step S <b> 501, the battery information management unit (setting unit) 210 of the battery control unit 203 can set an arbitrary upper limit for charging the charging battery 201. The battery information management unit 210 sets a charging upper limit of the charging battery 201 that supplies power to the load.

  The battery information management unit 210 sets a charging upper limit below the maximum charging amount of the charging battery 201. For example, the battery information management unit 210 can set the charging upper limit by the ratio of the charging upper limit to the maximum charging amount of the charging battery 201.

  The portable sensor 202 receives the charging upper limit in step S502-1, and stores the charging upper limit in the internal memory of the portable sensor 202 in step S502-2.

  The charging information management unit 205 of the charging battery 201 requests the set charging upper limit in step S503-1, and receives the charging upper limit from the portable sensor 202 in step S503-2. The charging information management unit 205 sets a new charging upper limit (or a ratio of the new charging upper limit to the maximum charging amount of the charging battery 201 described later) based on the charging upper limit received from the portable sensor 202 in step S504 during charging. Set the charging upper limit ratio.

  In step S505-1, the charge information management unit 205 acquires the remaining charge amount of the charge battery 201. In step S505-2, when the charge battery 201 is charged, the charge information management unit 205 determines whether the remaining charge amount has exceeded the upper limit of charge. To do. The charge information management unit 205 continues the charge state when the remaining charge does not exceed the charge upper limit, and stops the charge state when the remaining charge exceeds the charge upper limit.

In step S506, the charging information management unit 205 notifies the portable sensor 202 of battery information such as the charging completion date and time of the charging battery 201. In step S507, the portable sensor 202 saves / updates the battery information such as the charging completion date / time and the remaining charge amount of the charging battery 201 at the charging completion date / time in the internal memory.
FIG. 6 shows a count sequence of the count unit 211.

  The portable sensor 202 requests battery information from the charging battery 201 in step S600-1, and receives battery information from the charging battery 201 in step S600-2.

  In step S601, the count unit 211 of the battery control unit 203 displays a battery on / off notification (including power on / off date / time) of the portable sensor 202 and battery information of a charging battery mounted at that time. Input from the management unit 210. The count unit 211 counts the time when the portable sensor 202 is in a power-on state (power-on time) and the number of times the image data is captured by the portable sensor 202.

  When the power-on of the portable sensor 202 is notified, the count unit 211 manages the charge state of the rechargeable battery 201 in step S602. In step S602, when there is a change in the charging completion date and time at the previous charging, the counting unit 211 updates the charging completion date and time in step S603, and sets the power-on time and the number of photographing times of the portable sensor 202 to the initial values. Reset, and go to step S604. If there is no change in the charging completion date and time at the previous charging in step S602, the counting unit 211 proceeds to step S604.

  When the power-off of the portable sensor 202 is notified in step S604, the count unit 211 notifies the battery information management unit 210 of the battery control unit 203 of the power-on time of the portable sensor 202 in step S605.

  If X-ray imaging has been performed, in step S606, the battery information management unit 210 receives imaging information from the operation display unit 213 or the image data management unit 208 of the portable sensor 202. The count unit 211 counts the number of times the portable sensor 202 is photographed and notifies the battery information management unit 210 of the number of times.

  FIG. 7 shows a sequence for setting a new charge upper limit. The battery information management unit 210 calculates the load power consumption during standby of the portable sensor (radiation detection unit) 202 from the first charging time of the charging battery 201 to the second charging time, which is the next charging time. . The battery information management unit 210 calculates the load power consumption during the radiation detection of the portable sensor (radiation detection unit) 202 from the first charging time of the charging battery 201 to the second charging time. The load power consumption of this embodiment is calculated based on the load standby power consumption, standby time, operation power consumption, and operation time of the load.

  In step S701, the battery information management unit 210 calculates the load power consumption from the previous charging based on the standby power consumption and the imaging power consumption of the portable sensor 202 from Equation (2).

  Load power consumption [wh] = Standby power consumption [w] × Power-on time [h] + Shooting power consumption [wh] × Number of shootings (2)

  The load power consumption includes the standby power consumption of the radiation imaging apparatus from the first charging to the second charging at the next charging, the power-on time (standby time), and the imaging power consumption (operation) Hourly power consumption) and the number of shooting times (operating time). In the expression (2) of the present embodiment, the load power consumption is based on the standby power consumption amount, the power-on time, the photographing power consumption amount, and the number of photographing times of the portable sensor 202 from the previous charging time to the current charging time. A quantity is calculated.

  In step S <b> 702, the battery information management unit 210 manages the charging state of the charging battery 201, and calculates the battery consumption from the previous charging from the difference between the remaining charge at the previous charge and the current remaining charge.

  The battery information management unit 210 calculates the battery consumption amount of the charging battery 201 from the first charging time to the second charging time of the charging battery 201. In the present embodiment, the battery consumption is calculated based on the difference in the remaining charge amount of the charging battery 201 from the first charging time to the second charging time that is the next charging time. In the formula (2) of the present embodiment, the battery consumption is calculated based on the difference in the remaining charge amount of the charging battery 201 from the previous charging time to the current charging time.

  In step S703, the battery information management unit 210 calculates the deterioration state of the charging capacity of the charging battery 201 from the load power consumption and the battery consumption from the previous charging. The battery information management unit 210 is based on the load power consumption during standby of the portable sensor (radiation detection unit) 202, the load power consumption during radiation detection of the portable sensor 202, and the battery consumption of the rechargeable battery 201. The deterioration state is calculated.

  As shown in Expression (2), the deterioration state of the charging battery 201 includes the load power consumption and the battery consumption since the previous charging, the load power consumption and the battery in the state where the charging battery 201 is not deteriorated (initial state). Calculated from the ratio to consumption.

  Degradation state [%] = 100 [%] x ((load power consumption from previous charge [wh] ÷ battery consumption from previous charge [%])) / (initial load power consumption [wh] ÷ Initial battery consumption [%])) (3)

  The deterioration state is calculated based on the load power consumption and the battery consumption from the first charging time to the second charging time which is the next charging time. In equation (3) of the present embodiment, the load power consumption is calculated based on the load power consumption and the battery consumption from the previous charge to the current charge.

  The battery information management unit 210 calculates the ratio of the load power consumption amount of the load from the first charging time of the charging battery 201 to the second charging time of the next charging time and the battery consumption amount of the charging battery 201 as a charging battery. A value obtained by dividing the load power consumption amount of the load from the first reference charging time before the first charging time of 201 to the second reference charging time of the next charging and the battery consumption amount of the charging battery 201. Based on the above, the value of the deterioration state is calculated.

  The deterioration state is calculated based on the load power consumption and the battery consumption from the first reference charge to the second reference charge, which is the next charge. In the expression (3) of the present embodiment, the deterioration state is calculated based on the load power consumption and the battery consumption from the initial charging time of the charging battery 201 to the next charging time.

  The initial state of the charging battery 201 may be a state when the charging battery 201 is manufactured, or may be a state when the charging battery 201 is first built in the portable sensor 202. The initial state of the rechargeable battery 201 may be a state at an arbitrary time when the rechargeable battery 201 is built in the portable sensor 202.

  In step S <b> 704, the battery information management unit 210 calculates a new charge upper limit ratio according to the deterioration state from the charge upper limit ratio and the battery deterioration state using Equation (4). The battery information management unit 210 sets a new charge upper limit at the time of current charge based on a value obtained by dividing the charge upper limit by the value of the deterioration state.

  New charge upper limit ratio [%] = Charge upper limit ratio [%] ÷ (Deterioration state [%] ÷ 100 [%]) (4)

  As described above, the battery information management unit 210 increases the charging upper limit of the charging battery 201 as the charging battery deteriorates. For example, the battery information management unit 210 increases the ratio of the charging upper limit to the maximum charging amount of the charging battery 201 as the deterioration of the charging battery 201 progresses.

  FIG. 8 is a graph of the battery usable capacity when the charge upper limit ratio is used and the battery usable new capacity when the new charge upper limit ratio is used.

  The battery maximum charge amount 801 in FIG. 8A shows a state in which the battery capacity deteriorates with time. The battery usable capacity 802 using the charging upper limit ratio is an actually usable battery capacity in consideration of the deterioration state of the battery. When the charge upper limit ratio is 80% of the maximum battery charge amount 801, the battery usable capacity 802 is 80% of the current maximum battery charge amount 801 (at the time of current charging), and the battery usable capacity 802 is Become.

  The new charge upper limit ratio 803 in FIG. 8B is a value calculated by Expression (4). When the charge upper limit ratio of the formula (4) is 80% of the maximum battery charge amount 801, the new charge upper limit ratio 803 increases as the battery capacity deteriorates with age.

  The new battery usable capacity 804 in FIG. 8A is a battery capacity that can actually be used when the new charge upper limit ratio 803 is set as the charge upper limit ratio. The new battery usable capacity 804 is approximately 80 [%] of the battery maximum charge amount 801 in the initial state even if the battery deteriorates with age, and is substantially constant.

  As shown in FIG. 8A, when the charging upper limit ratio is set to 80 [%], the battery usable capacity 802 that can actually be used and can be reduced as the battery deteriorates over time. However, by using the new charge upper limit ratio of the present embodiment, the battery usable new capacity 804 can be kept within a predetermined range.

  As described above, the present embodiment sets the upper limit of charging of the charging battery 201 that supplies power to the load, and increases the ratio of the upper limit of charging to the maximum charging amount of the charging battery 201 as the deterioration of the charging battery 201 progresses.

As mentioned above, although embodiment which concerns on this invention was described, this invention is not limited to these, It can change and change within the range described in the claim.
Other embodiments according to the present invention will be described.

  It is known that when the charging battery 201 is charged, the lower the charging upper limit or the charging upper limit ratio, the lower the deterioration rate of the battery. The operation of the portable sensor 202 is considered to have a wide variety of operating conditions, such as when it is used for a long time or immediately after a short time of use. Therefore, in step S501 of FIG. 5, the battery information management unit 210 can set a plurality of charging upper limits or charging upper limit ratios according to the operation of the charging battery 201.

  In addition, when the charging frequency is high, it may be difficult to calculate an accurate deterioration state. Therefore, the calculated value of the previous deterioration state is stored in the battery information table 212 of FIG. In step S702 of FIG. 7, if the battery consumption since the previous charging is equal to or less than a predetermined threshold value, it is determined that there is a high possibility that the accuracy of the calculated deterioration state is inappropriate.

  In this case, using the degradation state calculated by the equation (3) from the load power consumption and the battery consumption from the first charging time before the previous charging time to the second charging time at the next charging time. The current new charge upper limit or the new charge upper limit ratio (at the time of current charge) may be calculated.

  In addition, the battery information table 212 of FIG. 2 stores the load power consumption and battery consumption during a plurality of past charges. Then, using the deterioration state calculated by the equation (3) from the load power consumption and the battery consumption from the past first charging time to the second charging time, which is the next charging time, the current (current charging) A new charge upper limit or a new charge upper limit ratio may be calculated.

  In step S704 of FIG. 7, when the new charge upper limit ratio is calculated and the new charge upper limit ratio exceeds 100 [%], it is determined that the charge battery 201 is in a severely deteriorated state and the charge amount cannot be maintained. Then, a warning prompting the user to replace the battery may be notified. The battery information management unit 210 notifies a warning when the deterioration state value exceeds a predetermined threshold value.

  In addition, the deterioration state of the rechargeable battery 201 is determined from at least one of a charge upper limit, current consumption, battery pack temperature upper limit, and usage time based on a capacity deterioration characteristic at the time of storage of the rechargeable battery 201 provided by the manufacturer. May be calculated. The deterioration state of the rechargeable battery 201 may be estimated by capacity deterioration simulation, or may be estimated by a function such as a preset attenuation curve.

  In this case, the battery information management unit 210 calculates the deterioration state based on at least one of the capacity deterioration characteristics during storage of the charge battery 201, the capacity deterioration simulation, and a preset function.

DESCRIPTION OF SYMBOLS 101 Sensor unit 102 X-ray tube 103 X-ray control part 104 Imaging control part 105 Operation input part 105 Operation display part 106 X-ray imaging apparatus (radiography apparatus)
107 network 108 RIS
109 PACS
110 Viewer 111 Printer 201 Rechargeable Battery 202 Portable Sensor (Radiation Detection Unit)
203 Battery control unit 204, 206, 209 Transmission / reception unit 205 Charging information management unit 207 Battery information acquisition unit 208 Image data management unit 210 Battery information management unit (setting unit)
211 count unit 212 battery information table 213 operation display unit

Claims (12)

A radiographic apparatus comprising a charging battery for supplying power to a load, and a setting means for setting a charging upper limit of the charging battery,
The radiographic apparatus according to claim 1, wherein the setting unit raises the charging upper limit of the charging battery as the charging battery deteriorates. A radiographic apparatus comprising a charging battery for supplying power to a load, and a setting means for setting a charging upper limit of the charging battery,
The radiographic apparatus according to claim 1, wherein the setting means increases a ratio of the charging upper limit to a maximum charging amount of the charging battery as the charging battery deteriorates.   The radiation imaging apparatus according to claim 1, wherein the setting unit sets a new charging upper limit at the time of current charging based on a value obtained by dividing the charging upper limit by a deterioration state value. The rechargeable battery is a rechargeable battery having a radiation detection means for detecting radiation as the load,
The setting means includes
Set the upper limit of charge below the maximum charge of the charge battery;
Calculating the load power consumption during standby of the radiation detection means from the first charging time of the charging battery to the second charging time, which is the next charging time,
Calculating the load power consumption during the radiation detection of the radiation detection means from the first charging time to the second charging time of the charging battery;
Calculating a battery consumption amount of the charging battery from the first charging time to the second charging time of the charging battery;
Based on the load power consumption during standby of the radiation detection means, the load power consumption during radiation detection of the radiation detection means, and the battery consumption of the charging battery, the value of the deterioration state of the charging battery To calculate
4. The radiographic apparatus according to claim 1, wherein the ratio of the upper limit of charge to the maximum charge amount of the charge battery is increased as the deterioration of the charge battery progresses. 5.   The setting means calculates a ratio of the load power consumption amount of the load and the battery consumption amount of the charging battery from the first charging time of the charging battery to the second charging time of the next charging time. Divided by the ratio of the load power consumption of the load and the battery consumption of the charging battery from the first reference charging time before the first charging time to the second reference charging time at the next charging time. The radiation imaging apparatus according to claim 1, wherein a value of a deterioration state of the charging battery is calculated based on the value. The load power consumption is calculated based on standby power consumption, standby time, operation power consumption, and operation time of the load,
The radiographic apparatus according to claim 5, wherein the battery consumption is calculated based on a difference in a remaining charge amount of the charging battery from the first charging time to the second charging time. .   The radiographic apparatus according to claim 1, wherein the setting unit notifies a warning when a value of a deterioration state of the charging battery exceeds a predetermined threshold value.   The said setting means calculates the deterioration state of the said charging battery based on at least one of the capacity deterioration characteristic at the time of the preservation | save of the said charging battery, a capacity deterioration simulation, and a preset function. The radiation imaging apparatus according to any one of 1 to 7. The rechargeable battery is a rechargeable battery having a radiation imaging apparatus for capturing a radiation image as the load,
The said setting means calculates the said load power consumption based on the standby power consumption of the said radiography apparatus, power-on time, the imaging power consumption, and the frequency | count of imaging | photography. The radiation imaging apparatus described.   The radiation imaging apparatus according to claim 9, further comprising a counting unit that counts the power-on time and the number of imaging. A charging battery control method for a radiation imaging apparatus comprising a charging battery for supplying power to a load, and a setting means for setting a charging upper limit of the charging battery,
A charging battery control method for a radiation imaging apparatus, comprising a step of raising the charging upper limit of the charging battery as the charging battery deteriorates. The program for functioning a computer as each means of the radiography apparatus of any one of Claims 1 thru | or 10.

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