JP2016038341A - Radiation imaging apparatus, method for controlling radiation imaging apparatus, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To control a plurality of power reception units in accordance with a state of a radiation imaging apparatus.SOLUTION: A radiation imaging apparatus capable of being operated by power of a secondary battery includes: a plurality of power reception units which can receive power for charging the secondary battery in a non-contact manner; a detection unit which detects a state of the radiation imaging apparatus; and a control unit which determines the power reception unit used for charging based on a detection result and controls the power reception unit used for charging and the power reception unit not used for charging.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a radiation imaging apparatus, a method for controlling the radiation imaging apparatus, and a program.

  2. Description of the Related Art An apparatus that irradiates an object with radiation and detects the intensity distribution of the radiation that has passed through the object to obtain a radiation image of the object is widely used in medical diagnosis. Patent Document 1 discloses a radiation imaging apparatus that captures a radiation digital image by a radiation detection unit that enters radiation into a phosphor and converts the corresponding emitted light into electrical information by a semiconductor sensor.

  In recent years, in particular, in order to increase portability, wireless type radiographic apparatuses that do not require cable connection have been developed. Patent Document 2 discloses a configuration in which a radiographic apparatus incorporating a rechargeable battery is connected to a predetermined charger or the like as a wireless type radiographic apparatus, and the rechargeable battery is charged. Patent Document 3 discloses a configuration in which communication is performed between a power receiving unit that does not perform charging and a power transmitting unit in a non-contact charging method.

Japanese Patent No. 3066944 JP 2009-258877 A JP 2011-205867 A

  However, when charging a radiation imaging apparatus with a built-in rechargeable battery as in Patent Document 2, an operation to match the position of the power receiving unit of the radiation imaging apparatus and the power transmission unit of the charger is required each time charging is performed. Load on the user.

  Further, in the configuration in which communication is performed between a power receiving unit that does not perform charging and a power transmission unit as in Patent Document 3, standby power for communication is required, and the power of the rechargeable battery is consumed. For this reason, there may be a case where the power required for shooting is insufficient and shooting cannot be performed.

  The present invention provides a radiation imaging apparatus capable of controlling each of a plurality of power reception units in accordance with the state of the radiation imaging apparatus.

  A radiation imaging apparatus according to one aspect of the present invention is a radiation imaging apparatus operable by power of a rechargeable battery, wherein the power for charging the rechargeable battery can be received in a contactless manner. A detecting unit that detects a state of the radiation imaging apparatus, a power receiving unit that is used for the charging based on a result of the detection, a power receiving unit that is used for the charging, and a power receiving unit that is not used for the charging And a control unit for controlling.

  According to the present invention, it is possible to control each of the plurality of power receiving units according to the state of the radiation imaging apparatus.

The figure which shows the external appearance of the radiography apparatus of 1st Embodiment. Sectional drawing which shows the structural example of the radiography apparatus of 1st Embodiment. The flowchart explaining the flow of a process until charge start. The figure which shows the table for controlling operation | movement of a receiving part exemplarily. The figure which shows the example which accommodates a radiography apparatus in a typical mount apparatus. The figure which shows the example which accommodates a radiography apparatus in a movable type round-trip car. The figure which shows the structural example of the charger provided in the holding | maintenance part. Sectional drawing which shows the structural example of the radiography apparatus of 3rd Embodiment. The figure which shows the external appearance of the radiography apparatus of 3rd Embodiment. The figure explaining illustratively the relative positional relationship of a power transmission part and a power receiving part.

  Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings. However, the components described in this embodiment are merely examples, and the technical scope of the present invention is determined by the scope of the claims, and is not limited by the following individual embodiments. Absent.

(First embodiment)
In the present embodiment, the configuration of a radiation imaging apparatus that can operate with the power of the rechargeable battery will be described. The radiation imaging apparatus has a plurality of power reception units that can receive power for charging the rechargeable battery in a non-contact manner. In addition, the radiographic apparatus determines a detection unit that detects the state of the device, a power reception unit that is used for charging based on a detection result, and controls a power reception unit that is used for charging and a power reception unit that is not used for charging. It has a control part.

  FIG. 1 is a diagram illustrating an appearance of a radiation imaging apparatus 100 according to the present embodiment. FIG. 1A is an external view of the radiation imaging apparatus 100 as viewed from the radiation incident surface, and FIG. 1B is an external view of the radiation imaging apparatus 100 as a surface opposite to the incidence surface. The radiation imaging apparatus 100 has a built-in power receiving unit 9 for receiving power supplied from the power transmitting unit of the charger. A portion indicated by a broken line in FIGS. 1A and 1B indicates an arrangement position of the power receiving unit 9 built in the radiation imaging apparatus 100. As shown in FIGS. 1A and 1B, the power reception unit 9 is provided on the back surface of the housing 3 and the side surface of the housing 3.

  FIG. 2 is a cross-sectional view illustrating a configuration example of the radiation imaging apparatus 100 according to the first embodiment, and is a diagram illustrating an internal cross section when the radiation imaging apparatus 100 in FIG. 1 is viewed from the AA direction. The radiation imaging apparatus 100 includes a radiation detection unit 1 that detects radiation, and the radiation detection unit 1 includes semiconductor elements arranged in a two-dimensional lattice pattern. The radiation irradiated by the radiation generator and transmitted through the subject is detected by the detection unit. Here, the radiation detection part 1 can be comprised from a glass substrate, a semiconductor element, fluorescent substance, a fluorescent substance protective film, etc. The radiation imaging apparatus 100 includes a housing 3, and a housing upper surface panel 3 a is provided on the radiation incident surface side of the housing 3 that houses the radiation detection unit 1.

  The control board 5 includes a control unit that controls the operation of each unit of the radiation imaging apparatus, a storage unit that stores a program, data, or table that processes a signal detected by the radiation detection unit 1, and an external control device (information processing unit). A communication unit capable of communicating with the device. Here, the storage unit is configured by a memory such as a ROM and a RAM, for example, and charging for determining a power receiving unit that can be used for charging among a plurality of power receiving units in the detected state of the radiation imaging apparatus. A table for storing setting information is stored. The control unit determines a power receiving unit to be used for charging from a plurality of power receiving units based on the detection result of the detecting unit, and is in a standby state in which power can be received by turning on the power of the circuit of the power receiving unit to be used for charging. And In addition, for the power receiving unit that is not used for charging, the control unit controls the power supply of the charging circuit to be in an off state so as not to shift to a standby state. When determining the power receiving unit, the control unit can refer to the charging setting information. The charge setting information includes restriction information for restricting a power receiving unit to be used. When power can be received by a plurality of power receiving units as power receiving units used for charging, the control unit uses the charging based on the restriction information. Limit the power receiving unit. Further, the restriction information includes information indicating the priority order of the power receiving units to be used. When a plurality of power receiving units can be used as the power receiving units used for charging, the control unit charges based on the set priority order. Determine the power receiving unit to be used.

  Further, the communication unit can communicate with an external control device (information processing device) and acquire position information of the radiation imaging apparatus. The control unit processes the signal detected by the radiation detection unit 1, and the communication unit transfers the processed signal to an external control device (information processing device). An image based on the transferred signal is displayed on a display unit of an external control device (information processing device) and can be used for diagnosis or the like.

  The control board 5 is connected to the radiation detection unit 1 by the flexible circuit board 4, and the control unit performs read control of data (signal) detected by the radiation detection unit 1 and output control of data (signal). Further, the radiation detection unit 1 and the control board 5 are supported by the base 2 and are disposed inside the housing 3 of the radiation imaging apparatus 100. A detection unit 12 for detecting the state of the radiation imaging apparatus 100 is provided inside the housing 3 of the radiation imaging apparatus 100. The detection unit 12 is connected to the control board 5 via a cable 13 (connection member). The detection unit 12 can transmit information indicating the state of the radiation imaging apparatus 100 detected via the cable 13 to the control unit of the control board 5.

  An impact absorbing member 6 for protecting from an impact force from the outside is disposed on the incident surface side of the radiation detection unit. Further, a radiation shielding member 8 is disposed between the base 2 and the radiation detection unit 1. Furthermore, in order to increase portability, the radiation imaging apparatus 100 is provided with a rechargeable battery 7 that functions as a power source for the radiation detection unit 1, the control unit of the control board 5, the communication unit, and the like. This is supplied to the detection unit 1 and the control board 5.

  As shown in FIGS. 1 and 2, the power receiving unit 9 is provided on the back surface of the housing 3 and the side surface of the housing 3 of the radiation imaging apparatus 100, and the control unit performs charging based on the state of the device. Determine and control the power receiving unit to be used. The power reception unit 9 can receive power supplied from the power transmission unit of the charger, and is connected to the rechargeable battery 7 via the cable 11 (connection member). The power receiving unit 9 charges the rechargeable battery 7 with the supplied power. The arrangement structure in which the power receiving unit 9 is arranged on the back surface portion of the housing 3 and the side surface portion of the housing 3 allows efficient non-contact charging without being blocked by the radiation shielding member 8 for electromagnetic waves for performing non-contact charging. Make it possible to do.

  The inside of the radiation imaging apparatus 100 has the following configuration. From the order of the radiation incident direction, the housing upper surface panel 3a (first member), the shock absorbing member 6 (second member), the radiation detection unit 1, and the radiation shielding member 8 (third) which are the radiation incident surfaces of the housing. And the base 2 (fourth member). Here, the housing upper panel 3 a (first member) and the shock absorbing member 6 (second member) are arranged on the radiation incident direction side with respect to the radiation detection unit 1. The radiation shielding member 8 (third member) and the base 2 (fourth member) are disposed on the opposite side of the radiation incident direction with respect to the radiation detection unit 1.

  Depending on the imaging method for capturing a radiographic image, a subject to be imaged may come into contact with the radiation imaging apparatus 100, so that the casing top panel 3 a that is a radiation incident surface of the casing 3 that houses the radiation detection unit 1 is large. Pressure may be applied. With this configuration, it is possible to reduce the stress applied to the radiation detection unit 1 by the force from the housing top panel 3a side.

  When a radiographic image is captured in the imaging room, it is necessary to change the relative positional relationship between the radiographic apparatus 100 and the subject depending on the part to be imaged and the state of the subject. Therefore, various gantry devices are used to maintain the state in which the radiation imaging apparatus 100 is positioned with respect to the subject. The gantry device can hold and use the radiation imaging apparatus 100 in accordance with various imaging modes.

  FIG. 5 shows, as an example of a gantry device, a gantry device 51 having a stand 30 that is used for photographing a chest and the like in a standing position, and a photographic table that is used for photographing a chest and an abdomen in a lying position. 3 is a view exemplarily showing a gantry device 52 having 32. FIG. For example, the radiation imaging apparatus 100 can be inserted from the insertion port 31 of the holding part B provided in the stand 30 and the radiation imaging apparatus 100 can be held in the holding part B provided in the gantry apparatus 51 and used for imaging. it can. Alternatively, the radiation imaging apparatus 100 is inserted from the insertion port 33 of the holding unit A provided on the front side of the imaging table 32, and the radiation imaging apparatus 100 is held in the holding unit A provided on the gantry device 52 for imaging. Can be used.

  The radiation imaging apparatus 100 needs to appropriately charge the rechargeable battery 7 in order to perform imaging smoothly and hold a sufficient amount of power during imaging. The radiation imaging apparatus 100 may be held by various gantry devices in accordance with the part to be imaged and the posture of the subject, and the rechargeable battery of the radiation imaging apparatus 100 is a charger provided in the holding unit of the gantry apparatus. By charging 7, smooth shooting can be performed.

  In the case of a subject who is difficult to image in the imaging room, for example, as shown in FIG. 6, using a mobile round-the-wheel wheel 40 having a radiation generation unit 41, the radiation generation unit 41 and The subject can be photographed by moving the radiation imaging apparatus 100. The rounding wheel 40 is provided with a holding unit capable of storing and holding the radiation imaging apparatus 100, and is configured to store and hold the radiation imaging apparatus 100 from the insertion port 42 of the holding part. Yes. The radiation generator 41 and the radiation imaging apparatus 100 are moved by the round-wheel 40 to a position where the subject can be imaged, and imaging can be performed by aligning the positions of the radiation generator 41 and the radiation imaging apparatus 100 with the imaging region of the subject. . When moving in the roundabout wheel 40, smooth imaging can be performed by charging the rechargeable battery 7 of the radiation imaging apparatus 100 with a charger provided in the holding unit.

  Charging performed in a non-contact manner between the power transmission unit and the power receiving unit (non-contact charging) is easier to provide a waterproof structure in the radiation imaging apparatus 100 than charging by wired connection, and charging of the operator There is an advantage that the burden of operation can be reduced. On the other hand, in non-contact charging, in order to perform efficient power transfer, it is necessary to match the relative positional relationship between the power transmission unit and the power reception unit. The radiation imaging apparatus 100 according to the present embodiment includes a plurality of power reception units that can receive power for charging a rechargeable battery in a contactless manner, and a detection unit that detects the state of the radiation imaging apparatus. The control unit determines a power receiving unit to be used for charging based on the detection result, and controls a power receiving unit to be used for charging and a power receiving unit not to be used for charging. The control unit controls the power receiving unit used for charging to charge the rechargeable battery 7 of the radiation imaging apparatus 100.

  As shown in FIGS. 1 and 2, the power receiving unit 9 is configured so that the rechargeable battery 7 can be efficiently charged even when the radiation imaging apparatus 100 is held by the holding units of various gantry devices. Are provided at a plurality of locations in the radiation imaging apparatus 100. In the configuration shown in FIGS. 1 and 2, non-contact charging power is received on the back surface, which is the surface opposite to the radiation incident direction of the radiation imaging apparatus 100, and the side surface orthogonal to the housing upper surface panel 3 a which is the radiation incident surface of the housing. One or more parts 9 are arranged.

  The power receiving unit 9 includes a power receiving coil that converts a magnetic field into a current and a charging circuit that rectifies the current generated in the power receiving coil and charges the rechargeable battery 7 with a predetermined voltage. The plurality of power receiving units 9 include power receiving units having different power receiving characteristics. In addition, the plurality of power receiving units include power receiving units having different power receiving directions. For example, in the present embodiment, two power receiving units 9 having different power receiving coil sizes (different power receiving characteristics) are provided on the back surface (first direction in which power can be received) of the radiation imaging apparatus 100, and the side surfaces are provided. One power receiving unit 9 is provided in the unit (second direction in which power can be received). By providing the power receiving units 9 at a plurality of locations, it is possible to increase the number of situations that can support non-contact charging according to the position of the power transmitting unit of the holding unit.

  The detection unit 12 detects whether or not the radiation imaging apparatus is held in the holding unit that is positioned with respect to the subject, and the control unit determines a power reception unit to be used for charging based on the detection result, The power receiving unit used for charging and the power receiving unit not used for charging are controlled. The control unit can individually control the operations of the plurality of power receiving units 9 according to the state of the radiation imaging apparatus 100 (for example, the state not held by the holding unit or the state held by the holding unit). It is.

  Further, the detection unit 12 identifies the holding unit when the radiation imaging apparatus 100 is held by the holding unit, and the control unit determines a power receiving unit to be used for charging based on the identification result and uses it for charging. The power receiving unit and the power receiving unit not used for charging are controlled. The control unit can individually control the operations of the plurality of power receiving units 9 according to the gantry device of the holding unit (for example, the gantry device 51 or the gantry device 52 in FIG. 5) while being held by the holding unit. Is possible.

  The storage unit of the control board 5 stores a table that stores charge setting information for determining a power receiving unit that can be used for charging among the plurality of power receiving units in the detected state of the radiation imaging apparatus. The control unit can determine the power receiving unit to be used for charging based on the detection result of the detection unit indicating the state of the radiation imaging apparatus 100, and can individually control the plurality of power receiving units 9. In this determination, the control unit can refer to the charging setting information in the table.

  FIG. 4 is a diagram exemplarily showing a table in which charge setting information is stored. In FIG. 4A, power reception units 91, 92, and 93 correspond to a plurality of power reception units 9 provided at a plurality of locations in the radiation imaging apparatus 100. Further, examples of the state of the radiation imaging apparatus 100 include a state that is not held by the holding unit and a state that is held by the holding unit B of the gantry device 51 and the holding unit A of the gantry device 52. The state of the radiation imaging apparatus 100 included in the charge setting information is not limited to this example. For example, as described later in the second embodiment and the third embodiment, the position of the radiation imaging apparatus 100, Posture information may be included.

  The detection unit 12 detects whether or not the radiation imaging apparatus is held in the holding unit that is positioned with respect to the subject, and the control unit determines a power reception unit to be used for charging based on the detection result, The power receiving unit used for charging and the power receiving unit not used for charging are controlled. The detection unit identifies the holding unit when the radiation imaging apparatus is held by the holding unit, the control unit determines a power receiving unit to be used for charging based on the identification result, and a power receiving unit to be used for charging. Control the power receiving unit that is not used for charging.

  The detection unit 12 of the housing 3 can be realized by, for example, an eddy current type non-contact sensor. For example, the detection unit 12 is configured to indicate an off state when the radiation imaging apparatus 100 is not held by the holding unit, and to indicate an on state when held by the holding unit. Based on the detection result of the on / off state, the control unit can determine whether or not the radiation imaging apparatus 100 is in a state of being held by the holding unit. In addition, a member for detecting the sensor (detection member) is provided in the holding unit of each gantry device, and the control unit detects which holding unit (the gantry device) the radiographic apparatus 100 based on the detection result of the member by the detection unit 12. ) Can be identified. For example, different materials, different member shapes, and different numbers of detection members are arranged for each holding unit of each gantry device. The detection unit 12 can identify the holding unit of the gantry device that holds the radiation imaging apparatus 100 by detecting the detection member. For example, when the detection unit 12 detects one detection member, the control unit of the control board 5 can determine that the radiation imaging apparatus 100 is held by the holding unit A in FIG. When the detection unit 12 detects a plurality of detection members, the control unit can determine that the radiation imaging apparatus 100 is held in the holding unit B in FIG. Note that the detection unit 12, the configuration of the detection member, and the determination process of the control unit are exemplary, and are not limited to this example. In addition, the configuration of the detection unit 12 is not limited to a non-contact type sensor, and for example, the detection unit 12 configured by a contact type sensor may be disposed on the housing 3.

  Next, the flow of processing up to the start of charging in the radiation imaging apparatus 100 of the present embodiment will be described using the flowchart of FIG. In step S <b> 101, the detection unit 12 detects the state of the radiation imaging apparatus 100. Here, the state of the radiation imaging apparatus 100 includes, for example, a state where the apparatus is not held by the holding unit, and a state where the apparatus is held by the holding unit B of the gantry device 51 and the holding unit A of the gantry device 52. . The state of the radiation imaging apparatus 100 further includes information indicating the state of the position and posture of the radiation imaging apparatus that will be described in detail in the second and third embodiments later.

  In step S102, the control unit determines a power receiving unit to be used for charging based on the detection result (S101) of the detection unit 12. In making this determination, the control unit can refer to the charging setting information in the table (S103). If there is no power receiving unit that can be used in the corresponding state of the radiation imaging apparatus 100, the control unit determines that charging is not possible (S104), and returns the process to step S101. On the other hand, if it is determined in step S102 that there is a power receiving unit that can be used in the corresponding state of the radiation imaging apparatus 100, the control unit advances the process to step S105.

  In step S105, the control unit determines whether there are a plurality of power receiving units that can be used. If one power receiving unit is available, the control unit advances the process to step S106. In step S106, the control unit controls the determined one power receiving unit to enter a standby state where power can be received (power transmission standby state). Charging starts when power is supplied from the power transmission unit. For example, when the radiation imaging apparatus 100 is not held by the holding unit based on the detection result of the detecting unit 12 (S101), the control unit refers to the charging setting information (S103, FIG. 4A), The power receiving unit 91 is determined as a power receiving unit that can be used for charging (S102). The control unit controls the power receiving unit 91 to enter a standby state where power can be received (power transmission standby state) (S106). The control unit controls the power receiving unit 91 to turn on the power supply of the charging circuit to a standby state where power can be received (power transmission standby state). The control unit controls the power receiving units 92 and 93 that are not used for charging so as not to enter the standby state. The control unit performs control so as not to enter the standby state by maintaining the power supply of the charging circuits of the power receiving units 92 and 93 in the off state.

  The power receiving unit 91 determined by the control unit is in a standby state in which power is transferred from a non-contact power transmitting unit outside the radiation imaging apparatus 100, and the other power receiving units 92 and 93 are not in a standby state. . The power receiving units 92 and 93 that do not enter the standby state do not require standby power for transmitting and receiving signals to and from the external power transmission unit, and can suppress power consumption of the rechargeable battery 7 and the power transmission unit of the radiation imaging apparatus 100. it can.

  The power receiving unit used for charging is determined by the control unit based on the detection result of the state of the radiation imaging apparatus 100. At this time, the control unit refers to the charging setting information corresponding to the state of the radiation imaging apparatus 100. For this reason, a control part can determine the power receiving part used for charge, without communicating the information for a charge start with an external power transmission part. As a result, it is possible to reduce the start time until charging is possible while suppressing power consumption of the rechargeable battery 7 and the power transmission unit.

  If it is determined in step S105 that there are a plurality of power receiving units that can be used, the control unit advances the process to step S107 to determine a power receiving unit to be used for charging. At this time, when the restriction information for restricting the power receiving unit to be used is set in the charging setting information stored in the table, the control unit uses the plurality of power receiving units for charging based on the restriction information. The power receiving unit to be determined is determined. When the restriction information is not set, the control unit controls to use the plurality of power receiving units determined in the previous step S102 for charging.

  Here, the process of the control unit in step S107 will be specifically described with reference to FIG. FIG. 10 is a diagram for exemplarily explaining the relative positional relationship between the power transmission unit and the power reception unit. FIG. 10A is a diagram illustrating a configuration in which a plurality of power transmission units 102 are provided on the power supply pad 101 as a charger disposed in the holding unit A (FIG. 5).

  Based on the detection result of the state in which the radiation imaging apparatus 100 is held by the holding unit A (FIG. 5) (S101), the control unit determines a power receiving unit used for charging (S102). At this time, the control unit refers to the charging setting information (FIG. 4A) in the table (S103), and the control unit determines the power receiving unit 91 and the power receiving unit 92 as power receiving units that can be used for charging (S102). And when the restriction | limiting information restrict | limited to use of any one among the power receiving parts 91 and 92 is not set to charge setting information (S108), a control part uses the power receiving part 91 and the power receiving part 92 for charge using the power receiving part (S107). The control unit controls the power receiving units 91 and 92 to enter a standby state where power can be received (power transmission standby state). Further, the control unit controls the power receiving unit 93 that is not used for charging so as not to enter the standby state.

  When a plurality of power receiving units can be used as power receiving units used for charging, the control unit compares the amount of power received from the plurality of power receiving units, and the power receiving unit receives the largest amount of power received from the plurality of power receiving units. It is possible to control to select a part. Thereby, power transfer efficiency can be raised. Further, as the restriction information, it is possible to set the priority order ((1), (2) in FIG. 4A) for selecting a plurality of power receiving units in the charge setting information. When a plurality of power receiving units can be used as the power receiving unit used for charging, the control unit can determine the power receiving unit used for charging based on the set priority (S107).

  The controller can set, for example, a charging time priority mode that prioritizes the charging time required for charging or a transfer efficiency priority mode that prioritizes power transfer efficiency as the charging mode when charging the rechargeable battery 7. When charging is performed in the transfer efficiency priority mode, the control unit determines, based on the priority set as the restriction information, the power receiving unit with the largest amount of power that can be received as the power receiving unit to be used for charging. The power receiving unit is controlled so as to charge the rechargeable battery 7 via the power receiving unit. On the other hand, when the restriction information is not set, the control unit sets the charging time priority mode, the control unit determines all the power receiving units that can be used for charging as power receiving units that are used for charging, and determines the determined power receiving unit. The power receiving unit is controlled so as to charge the rechargeable battery 7.

  In order to select a power receiving unit, a selection unit (such as a switch) for selecting the power receiving unit is provided in the housing 3 of the radiation imaging apparatus 100, and an operator operates the selection unit to select a power receiving unit that receives power. You may decide. When a plurality of power receiving units can be used as the power receiving unit used for charging, the control unit controls the power receiving unit selected by the selection unit as the power receiving unit used for charging, and the unselected power receiving unit is charged. Control as an unused power receiving unit. The power receiving unit determined based on the operation of the selection unit is put into a standby state in which power can be received from outside as described above by the control unit. When another power receiving unit has already received power, the control unit switches the power receiving unit so that the power receiving unit selected by the selection unit receives power from the power transmitting unit.

  The radiation imaging apparatus 100 includes a display unit that displays the state of the power reception unit. The display unit can display a power receiving unit that is charging or a power receiving unit that is controlled in a transmission standby state. The operator can confirm the power receiving unit determined as the power receiving unit to be used for charging by the display on the display unit. Further, the operator can confirm the charging state of the radiation imaging apparatus 100 and the transmission standby state by displaying on the display unit. If there is no power receiving unit that can be used for charging in the process of step S102, the control unit determines that charging is not possible (S104). In this case, the control unit can control the display unit to display notification information for notifying the operator that charging is not possible. As a result, the control unit can prompt the operator to put the device into a state where it can be charged.

(Modification)
As the sensor constituting the detection unit 12, a GPS sensor that acquires position information of the radiation imaging apparatus 100 can be used in addition to the above configuration. For example, in a photographing room for photographing, the position information of the gantry device 51 having the stand 30 used for photographing the chest and the like in the standing position and the gantry including the photographing table 32 used for photographing the chest and the abdomen in the prone position. Assume that the position information of the device 52 is known. In this case, the control unit compares the position information of the known gantry device and the position information of the GPS sensor, and the control unit determines whether the radiation imaging apparatus 100 is held by the holding unit B of the gantry device 51 or the gantry device 52. It can be determined whether it is held by the holding unit A. The control unit determines a power receiving unit used for charging based on the detection result of the GPS sensor, and controls a power receiving unit used for charging and a power receiving unit not used for charging.

  According to the present embodiment, it is possible to control each of the plurality of power receiving units according to the state of the radiation imaging apparatus. While suppressing the power consumption of the rechargeable battery, it is possible to efficiently charge while dealing with various charging environments and reducing the burden of the charging operation of the operator.

(Second Embodiment)
In the present embodiment, based on the detection result of the posture of the radiation imaging apparatus 100, the control unit determines a power receiving unit to be used for charging, and controls a power receiving unit used for charging and a power receiving unit not used for charging. explain. The configuration of the radiation imaging apparatus has the same configuration as that of FIGS. 1 and 2 described in the first embodiment. Further, when determining the power receiving unit, the control unit can refer to the charging setting information (FIG. 4B) in the table corresponding to the detection result of the detecting unit 12. A control part determines the power receiving part used for charge based on the result of the detection of an attitude | position. Here, FIG. 4B shows a power receiving unit used when the radiation imaging apparatus 100 is in a horizontal posture (horizontal state) and a power receiving unit used when the radiation imaging device 100 is in a vertical posture (vertical state). It is a figure which illustrates the charge setting information of the table shown.

  In the present embodiment, a three-dimensional gravity sensor or a three-dimensional acceleration sensor can be used as a sensor constituting the detection unit 12 that detects the posture of the radiation imaging apparatus 100 as the configuration of the detection unit 12. The three-dimensional acceleration sensor can handle gravitational (static acceleration) measurement. For example, the orientation (posture) of the radiation imaging device relative to the ground can be detected from the sum of the acceleration vectors of the X, Y, and Z axes. can do.

  FIG. 7 is a diagram illustrating a configuration example of a charger provided in the holding unit. When a charger configured to insert the radiation imaging apparatus 100 into the insertion opening 61 of the cradle 60 is used, the posture of the radiation imaging apparatus during charging is determined. On the other hand, it is possible to use a so-called charging pad 62 having a flat shape without a cradle 60 or an insertion slot. The detection unit 12 detects the attitude of the radiation imaging apparatus 100, and the control unit determines whether the radiation imaging apparatus 100 is held by a holding unit of a type having the cradle 60 based on the detection result of the detection unit 12 or a charging pad. It is determined whether it is held by a holding unit of the type using 62.

  FIG. 10B is a diagram illustrating a state in which the radiation imaging apparatus 100 is held in the cradle 60 in which the power transmission unit 102 is provided. In a state where the radiation imaging apparatus 100 is held by the cradle 60, the control unit refers to the charge setting information of the table (FIG. 4B) based on the posture (vertical posture) detected by the detection unit 12. The power receiving unit 93 is determined as the power receiving unit used for charging.

  If the radiation incident surface of the radiation imaging apparatus intersects the incident direction (vertical direction) of radiation irradiated from the radiation generating unit (horizontal posture), the control unit is placed on the surface opposite to the radiation incident surface. The arranged power receiving units 91 and 92 are determined as power receiving units used for charging. This state corresponds to, for example, the state shown in FIG. The control unit turns on the power supply of the power receiving unit 91 and the charging circuit of the power receiving unit 92 to enter a standby state in which power can be received (power transmission standby state). And about the power receiving part 93 which is not utilized for charge, a control part leaves the power supply of a charging circuit in an OFF state (control not to transfer to a standby state).

  On the other hand, if the posture of the radiation imaging apparatus 100 is a posture (vertical posture) in which the radiation incident surface is parallel to the radiation incident direction (vertical direction), the control unit receives power received on a surface perpendicular to the radiation incident surface. The part 93 is selected (FIG. 10B). The control unit determines the power receiving unit 93 as a power receiving unit to be used for charging, and turns on the power supply of the charging circuit of the power receiving unit 93 to enter a standby state where power can be received (power transmission standby state). And about the power receiving part 91 and the power receiving part 92 which are not utilized for charge, a control part leaves the power supply of a charging circuit in an OFF state (control not to transfer to a standby state).

  When a plurality of power receiving units 93 are arranged in a direction perpendicular to the paper surface and can be used for charging, the control unit receives power among the plurality of power receiving units as in the first embodiment. It is possible to perform control so that the power receiving unit with the largest amount of electric power is selected.

  Moreover, the priority order ((1), (2) in FIG. 4B) to be selected for a plurality of power receiving units is set in the charging setting information as the restriction information, and the control unit is based on the set priority order. The power receiving unit can be determined. In addition, in order to select the power receiving unit, a selection unit (such as a switch) for selecting the power receiving unit is provided in the housing 3 in place of the table (FIG. 4B) referred to when determining the power receiving unit. The operator may operate the selection unit to determine a power receiving unit that receives power. When a plurality of power receiving units can be used as the power receiving unit used for charging, the control unit controls the power receiving unit selected by the selection unit as a power receiving unit used for charging, and selects a power receiving unit not selected by the selection unit. Control as a power receiving unit not used for charging.

  According to the present embodiment, it is possible to control each of the plurality of power receiving units according to the state of the radiation imaging apparatus. While suppressing the power consumption of the rechargeable battery, it is possible to efficiently charge while dealing with various charging environments and reducing the burden of the charging operation of the operator.

(Third embodiment)
In this embodiment, based on the position information of the radiographic apparatus, a power receiving unit to be used for charging is determined from among a plurality of power receiving units of different contactless charging methods, and a power receiving unit to be used for charging and a power receiving unit not to be used for charging A configuration for controlling the above will be described. Non-contact charging methods include an electromagnetic induction method, a magnetic resonance method, and an electric field coupling method. The power transfer distance and the like vary depending on each method. In general, the magnetic resonance method has lower power transfer efficiency than the electromagnetic induction method, but the power transfer distance can be transferred to a longer distance than the electromagnetic induction method. By increasing the power transfer distance, if the power transmission unit is installed within the range of the power transfer distance in the environment where the radiation imaging apparatus 100 is used, an operator load such as installing the radiation imaging apparatus in the charger is not required. In addition, charging can be performed.

  The control unit determines a power receiving unit to be used for charging among a plurality of power receiving units of different contactless charging methods based on position information of the radiation imaging apparatus, and a power receiving unit to be used for charging and a power receiving unit not to be used for charging To control. For example, in a radiographing room using the radiation imaging apparatus 100, the control unit controls the power receiving unit so as to perform charging by a magnetic resonance method. When charging in a place outside the radiographing room, the control unit controls the power receiving unit so that charging is performed by an electromagnetic induction method in a state where the radiographic apparatus 100 is held in a dedicated charger or the like. As described above, there are a plurality of types of non-contact charging methods, and in order to perform charging with a non-contact charging method adapted to various imaging environments, the inside of the radiation imaging apparatus 100 has the following configuration. .

  FIG. 9 is a diagram illustrating an appearance of the radiation imaging apparatus 100 according to the third embodiment. FIG. 9A is an external view of the radiation imaging apparatus 100 as viewed from the radiation incident surface, and FIG. 9B is an external view as viewed from the back of the radiation imaging apparatus 100 that is the surface opposite to the incident surface. The radiation imaging apparatus 100 is provided with a power receiving unit 9 and a power receiving unit 10 for receiving power supplied from a power transmission unit of a charger. The power receiving unit 9 is a power receiving unit capable of non-contact charging by an electromagnetic induction method, and the power receiving unit 10 is a power receiving unit capable of non-contact charging by a magnetic resonance method. Note that the non-contact charging method in this embodiment is illustrative and is not limited to this example. As shown in FIGS. 9A and 9B, the electromagnetic induction power receiving unit 9 is provided on the back surface of the housing 3 and the side surface of the housing 3. Further, as shown in FIG. 9B, the power receiving unit 10 using the magnetic field resonance method is provided on the back surface of the housing 3. By providing a plurality of power receiving units corresponding to different non-contact charging methods in the radiation imaging apparatus 100, it is possible to increase situations and opportunities that can support different non-contact charging methods in various imaging environments. The power reception unit 9 and the power reception unit 10 can receive power supplied from the power transmission unit, and are connected to the rechargeable battery 7 via the cable 11 (connection member). The power receiving unit 9 and the power receiving unit 10 charge the rechargeable battery 7 with the supplied power.

  FIG. 8 is a cross-sectional view illustrating a configuration example of the radiation imaging apparatus 100 according to the third embodiment, and is a diagram illustrating an internal cross section when the radiation imaging apparatus 100 in FIG. 9 is viewed from the AA direction. Similar to the configuration of FIG. 2 described in the first embodiment, the radiation detection unit 1 and the control board 5 are included in the housing 3. The control board 5 is connected to the radiation detection unit 1 by the flexible circuit board 4, and the control unit of the control board 5 performs read control of data (signal) detected by the radiation detection unit 1 and output control of data (signal). Do. Further, the radiation detection unit 1 and the control board 5 are supported by the base 2 and are disposed inside the housing 3 of the radiation imaging apparatus 100. A detection unit 12 for detecting the state of the radiation imaging apparatus 100 is provided inside the housing 3 of the radiation imaging apparatus 100. The detection unit 12 is connected to the control board 5 via a cable 13 (connection member). The detection unit 12 can transmit information indicating the state of the radiation imaging apparatus 100 detected via the cable 13 to the control unit of the control board 5.

  In the present embodiment, the communication unit of the control board 5 can perform wireless LAN communication such as Wi-Fi (Wireless Fidelity) with an external device. The communication unit communicates with an external control device (information processing device) and acquires position information of the radiation imaging apparatus. The control unit can acquire the position information of the radiation imaging apparatus 100 via the communication unit. The radiation imaging apparatus 100 can also include a GPS sensor as a configuration of the detection unit 12, and the control unit can acquire position information of the radiation imaging apparatus 100 detected by the GPS sensor.

  The control unit determines a power receiving unit to be used for charging based on a comparison between the known position information of the photographing room and the position information acquired by the communication unit or the position information detected by the detection unit, and is used for charging. To control the power receiving unit to be used and the power receiving unit not to be used for charging. When determining the power receiving unit, the control unit can refer to the charging setting information (FIG. 4C) in the table. FIG. 4C is a diagram illustrating charging setting information of a table indicating a power receiving unit used when the radiation imaging apparatus 100 is in the imaging room and a power receiving unit used when the radiation imaging apparatus 100 is outside the imaging room. is there.

  It is assumed that the position information of the shooting room where shooting is performed is known. The control unit determines a power receiving unit to be used for charging based on a comparison between the known position information and the position information acquired by the communication unit or the position information by the detection unit 12 (GPS sensor), and receives the power to be used for charging. Control unit and a power receiving unit not used for charging.

  The control unit compares the position information of the known photographing room with the position information acquired via the communication unit or the GPS sensor, and the radiation photographing apparatus 100 is located in the photographing room or located outside the photographing room. It is determined whether or not. When the radiation imaging apparatus 100 is located in the imaging room, the control unit determines the power receiving unit 10 that performs charging by the magnetic resonance method as a power receiving unit to be used for charging, and turns on the power supply of the charging circuit of the power receiving unit 10 to receive power. Control to possible standby state (transmission standby state). And a control part leaves the power supply of a charging circuit in the OFF state about the power receiving part 9 which is not utilized for charge (it controls not to transfer to a standby state).

  When the radiation imaging apparatus 100 is located outside the imaging room, the control unit determines the power receiving unit 9 that performs charging by electromagnetic induction as the power receiving unit to be used for charging, and turns on the power supply of the charging circuit of the power receiving unit 9. And control to a standby state where power can be received (power transmission standby state). And about a power receiving part 10 which is not utilized for charge, a control part leaves the power supply of a charging circuit in an OFF state (control not to transfer to a standby state).

  When a plurality of power receiving units can receive power, as described in the first and second embodiments, the control unit determines a power receiving unit to be used for charging based on the priority set as the restriction information. It is possible.

  Further, the control unit can perform control so as to select a power receiving unit having the largest amount of power received from among the plurality of power receiving units. In addition, in order to select the power receiving unit, a selection unit (such as a switch) for selecting the power receiving unit is provided in the housing 3 in place of the table (FIG. 4C) referred to when determining the power receiving unit. The operator may operate the selection unit to determine a power receiving unit that receives power. When a plurality of power receiving units can be used as the power receiving unit used for charging, the control unit controls the power receiving unit selected by the selection unit as a power receiving unit used for charging, and selects a power receiving unit not selected by the selection unit. Control as a power receiving unit not used for charging.

  According to the present embodiment, it is possible to control each of the plurality of power receiving units according to the state of the radiation imaging apparatus. While suppressing the power consumption of the rechargeable battery, it is possible to efficiently charge while corresponding to various charging environments and charging methods and reducing the burden of the charging operation of the operator.

(Other embodiments)
The present invention can also be realized by executing the following processing. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, or the like) of the system or apparatus reads the program. It is a process to be executed.

100: radiation detector, 1: radiation detector, 2: base
3: Housing, 4: Flexible circuit board, 5: Control board (control unit),
7: Rechargeable battery 9,10: Power receiving unit

Claims (17)

A radiography apparatus operable by the power of a rechargeable battery,
A plurality of power receiving units capable of receiving power for charging the rechargeable battery in a contactless manner;
A detection unit for detecting a state of the radiation imaging apparatus;
Determining a power receiving unit to be used for the charging based on the detection result, and a control unit for controlling the power receiving unit to be used for the charging and the power receiving unit not to be used for the charging;
A radiation imaging apparatus comprising: A storage unit for storing a table for storing charging setting information for determining a power receiving unit to be used for charging among the plurality of power receiving units in the detected state of the radiation imaging apparatus;
The control unit determines a power receiving unit to be used for charging from the plurality of power receiving units based on the detection result and the charge setting information, and turns on the power of the power receiving unit to be used for the charging. In a standby state where power can be received,
The radiographic apparatus according to claim 1, wherein the power receiving unit that is not used for charging is controlled so as to maintain a power supply in an off state and not shift to the standby state. The charge setting information includes restriction information for restricting a power receiving unit to be used,
The radiographic imaging according to claim 2, wherein when receiving power by a plurality of power receiving units as the power receiving unit used for charging, the control unit limits the power receiving unit used for charging based on the restriction information. apparatus. The restriction information includes information indicating the priority order of the power receiving unit to be used,
The control unit determines a power receiving unit to be used for charging based on the set priority order when a plurality of power receiving units can be used as the power receiving unit to be used for the charging. The radiation imaging apparatus described.   When a plurality of power receiving units can be used as the power receiving unit used for the charging, the control unit compares the amount of power received from the plurality of power receiving units, and the power receiving unit receiving the largest amount of power is charged. The radiation imaging apparatus according to claim 1, wherein the radiation imaging apparatus is determined as a power reception unit to be used for the radiography. A selection unit that selects a power receiving unit to be used for charging from the plurality of power receiving units;
When a plurality of power receiving units can be used as the power receiving unit used for the charging, the control unit controls the selected power receiving unit as the power receiving unit used for the charging, and the unselected power receiving units are The radiation imaging apparatus according to claim 1, wherein the radiation imaging apparatus is controlled as a power receiving unit that is not used for charging. The control unit can set, as a charging mode when charging the rechargeable battery, a charging time priority mode that prioritizes charging time required for charging, or a transfer efficiency priority mode that prioritizes power transfer efficiency,
The control unit, when charging in the transfer efficiency priority mode, determines the power receiving unit with the most power as the power receiving unit used for the charging,
3. The radiographic apparatus according to claim 1, wherein, when charging is performed in the charging time priority mode, the control unit determines a power receiving unit usable for charging as a power receiving unit used for the charging. 4. . The detection unit detects whether or not the radiation imaging apparatus is held in a holding unit that is positioned with respect to the subject,
The control unit determines a power receiving unit to be used for the charging based on the detection result, and controls a power receiving unit to be used for the charging and a power receiving unit not to be used for the charging. The radiation imaging apparatus according to any one of 1 to 7. The detection unit identifies the holding unit when the radiation imaging apparatus is held by the holding unit;
The said control part determines the power receiving part used for the said charge based on the result of the said identification, and controls the power receiving part used for the said charging, and the power receiving part not used for the said charging. The radiation imaging apparatus described in 1. The detection unit detects the posture of the radiographic apparatus,
The said control part determines the power receiving part used for the said charge based on the detection result of the said attitude | position, and controls the power receiving part used for the said charging, and the power receiving part not used for the said charging. Item 8. The radiation imaging apparatus according to any one of Items 1 to 7. The detection unit detects position information of the radiation imaging apparatus,
The control unit determines a power receiving unit to be used for the charging based on a comparison between known position information and a result of detection of the position information by the detecting unit, and the power receiving unit to be used for the charging and not to be used for the charging. The radiation imaging apparatus according to claim 1, wherein the radiation receiving apparatus is controlled.   The radiation imaging apparatus according to claim 1, wherein the plurality of power reception units include power reception units having different power reception characteristics.   The radiation imaging apparatus according to claim 1, wherein the plurality of power receiving units include power receiving units having different directions in which power can be received.   The radiation imaging apparatus according to claim 1, wherein the plurality of power receiving units include power receiving units having different contactless charging methods. A display unit for displaying a power receiving unit controlled by the control unit;
The radiation imaging apparatus according to claim 1, wherein when the plurality of power receiving units cannot be charged, the control unit controls the display unit to display notification information. . A method for controlling a radiation imaging apparatus having a plurality of power receiving units capable of receiving power for charging a rechargeable battery in a non-contact manner,
Detecting a state of the radiation imaging apparatus;
Determining a power receiving unit to be used for the charging based on the detection result;
A method for controlling a radiographic apparatus, comprising: a step of controlling a power receiving unit used for charging and a power receiving unit not used for charging.   The program for making a computer perform each process of the control method of the radiography apparatus of Claim 16.

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