JP2014054566A - Radiographic apparatus and control method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radiographic apparatus capable of notifying a photographer whether a charging state is sufficient for ordered photographing or not by monitoring how much photographable power is left in an imaging device, and control method thereof.SOLUTION: The radiographic apparatus includes a generation unit for generating radiation, and a battery for supply the generation unit with electric power. The radiographic apparatus acquires management information including a photographing order by the radiographic apparatus, and outputs information relating to excess/deficiency of the residual amount of the battery for the photographing order on the basis of the photographing order and the charged amount of the battery.

Description

  The present invention relates to a portable radiographic apparatus and a control method thereof.

  Conventionally, imaging devices that irradiate an object and detect the intensity distribution of the radiation that has passed through the object to obtain a radiation image of the object are widely used in industrial nondestructive inspection and medical diagnosis. Has been. As a general photographing method in such a photographing apparatus, there is a film / screen method. This is a method of performing radiography by combining a photosensitive film and a phosphor having sensitivity to radiation. That is, a sheet of rare earth phosphor that emits light upon irradiation is held in close contact with both sides of the photosensitive film, and the radiation transmitted through the subject is converted into visible light by the phosphor. Capture this light. The latent image formed on the film can be visualized by developing it by chemical processing.

  On the other hand, with the advancement of digital technology in recent years, a method of obtaining a high-quality radiographic image by converting a radiographic image into an electric signal, processing the electric signal, and reproducing it as a visible image on a CRT or the like has become widespread. Yes. As a system using such a method of converting a radiation image into an electrical signal, a transmission image of radiation is once accumulated as a latent image in a phosphor, and then the latent image is photoelectrically irradiated by exciting light such as laser light. A radiation image recording / reproducing system that obtains a visible image by automatically reading out has been proposed.

  Further, with recent progress in semiconductor process technology, an apparatus for taking a radiation image using a semiconductor sensor has been developed. These systems have a very wide dynamic range as compared to conventional radiographic systems using a photosensitive film, and are practical in that radiographic images that are not affected by fluctuations in the exposure dose of radiation can be obtained. Has advantages. At the same time, unlike the conventional photosensitive film system, there is an advantage that no chemical treatment is required and an output image can be obtained immediately.

  FIG. 9 is a conceptual diagram showing a system using such a radiation image capturing apparatus 103. The radiation emitted by the radiation generation apparatus 101 is irradiated on the subject 102, and the radiation transmitted through the subject reaches the radiation detection sensor 104 built in the radiation image capturing apparatus 103. In the radiation detection sensor 104, the radiation is converted into visible light through a phosphor, and is detected as an electrical signal by photoelectric conversion elements arranged in a two-dimensional lattice. A control unit 105 is provided that controls the radiation detection sensor 104 such as reading drive and image transfer. The control unit 105 performs digital image processing on the image signal output from the radiation detection sensor 104 and displays the image signal on the monitor 106 as a radiation image of the subject 102. The system shown in FIG. 9 is advantageous in that an image can be monitored immediately, unlike the above-described radiation image recording / reproducing system that reads out an image in post-processing. In such an imaging system, the radiation detection sensor 104 is installed on a dedicated gantry according to the imaging mode such as standing position or lying position, and is used properly as necessary.

  Conventionally, this type of imaging apparatus has been installed and used in a radiation room. However, in recent years, a thin and lightweight portable imaging device (referred to as an electronic cassette) has been developed in order to enable imaging of a wide range of parts more quickly. As a result, an imaging system that can be applied not only to cassette imaging in a radiation room but also to the field of round visits has been proposed (see Patent Document 1). Such an imaging system has a problem that it is necessary to carry a number of cassettes for storing conventional films and fluorescent screens in round-trips, and that it is time-consuming to re-photograph because an imaging mistake cannot be immediately confirmed. It is a very useful system because it can solve both problems.

JP-A-11-99144

  The mobile radiation imaging apparatus as described above is driven by a battery. Here, it is necessary to avoid a situation in which imaging cannot be performed due to a battery exhaustion during round-trip imaging.

  The present invention has been made in view of the above problems, and monitors how much power that can be photographed in the photographing apparatus is charged, and determines whether the charge state is sufficient for the ordered photographing. The purpose is to be able to notify.

In order to achieve the above object, a radiation imaging apparatus according to an aspect of the present invention has the following configuration. That is,
A generator that generates radiation; and
A radiography apparatus having a battery for supplying electric power to the generator,
Acquisition means for acquiring management information including an imaging order by the radiation imaging apparatus;
Output means for outputting information relating to excess or deficiency of the remaining amount of the battery with respect to the imaging order based on the imaging order and the charge amount of the battery.

  With this configuration, it is possible to determine whether the state of charge is sufficient for the ordered shooting and inform the photographer of this information.

It is side surface sectional drawing of the imaging | photography part in 1st Embodiment. It is a figure explaining the structure of the mobile imaging device in 1st Embodiment. It is a flowchart explaining operation | movement of the mobile imaging device in 1st Embodiment. It is a figure explaining the structure of the mobile imaging device in 2nd Embodiment. It is a figure explaining the screen structure of the operation part in 2nd Embodiment. It is a figure explaining the screen structure in 3rd Embodiment. It is a figure explaining the movable imaging device in 4th Embodiment. It is a figure explaining the movable imaging device in 5th Embodiment. It is a figure explaining a general radiography system. It is a figure which shows the example of a list display of the management information in an operation part.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In each of the following embodiments, a medical imaging apparatus (X-ray imaging apparatus) for imaging a subject (human body) using X-rays will be described as an example of the radiographic imaging apparatus of the present invention. It is also possible to apply the invention to an X-ray imaging apparatus for imaging a subject other than a human body or an imaging apparatus using other radiation (for example, an electron beam or a gamma ray).

<First Embodiment>
FIG. 1 is a side sectional view of a photographing unit in the present embodiment, and FIG. 2 is a diagram for explaining the configuration of a mobile photographing apparatus according to the present embodiment. FIG. 3 is a flowchart for explaining the operation of the mobile photographing apparatus of this embodiment.

  In FIG. 1, an X-ray detection panel 1 is mainly composed of a fluorescent plate 1a, a photoelectric conversion element 1b, and a substrate 1c. As the substrate 1c, a glass plate is often used because it has no chemical action with a semiconductor element, can withstand the temperature of a semiconductor process, and needs for dimensional stability. Photoelectric conversion elements 1b are formed in a two-dimensional array on such a glass substrate 1c by a semiconductor process. The fluorescent plate 1a is obtained by applying a phosphor of a metal compound to a resin plate, and is integrated with the substrate 1c by adhesion.

  The X-ray detection panel 1 having the above configuration is fixedly supported on a metal base 2 to ensure mechanical strength. The circuit board 3 is mounted with electronic components 3 a and 3 b that process the electrical signals converted by the photoelectric conversion element 1 b, and is connected to the photoelectric conversion element 1 b by the flexible circuit board 4, and is provided on the back side of the base 2. It is fixed via the projection 2a. The base 2 is fixed to the housing body 5a via the support portion 2b, sealed with an X-ray transmissive housing lid 5b and housed in the housing 5, and the imaging unit 10 is configured as an electronic cassette. Further, a cable 6 for supplying power to the circuit board 3 and the like and transmitting signals such as image signals and control signals is connected to the photographing unit 10 via the relay unit 7 and the like.

  Such an imaging unit 10 is combined with the mobile X-ray generator 20 for round trips and used as a mobile imaging device 50. A configuration in the present embodiment will be described with reference to FIG.

  The movable photographing apparatus main body 21 is installed on a carriage unit 22 having a plurality of wheels 23 and 24, and can be arbitrarily moved. A rotation detection sensor 25 provided in the carriage unit 22 detects the rotation of the wheel 24, and this detection signal is used to detect whether or not the photographing apparatus 50 is in a moving state. The rotation detection sensor 25 can be realized by a simple method such as a rotary encoder. On the other hand, the support | pillar 26 is vertically supported by the trolley | bogie part 22 so that rotation around an axis | shaft is possible. An arm 27 is provided that extends in the horizontal direction with respect to the column 26 and is supported so as to be slidable in the vertical direction. An X-ray generator 28 including an X-ray tube is attached to the arm 27 so as to be slidable in the horizontal direction along the arm 27 and rotatable about the axial direction of the arm 27. Thereby, the irradiation direction of the X-rays by the X-ray generator 28 can be arbitrarily adjusted. The X-ray generation unit 28 is provided with a grip 29, and the grip 29 is further provided with a contact sensor (not shown). When the contact sensor detects that the operator has gripped the grip 29, the lock that prohibits the movement of each mechanism such as the arm 27 and the X-ray generation unit 28 is released, and the X-ray is within the range where the rotation and sliding are possible. The tube can be positioned at a desired position and posture.

  Further, inside the main body 21, a driving circuit 30 including an electric circuit that controls tube driving for X-ray irradiation, locking of a mechanism unit, and the like, a battery 31 for supplying power to each part of the mobile imaging device 50, A control unit 32 for controlling the imaging unit 10 and the X-ray generation unit 28 to obtain a captured image is disposed. The control unit 32 mainly includes a storage unit that stores a captured image obtained by digitally processing an image signal from the imaging unit 10, first and second operation units 34 and 36 that provide an interface with an operator, An interface unit for linking the line generator 28 and the imaging unit 10 and a controller for controlling them are provided.

  The control unit 32 instructs the drive circuit 30 to generate X-rays in the X-ray generation unit 28 via the cable 33. The X-ray generator 28 and the drive circuit 30 are connected by a cable 19, and a drive signal and power are supplied to the X-ray generator 28. The drive circuit 30 controls exposure by sending a drive signal to the X-ray generation unit 28 in accordance with an X-ray generation instruction from the control unit 32.

  The drive timing of the X-ray detection panel 1 needs to be controlled so as to be interlocked with the exposure from the X-ray generation unit 28. For this reason, the imaging unit 10 is connected to the control unit 32 by the cable 6, and a drive signal is transmitted from the control unit 32 to the imaging unit 10 via the cable 6. The cable 6 is intended to supply power to the image capturing unit 10 and to transmit image signals and control signals to and from the image capturing unit 10, and has flexibility and power supply and signal transfer so that there is no inconvenience in operation. It has a sufficient length as long as there is no.

  The first operation unit 34 used for the operation of the imaging unit 10 and the mobile X-ray generator 20 includes a monitor for display output and an input device for operation input. Has been. As the input device, for example, a combination of a selection key for switching selection items on the monitor display and a determination button for determining selection, a touch panel arranged on the monitor screen, and the like are conceivable. On the monitor of the first operation unit 34, an imaging region is selected and the imaging unit 10 is changed to a state where imaging is possible, and imaging conditions such as tube voltage, tube current, and irradiation time of the X-ray generation unit 28 are set. An operation menu is displayed. These items in the operation menu are selected and set with an input device, and desired shooting is performed. That is, in the first operation unit 34, various settings relating to the imaging unit 10 and the X-ray generation unit 28 and instructions for imaging operations are performed. In addition, a series of operations until the captured image is stored in the storage unit built in the control unit 32 using the input device of the first operation unit 32 is performed on the captured image. be able to.

  The battery 31 is connected to the drive circuit 30, the imaging unit 10, the control unit 32, and the like to supply power to each unit, and can be charged from the outside via the AC cable 35. Electric power for operating the mobile imaging device 50 is charged in advance to the battery 31 through the AC cable 35 during a time period when there is no shooting operation, and the AC cable 35 is housed inside the apparatus main body 21 during movement.

  In addition, the control unit 32 incorporates a software module (management module) for managing management information such as information on a patient for whom X-ray imaging has been ordered, imaging conditions, imaging history, and the like. Such a management module may be realized by a control unit separate from the control unit 32. As shown in FIG. 2, a second operation unit 36 is connected to the control unit 32, and the management module displays management information on a monitor of the second operation unit 36 (for example, displays a list of patients). The management content can be confirmed by the operator. When the list display does not fit on one screen, screen scrolling can be instructed via an input device provided in the second operation unit 36. The management information can be obtained by communicating with an external terminal in the hospital (not shown) via an external communication connector 37 connected to the control unit 32. In this example, it is assumed that an external terminal is connected to an RIS terminal that realizes connection with an RIS (Radiology Information System). However, the system for connecting this apparatus is not limited to RIS, and can be applied to other arbitrary systems such as HIS (Hospital Information System). Note that such a communication process is also supported by the management module.

  Next, the operation of the mobile imaging device 50 will be described. FIG. 3 is a flowchart for explaining the operation (processing procedure by the control unit 32) of the mobile imaging device 50 according to the present embodiment.

  First, in step S101, it is determined whether or not the control unit 32 is connected to an external RIS (Radiology Information System) terminal via the external communication connector 37. If it is determined that the terminal is connected to the RIS terminal, the process proceeds to step S102. For example, management information is fetched from the RIS terminal in accordance with an operation of the operator with respect to the second operation unit 36, or management results including the photographing result are stored in the RIS terminal. Or output information. In step S103, the management information is displayed in a list on the second operation unit 36.

  As described above, the operator (engineer) connects the control unit 32 of the mobile imaging apparatus 50 and the in-hospital RIS terminal via the external communication connector 37, and acquires management information including an order of X-ray imaging. 50 side can be transferred. The transferred management information is displayed as a list on the second operation unit 36, and the engineer can confirm the management information. With this display, the operator can plan a rough schedule for the round-trip imaging in consideration of the priority and the moving route. The contents displayed in the list include, for example, patient information such as a patient name and sex, a room number, imaging requirements such as an imaging region and an imaging posture, as shown in FIG.

  When the above preparation is completed, the operator starts moving to a predetermined hospital room while pushing the mobile imaging device 50 in accordance with the scheduled schedule.

  When the mobile imaging device 50 is moved, the operator does not operate the X-ray imaging unit 28 or the imaging unit 10 in order to safely move the device. In the present embodiment, in order to prevent unnecessary operations from occurring due to unnecessary operations (operations on the X-ray imaging unit 28 and the imaging unit 10) in these moving states, and to prevent unnecessary power consumption. In addition, a function that is not used in the moving state is automatically suspended according to the detection of the movement of the apparatus. This function reduces power consumption when moving. As described above, the mobile imaging device 50 detects the rotation of the wheel 24 and detects the movement state of the mobile imaging device 50. In the present embodiment, when the rotation detection sensor 25 detects a speed of a certain level or more, it is determined that the apparatus is in a moving state, and the function to be paused is automatically paused.

  The function to be paused is a function of various operations including settings for the X-ray generator 28 and the imaging unit 10. In the present embodiment, this is dealt with by stopping the operation function of the first operation unit 34. As a result, it is possible to prevent malfunctions such as inadvertently touching an input device such as an operation key to drive the drive circuit 30 or the photographing unit 10, and not only suppress power consumption but also safety during movement. Can also be secured.

  On the other hand, display of a list of patient information may be necessary even in a moving state in order to determine a schedule for round trip imaging. As described above, the second operation unit 36 displays a list that enables confirmation of a hospital room and confirmation of a patient's name. Accordingly, the second operation unit is caused to function even when the mobile imaging device 50 is in the moving state. As a result, the functions of patient information list display and list access (display scrolling, etc.) are effective even when the apparatus is in a moving state.

  In order to realize the above operation, whether or not the mobile photographing device 50 is in a moving state is detected based on detection of the rotation of the wheel 24 by the rotation detection sensor 25. If it is detected that the mobile device is in the moving state, the process proceeds from step S104 to step S109, the first operation unit 34 is set in a sleep state, and the process returns to step S101.

  When the movement of the mobile photographing device 50 is completed and the stop is detected by the rotation sensor 25, the process proceeds from step S104 to step S105, and the function of the first operation unit 34 is restored. When various imaging settings are made by the first operation unit 34 and an instruction to start imaging is given, the process proceeds from step S106 to step S107, and X-ray imaging by the X-ray generation unit 28 and the imaging unit 10 is started. The When the X-ray imaging is finished, the process proceeds to step S108, the corresponding management information is updated, and the process returns to step S101. In the management information update, for example, “taken” is set for the shooting order, or information for associating the shot image stored in the storage unit with the shooting order is recorded. Thereafter, when the management information list display is updated in step S103, the captured information is reflected in the “shooting” field shown in FIG. 10 (the corresponding field changes from “not yet” to “already”). become.

  For example, when the operator moves the mobile imaging device 50 and arrives at a predetermined hospital room and stops moving, the first operation unit 34 becomes operable (step S105). Thereafter, the operator adjusts the position of the X-ray generation unit 28 with respect to a predetermined imaging posture, and then selects an imaging region using the first operation unit 34, the tube voltage (kV) of the X-ray generation unit 28, and the tube current ( mA), shooting conditions such as shooting time (mS) are confirmed and set, and an instruction to start shooting is given. X-ray imaging is executed in accordance with this imaging start instruction (steps S106 and S107). When the X-ray imaging is completed, the fact that the imaging has been performed is reflected as the management information of the patient, and the management information is automatically updated (step S108).

  The updated management information is then displayed on the operation unit 36 in step S103, so that the operator sees this display, whether there is a next imaging order, if there is any room to go to, etc. Can be easily determined. That is, if there is an imaging order that has not been taken in the management information list that is displayed, it moves to the next hospital room and repeats the X-ray imaging by the series of operations and processes described above. When there is no longer an imaging order, the operator returns the mobile imaging device 50 to a predetermined standby position. Further, the control unit 32 of the mobile imaging device 50 and the in-hospital RIS terminal can be connected via the external communication connector 37, and the updated management information can be output to the RIS terminal (steps S101 and S102). .

  Various methods are conceivable as a method for suspending functions such as setting and driving of the X-ray generator 28 and the imaging unit 10. In the first embodiment, since operations for setting, driving, and the like of the X-ray generator 28 and the imaging unit 10 are performed using the first operation unit 34, the following measures can be taken. For example, it is conceivable to simply turn off the power supply to the first operation unit 34. Alternatively, a method of turning off the output to the first operation unit 34 (display output, including a backlight in the case of liquid crystal) and not reacting to the input operation to the first operation unit 34 may be considered.

  In addition, as described above, several effects can be considered in which the first and second operation units are separated. For example, by configuring the second operation unit 36 to be attachable to and detachable from the photographing apparatus main body 21, it is possible to configure the operator so that it can be carried alone as an information terminal such as a PDA. In this case, for example, it is possible to add a new function such as urgent shooting order communication (for example, an emergency order can be received wirelessly and confirmed by being carried during standby). Or, you can take an emergency order as another terminal). In addition, the monitor can be configured according to specifications such as resolution required for each of the first and second operation units 34 and 36. For example, the menu screen for shooting control does not require so much resolution, and conversely, if the resolution is increased, the amount of information such as operation icons increases. On the other hand, the list display desirably outputs a large amount of information on one screen, and a display with high resolution is desired. Accordingly, it is desirable that the resolution of the monitor in the first operation unit 34 is relatively low and the resolution of the monitor in the second operation unit 36 is higher than that.

  In the above embodiment, the rotation of the wheel 24 of the carriage 22 is detected by using an encoder or the like to determine whether or not the apparatus is in a moving state. However, the present invention is not limited to this. For example, it may be determined that the X-ray generation unit 28 is in a moving state by detecting that the X-ray generation unit 28 is accommodated in a predetermined position (for example, a position described later in the fourth embodiment (FIG. 7)). Alternatively, for example, release of a brake state by a brake mechanism provided in the carriage 22 may be detected, and it may be determined whether or not the vehicle is in a moving state based on this detection. From these viewpoints, it will be understood that the movement state of the device can include not only that the device is actually moving, but also that the device is movable. Further, the brake may be released mechanically, or the X-ray generator 28 is accommodated at a predetermined position (for example, at a position described later in the fourth embodiment (FIG. 7)). May be detected and the brake may be released. Further, the photographing unit 10 may be detachable from the main body 21 and may be configured to detect that the photographing unit 10 has been detached from the main body 21 and release the brake state. Of course, it may be determined that the photographing unit 10 is in the moving state by detecting that the photographing unit 10 has been removed from the main body 21. Further, if the carriage 22 includes a motor that drives the wheels, it may be determined that the vehicle is in a moving state when a driving instruction is given to the motor.

  As described above, according to the first embodiment, functions that are not used during movement are paused, while functions that are useful during movement are maintained, so that standby power is not hindered in operation. Consumption can be suppressed, and unnecessary power consumption due to malfunction can be suppressed.

Second Embodiment
In the first embodiment, a configuration is provided in which the first operation unit 34 for performing setting and driving operations on the X-ray generation unit 28 and the imaging unit 10 and the second operation unit 36 for displaying management information are provided separately. explained. The merits when the first and second operation units are separate are as described above. However, when the cost is more important than these merits, it is conceivable that the operation unit is constituted by a single unit. In the second embodiment, an example of realizing erroneous operation prevention and power saving in such a case will be described.

  FIG. 4 is a schematic configuration diagram illustrating the configuration of the mobile imaging device 51 according to the second embodiment. The first embodiment is the same as the first embodiment except that the first operation unit 34 and the second input / output 36 are configured by a single operation unit 40. The operation unit 40 has a display device as an output unit and a touch panel provided on the display device as an input unit. And each function of the 1st and 2nd operation parts 34 and 36 of 1st Embodiment is implement | achieved by switching the screen on a display device.

  FIG. 5 is a diagram showing a display example of the display device according to the second embodiment. As shown in FIG. 5A, on the first screen 41, an operation area 42 for selecting a region to be imaged, and confirmation / setting of imaging conditions for the X-ray generation unit 28 and / or the imaging unit 10, etc. An operation area 43 is arranged. On the other hand, as shown in FIG. 5B, the second screen 44 has a list 45 (for example, a list based on management information as shown in FIG. 10A) for displaying patient information and imaging requirements. Is displayed. These can be switched alternately by selecting the screen switching key 46.

  When it is detected that the mobile photographing device 51 is in a moving state (for example, the moving state is detected based on a signal from the rotation detection sensor 26), the screen is automatically switched to the second screen 44, and the screen is switched. By making the key 46 unusable, switching to the first screen 41 is disabled. By doing so, similarly to the first embodiment, it is possible to prevent an operation (erroneous operation) while moving to the X-ray generation unit 28 or the imaging unit 10, thereby achieving power saving.

<Third Embodiment>
In the second embodiment, the screen is switched in one operation unit 40, thereby preventing an erroneous operation when the apparatus is in a moving state. In the third embodiment, one screen is divided into a plurality of areas, and an erroneous operation is prevented by providing an area that does not accept an operation input while the mobile photographing apparatus is in a moving state.

  FIG. 6 is a diagram showing a display example of the input / output device 40 according to the third embodiment. In the example of FIG. 6, the screen on the display device is divided into a display area 47 and a display area 48. In the display area 47, a screen display for operations on the X-ray generation unit 28 and the imaging unit 10 is displayed. The patient information list display based on the management information (list display as shown in FIG. 10A) is performed. When the movement of the mobile photographing apparatus is detected, the output to the first display area is automatically turned off so as not to react to the input. It should be noted that only the display area 47 may be the region that does not respond to input. In this way, since it responds to an input to the display area 48, it is possible to cope with a case where scrolling is necessary in the patient information list display.

<Fourth embodiment>
The fourth embodiment of FIG. 7 has the same configuration of the input / output means as the third embodiment, but uses a different method of pausing. During movement, it is desirable to return the X-ray generator itself to a predetermined position for safety. Therefore, the first display area 47 divided by the X-ray generator 28 is hidden and the second display area 48 is accommodated above the imaging apparatus main body 21 so as not to be hidden. As a result, the first display area 47 cannot be physically accessed, and a function of preventing inadvertent operation can be provided. At the same time, the imaging apparatus has means for detecting that the X-ray generation unit is at a predetermined storage position, and has a function of prohibiting movement of the imaging apparatus when it is not at the predetermined position. Therefore, the first display area 47 is surely hidden by the X-ray generator during movement.

  In the present embodiment, it is detected that the X-ray generator 28 is accommodated in the above position, and the brake state of the brake mechanism provided in the carriage 22 is released by this detection, so that the apparatus can move. To do.

  The above is a case where a single operation unit is used, but the same method can be applied to the case of the first embodiment provided separately as the first and second operation units. In this case, for example, it can be realized by setting the storage position of the X-ray generation unit 28 so that only the first operation unit 34 is hidden and the second operation unit 36 is not hidden. Further, instead of hiding the first operation unit with the X-ray generation unit, a second operation unit formed separately may slide on the first operation unit to hide the first operation unit. In this case, the brake state is released by detecting that the second operation unit is disposed on the first operation unit.

<Fifth Embodiment>
It is necessary to avoid a situation in which imaging cannot be performed due to the battery running out during the rounds. Therefore, there is a demand for a function that can monitor in advance how much power that can be photographed is charged as a photographing apparatus. In other words, while realizing the measures to reduce power consumption as described above, it is also notified of the power consumption necessary for future shooting, and whether the current charging state can cover such power consumption It is also desirable to do. In the fifth embodiment, an imaging apparatus capable of performing such notification will be described. The configuration of the mobile imaging device is the same as that of the first embodiment (FIGS. 1 and 2). Hereinafter, notification processing regarding the power of the mobile imaging device according to the fifth embodiment will be described with reference to FIG.

  First, when management information including an imaging order or the like is taken into the mobile imaging apparatus 50 from the RIS terminal, information (patient information) about a patient for whom imaging is ordered is acquired from the management information (step S201). Since the captured management information includes tube voltage, tube current, and irradiation time as imaging requirements, the power consumption of the X-ray generator 28 can be calculated for each ordered imaging. The total power consumption is calculated by calculating and accumulating this for all photographing orders. On the other hand, if the irradiation time is known, the time for driving the X-ray detection panel 1 of the imaging unit 10 can be known, so the power consumption required by the imaging unit 10 can also be calculated. By adding the power consumed by the control unit 32 and the first and second operation units 32 and 36 to these, the total power consumption can be predicted (step S202).

  On the other hand, the controller 32 monitors the state of charge of the battery 31 (step S200), and compares the power consumption estimated in step S202 with the power charged in the battery 31 (step S203). In this way, it is possible to determine whether the charging state is sufficient or insufficient for the ordered photographing, and inform the operator of this information (step S204). As a method for notifying this information, simply mark the order that can be photographed on the list displayed on the second operation unit 36, which is a numerical display or a graph-like display for the power required for the photographing order. It can be realized by displaying. For example, as shown in FIG. 10B, it can also be realized by indicating whether or not photographing is possible during list display.

  As described above, according to the fifth embodiment, the required battery capacity is estimated from the imaging order notified by the management information, and the excess or shortage of the charge amount is manipulated by comparing this with the current battery capacity. Can be informed. For this reason, it is possible to operate efficiently, such as adjusting the shooting schedule in advance.

  Needless to say, the X-ray imaging apparatus of the above-described embodiment can be variously modified without departing from the scope of the claims.

Claims (11)

A generator that generates radiation; and
A radiography apparatus having a battery for supplying electric power to the generator,
Acquisition means for acquiring management information including an imaging order by the radiation imaging apparatus;
Output means for outputting information on excess or deficiency of the remaining amount of the battery with respect to the photographing order based on the photographing order and the charge amount of the battery;
A radiation imaging apparatus comprising:   The radiation imaging apparatus according to claim 1, wherein the output unit notifies an imaging order that can be executed among the acquired imaging orders.   The radiation imaging apparatus according to claim 1, wherein the output unit outputs information indicating whether or not the imaging order is executable. A calculation means for calculating the amount of power required for shooting based on management information including a shooting order;
A comparison unit that compares the amount of power calculated by the calculation unit with a charge amount of a battery that supplies power to the radiation imaging apparatus;
The radiation imaging apparatus according to claim 1, further comprising:   The radiographic apparatus according to claim 4, wherein the output unit outputs the result of the comparison. It has an imaging unit that detects radiation and obtains radiation images,
The radiation imaging apparatus according to claim 1, wherein the battery supplies power to the imaging unit. A generator that generates radiation; and
An imaging unit that detects radiation and obtains a radiation image;
A radiography apparatus having a carriage on which the generator and the imaging unit are mounted and moved;
Acquisition means for acquiring management information including order information of imaging by the radiation imaging apparatus;
A calculation means for calculating the amount of power required for shooting based on management information including a shooting order;
A comparison unit that compares the amount of power calculated by the calculation unit with a charge amount of a battery that supplies power to the radiation imaging apparatus;
Output means for outputting the result of the comparison;
A radiation imaging apparatus comprising: An imaging unit that detects radiation and obtains a radiation image;
A battery for supplying power to the imaging unit;
Output means for outputting information relating to excess or deficiency of the remaining amount of the battery with respect to the imaging order based on the imaging order by the imaging unit and the charge amount of the battery;
A radiation imaging apparatus comprising: A control method for a radiation imaging apparatus, comprising: a generator that generates radiation; and a battery that supplies power to the generator.
An acquisition step of acquiring management information including an imaging order by the radiation imaging apparatus;
An output step of outputting information on excess or deficiency of the remaining amount of the battery with respect to the photographing order based on the photographing order and the charge amount of the battery;
A control method for a radiation imaging apparatus, comprising: A radiation imaging apparatus control method comprising: a generator that generates radiation; an imaging unit that detects radiation to obtain a radiation image; and a carriage that mounts and moves the generator and the imaging unit,
An acquisition step of acquiring management information including order information for imaging by the radiation imaging apparatus;
A calculation step for calculating the amount of power required for shooting based on management information including a shooting order;
A comparison step of comparing the amount of power calculated in the calculation step with a charge amount of a battery that supplies power to the radiation imaging apparatus;
An output step for outputting the result of the comparison;
A control method for a radiation imaging apparatus, comprising: A radiography apparatus control method comprising: an imaging unit that detects radiation and obtains a radiographic image; and a battery that supplies power to the imaging unit,
An output step of outputting information on excess or deficiency of the remaining amount of the battery with respect to the imaging order based on the imaging order by the imaging unit and the charge amount of the battery;
A control method for a radiation imaging apparatus, comprising:

Images