JP6361163B2 - Radiography equipment - Google Patents

Description

  The present invention relates to a radiation imaging apparatus that images a subject with radiation, and more particularly to a radiation imaging apparatus having a configuration in which different types of radiation detection means can be selectively used.

  A medical institution is equipped with a radiation imaging apparatus that images a subject M by irradiating radiation (see, for example, Patent Document 1). Such a radiation imaging apparatus includes a radiation source 53 for irradiating radiation and a cassette 60 for detecting radiation, as shown in FIG. A top plate 52 on which the subject M is placed is provided between the radiation source 53 and the cassette 60. The top plate 52 has a drawer for storing the cassette 60.

  The cassette 60 contains a film that sensitizes radiation, and is configured to perform imaging when radiation enters the film. Therefore, the cassette 60 once irradiated with radiation cannot be used for imaging again. If the same cassette 60 is used for two shootings, the first and second shot images will appear on the cassette 60 in an overlapping manner. In order to prevent such a shooting failure, the conventional apparatus is configured to prohibit double shooting for the same cassette 60.

  In other words, the conventional apparatus is configured such that after the first photographing is completed, the second photographing is not executed unless the replacement of the cassette 60 is confirmed by the sensor. Whether or not the cassette 60 has been replaced can be known from the output of a sensor provided for drawing the top plate 52.

  By the way, in recent radiographic apparatuses, a radiation detector is often used instead of the cassette 60. This radiation detector has a method of detecting radiation by converting it into an electrical signal, and the principle of detecting radiation is different from that of a cassette. Such a radiation detector has a configuration capable of continuous imaging. Therefore, the same radiation detector can be used for imaging any number of times, and it is not necessary to replace it every time imaging is performed like a cassette. Therefore, it is not necessary to provide the double imaging prohibition function as described above in an apparatus including a radiation detector.

JP-A-5-200020

  However, the conventional apparatus has the following problems. That is, the conventional apparatus does not assume a case where a cassette and a radiation detector are used in combination as radiation detecting means.

  Nowadays, radiation images are often taken using a radiation detector. That said, it is not the case that the cassette is no longer used. The cassette is used as a backup when the radiation detector still fails, or is used when imaging must be performed with a wide field of view that cannot be handled by the radiation detector.

  Since today's radiation imaging apparatus is premised on the use of a radiation detector, it does not have the above-described double imaging prohibition function. Therefore, if shooting is performed using a cassette, it may occur that shooting continues without replacing the cassette by mistake. Such a shooting failure is detected after the film is developed, so it is not noticed immediately after shooting. Therefore, such a failure does not mean that you can easily retry. In addition, such a failure should be prevented from the viewpoint of preventing unnecessary radiation exposure to the subject.

  The present invention has been made in view of such circumstances, and the object thereof is to suppress imaging failures even when a cassette and a radiation detector are used in combination as radiation detecting means. The object is to provide a radiation imaging apparatus.

The present invention has the following configuration in order to solve the above-described problems.
That is, the radiation imaging apparatus according to the present invention is detachable from a radiation source that irradiates radiation, an input unit that inputs an instruction to start radiation irradiation, and a radiation detection unit that detects and converts the irradiated radiation into an image The holding means that can be held and opened and closed , and the radiation detection means held by the holding means are cassettes that need to be replaced each time radiation is irradiated, or detection devices that do not need to be replaced each time radiation is irradiated A type determination unit that determines whether or not there is used, a replacement detection sensor that detects whether or not the radiation detection unit held by the holding unit has been replaced by monitoring opening and closing of the holding unit , and a type determination unit that are used for imaging. If the radiation detecting means is determined to be a cassette, as long as the opening and closing of the holding means by the detection sensor does not detect, if there is an instruction to start morphism irradiation Radiation controls the radiation source to avoid irradiating, by type determination unit, if the radiation detecting device used for photographing is determined to be a detection device, opening and closing of the holding means by the detecting sensor if there is an instruction to start the irradiation It is characterized by comprising a radiation source control means for controlling the radiation source so as to irradiate the radiation even if no is detected.

  [Operation / Effect] According to the present invention, it is possible to provide a radiation imaging apparatus capable of suppressing imaging failure even when a cassette and a radiation detector are used in combination as radiation detection means. That is, the present invention is configured to perform imaging using either a cassette or a detection device as a radiation detection means. When imaging is performed with a cassette, an instruction to start irradiation is given unless a cassette replacement is detected. But do not irradiate radiation. With such a configuration, the same cassette is irradiated with radiation twice and imaging does not fail. Further, according to the present invention, radiation can be continuously applied to a detection device that does not need to be replaced. This is because, when the radiation detection means used for imaging is a detection device, radiation can be irradiated even if the replacement of the detection device is not detected.

  In the above-described radiation imaging apparatus, the type determination unit is more preferable if the type of the radiation detection unit is determined based on an operator's input indicating the type of the radiation detection unit.

  [Operation / Effect] The above-described configuration shows a specific configuration of the present invention. If the type of the radiation detection means is identified based on the operator's input indicating the type of the radiation detection means, the present invention can be realized more reliably.

  In the radiographic apparatus described above, the type determination unit includes a type detection sensor that detects the type of the radiation detection unit held in the holding unit, and determines the type of the radiation detection unit based on the output of the type detection sensor. This is more desirable.

[Operation / Effect] The above-described configuration shows a specific configuration of the present invention. If the type of the radiation detection means is identified based on the output of the type detection sensor, the present invention can be realized more reliably.
In addition, a display unit for displaying information is provided, and the radiation source control unit displays an indication that an erroneous operation has been performed on the display unit when there is an instruction to start irradiation in a state where the detection sensor does not detect opening and closing of the holding unit. It is good also as composition which makes it.

  The present invention is configured to perform imaging using either a cassette or a detection device as detection means. When imaging is performed with a cassette, radiation is instructed even if there is an instruction to start irradiation unless a cassette replacement is detected. Do not irradiate. With such a configuration, the same cassette is irradiated with radiation twice and imaging does not fail. Further, according to the present invention, radiation can be continuously applied to a detection device that does not need to be replaced.

1 is a functional block diagram illustrating an overall configuration of an X-ray imaging apparatus according to Embodiment 1. FIG. It is a perspective view explaining the top plate concerning Example 1. FIG. FIG. 6 is a schematic diagram for explaining standing shooting according to the first embodiment. 1 is a perspective view illustrating an FPD according to Embodiment 1. FIG. 3 is a cross-sectional view illustrating the FPD according to Embodiment 1. FIG. It is a partial fracture sectional view explaining the cassette concerning Example 1. FIG. FIG. 3 is a schematic diagram for explaining a photographing style according to the first embodiment. FIG. 3 is a schematic diagram for explaining a photographing style according to the first embodiment. 6 is a schematic diagram illustrating a configuration of a detection system operation panel according to Embodiment 1. FIG. 3 is a flowchart for explaining the operation of the X-ray imaging apparatus according to Embodiment 1; It is a mimetic diagram explaining one modification of the present invention. It is a mimetic diagram explaining one modification of the present invention. It is a schematic diagram explaining the radiography apparatus of a conventional structure.

<Overall configuration of X-ray imaging apparatus>
First, the configuration of the X-ray imaging apparatus 1 according to the first embodiment will be described. As shown in FIG. 1, the X-ray imaging apparatus 1 irradiates the subject M with the top plate 2 on which the subject M in the supine position is placed and the X-rays provided on the upper side (one surface side) of the top plate 2. An X-ray tube 3 and an FPD 4 that is placed on the top 2 and detects X-rays that have passed through the subject M disposed below the subject M and outputs a detection signal are provided. The FPD 4 is a rectangle having four sides along either the body axis direction A or the body side direction S of the subject M. One of the FPDs 4 is used at the time of imaging, and is arranged between the subject M and the top board 2 in the case of imaging related to the supine position. The detection surface for detecting X-rays of the FPD 4 faces the X-ray tube 3 and the subject M side. The X-ray tube 3 irradiates the quadrangular pyramid-shaped X-rays toward the FPD 4. Therefore, the FPD 4 receives X-rays on the entire detection surface. The support column 5 extends from the ceiling of the examination room toward the floor surface, and supports the X-ray tube 3. The X-ray imaging apparatus 1 having such a support 5 is called a radiation source suspended type. The X-ray tube 3 corresponds to the radiation source of the present invention, and the FPD 4 corresponds to the detection device of the present invention.

  The X-ray tube controller 6 (see FIG. 1) is provided for the purpose of controlling the X-ray tube 3 with a predetermined tube current, tube voltage, and pulse width. The X-ray tube control unit 6 corresponds to the radiation source control means of the present invention.

  The FPD 4 provided on the lower side of the top plate 2 of the X-ray imaging apparatus 1 of the present invention is configured to be removable from the top plate 2. FIG. 2 illustrates the top plate 2 of the X-ray imaging apparatus 1 of the present invention. The top plate 2 is provided with a drawer 2a as shown in FIG. The drawer 2a can be taken in and out in the body side direction S with respect to the top plate 2 main body. When the FPD 4 is set under the top plate 2, the FPD 4 is accommodated in the drawer 2a. The drawer 2a is configured to detachably hold the radiation detection means and corresponds to the holding means of the present invention.

  The top plate 2 is provided with a replacement detection sensor 2s1 for detecting replacement of a cassette 10 described later. The replacement detection sensor 2s1 monitors the opening and closing of the drawer 2a with respect to the top plate 2. When the operator pulls the drawer 2a out of the top plate 2 and returns it to the inside, the replacement detection sensor 2s1 is held by the drawer 2a. It is detected that the cassette 10 to be replaced has been replaced. Thus, the replacement detection sensor 2s1 is configured to detect whether or not the detection means held in the drawer 2a has been replaced. Since the replacement detection sensor 2s1 itself cannot be distinguished whether the FPD 4 or the cassette 10 is set in the drawer 2a, the operator pulls out the drawer 2a from the top plate 2 and sets the FPD 4 inside. The replacement detection sensor 2s1 detects that replacement has been performed. The detection result of the replacement detection sensor 2s1 is sent to the X-ray tube control unit 6 in addition to the main control unit 27.

  One of the features of the X-ray imaging apparatus 1 of the present invention is that imaging of a standing subject M as shown on the left side of FIG. 3 can be performed. That is, the X-ray imaging apparatus 1 of the present invention has a support shaft 7 that supports the FPD so as to be movable in the vertical direction, and stands the subject M in front of the FPD attached to the support shaft 7. Can be taken. The support shaft 7 extends in the vertical direction from the floor of the examination room toward the ceiling.

  An X-ray source used for standing-up imaging is an X-ray tube 3 used for imaging the supine position with the subject M placed on the top 2. That is, the support column 5 is configured so that the X-ray tube 3 can be freely moved. If the X-ray tube 3 can be moved to a position suitable for imaging using the top 2, the support shaft 7 can be moved. The X-ray tube 3 can also be moved to a position suitable for the used imaging.

  The FPD 4 can be set also on the support shaft 7 of the X-ray imaging apparatus 1 of the present invention. The right side of FIG. 3 illustrates the support shaft 7 of the X-ray imaging apparatus 1 of the present invention. As shown in FIG. 3, the support shaft 7 is provided with a cover 8 that covers the FPD 4b. The cover 8 includes a drawer 8a that can be taken in and out in the body side direction S of the subject M with respect to the cover 8 body. The drawer 8a is configured to detachably hold the radiation detection means and corresponds to the holding means of the present invention.

  The cover 8 is provided with a replacement detection sensor 8s1 that detects replacement of a cassette 10 described later. The replacement detection sensor 8s1 monitors the opening and closing of the drawer 8a with respect to the cover 8. When the operator performs an operation of taking out the drawer 8a from the cover 8 and returning it to the inside, the replacement detection sensor 8s1 is held by the drawer 8a. It is detected that the cassette 10 has been replaced. Thus, the replacement detection sensor 8s1 is configured to detect whether or not the detection means held in the drawer 8a has been replaced. Since the replacement detection sensor 8s1 itself cannot be distinguished whether the FPD 4 or the cassette 10 is set in the drawer 2a, even if the operator pulls out the drawer 2a from the top 2 and sets the FPD 4 inside. The replacement detection sensor 8s1 detects that replacement has been performed. The detection result of the replacement detection sensor 8s1 is sent to the X-ray tube control unit 6 in addition to the main control unit 27.

  As shown on the left side of FIG. 4, the FPD 4 has a connection terminal that is connected to the X-ray imaging apparatus 1. When the FPD 4 is set below the top plate 2, this connection terminal is connected to a connector provided inside the drawer 2a. By this connection work, the FPD 4 can obtain power from the apparatus main body and can transmit and receive signals to and from the apparatus main body. The present invention can also employ an FPD configured to exchange information with the X-ray imaging apparatus 1 wirelessly. Such an FPD does not include a connection terminal and operates by receiving power from an internal battery.

<Configuration of FPD4>
Since the configuration of the FPD 4 is important for understanding the features of the present invention, the FPD 4 will be described. The FPD 4 is a direct conversion type X-ray detector. As shown in FIG. 5, the FPD 4 includes a detection element including a capacitor that detects charges and accumulates charges and a transistor that controls extraction of the accumulated charges. An arrayed active matrix substrate 34, an amorphous selenium layer 31 that converts X-rays into charge pairs, a second high resistance film 32, a common electrode 33 for placing the amorphous selenium layer 31 in an electric field, and an epoxy resin layer 35 And an auxiliary plate 36 made of glass and a first high resistance film 37. The FPD 4 has a configuration in which an active matrix substrate 34, a first high resistance film 37, an amorphous selenium layer 31, a second high resistance film 32, a common electrode 33, an epoxy resin layer 35, and an auxiliary plate 36 are stacked in this order. ing.

A configuration related to charge accumulation of the FPD 4 will be described. The amorphous selenium layer 31 is made of high-purity amorphous selenium having a specific resistance of 10 ⁹ Ωcm or more (preferably 10 ¹¹ Ωcm or more). When the amorphous selenium layer 31 is irradiated with X-rays, a charge pair that is a pair of holes and electrons is generated. Since the amorphous selenium layer 31 is placed in a strong electric field, the charge moves along with it, and a charge is induced in the collecting electrode 34 a formed on the active matrix substrate 34.

  In the active matrix substrate 34, a collecting electrode 34a for collecting charges is formed on a glass substrate. The collection electrode 34 a is in contact with the first high resistance film 37 and is two-dimensionally arranged on the surface of the active matrix substrate 34. As shown in FIG. 5, the collection electrode 34a is connected to a charge storage capacitor 34c. The capacitor 34c accumulates the charge collected by the collecting electrode 34a.

  Subsequently, a configuration related to reading of electric charges of the FPD 4 will be described. A capacitor 34c that accumulates electric charge is connected to the transistor 34t. In addition to the input terminal connected to the capacitor 34c, the transistor 34t has a gate G for current control and a read electrode P for reading a detection signal. When the gate G of the transistor 34t is turned on, the electric charge accumulated in the capacitor 34c flows toward the readout electrode P. This current is an X-ray detection signal and represents the incident dose of X-rays.

  Accordingly, when the FPD 4 is irradiated with X-rays, the X-rays are first converted into electric signals. The FPD 4 completes the X-ray detection operation by outputting this electrical signal as a detection signal. After the FPD 4 outputs the detection signal, the amorphous selenium layer 31 is refreshed to the state before the X-ray incidence, so that the FPD 4 can detect X-rays again.

<Configuration of cassette 10>
The X-ray imaging apparatus of the present invention can use the cassette 10 in addition to the FPD 4 as means for detecting X-rays. The cassette 10 has the same shape as the FPD 4 and can be set on the top board 2 or the cover 8 instead of the FPD 4. The cassette 10 detects X-rays based on a principle different from that of the FPD 4. FIG. 6 is a view in which the cassette 10 is partially cut away so that the internal configuration of the cassette 10 can be understood. As shown in FIG. 6, the cassette 10 has a configuration in which an X-ray photosensitive film 10b is accommodated in a housing 10a. The X-ray photosensitive film 10b is coated with a photosensitive material that undergoes a chemical change when exposed to X-rays. When such an X-ray photosensitive film 10b is irradiated with X-rays, an X-ray image is baked onto the X-ray photosensitive film 10b. Such a cassette 10 can only be used for one-time shooting, and it is necessary to replace the cassette 10 when shooting is continued.

  Further, an imaging plate can be used instead of the X-ray photosensitive film 10b to constitute the cassette 10. The imaging plate is configured to print an X-ray image in the same manner as the X-ray photosensitive film 10b. Therefore, even if an imaging plate is used instead of the X-ray photosensitive film 10b, the situation that the cassette 10 must be replaced does not change.

  The detection means for detecting X-rays in the apparatus according to the present invention is configured by either the cassette 10 that needs to be replaced every time X-ray irradiation or the FPD 4 that does not need to be replaced every time X-ray irradiation.

<Different shooting styles for FPD and cassette>
There is no difference in detection means between the FPD 4 and the cassette 10. Nevertheless, the shooting mode differs depending on the detection means used for shooting. This difference will be specifically described. FIG. 7 illustrates an operation when the FPD 4 is used for photographing. In order to perform shooting using the FPD 4, the FPD 4 is first set on the top 2 or the cover 8. When X-ray irradiation is performed in this state, the FPD 4 outputs an X-ray image P. Thereafter, when X-ray irradiation is performed again, the FPD 4 outputs the X-ray image P again. In this way, the FPD 4 set on the top board 2 or the like operates so as to output detection signals constituting the X-ray image P every time X-ray irradiation is performed.

  The detection signal output from the FPD 4 is sent to the image generation unit 11. The image generation unit 11 generates an X-ray image P in which a fluoroscopic image of the subject M is reflected based on this detection signal.

  FIG. 8 shows an operation when the cassette 10 is used for photographing. In order to perform imaging using the cassette 10, the cassette 10 is first set on the top 2 or the cover 8. When X-ray irradiation is performed in this state, an X-ray image is baked onto the photosensitive material of the cassette 10. Thereafter, in order to perform X-ray irradiation again, the cassette 10 must first be replaced with a new one. Thus, the cassette 10 set on the top plate 2 or the like must be replaced every time X-ray irradiation is performed. The cassette 10 is exchanged manually.

  The detection system control panel 12 is a console that allows an operator to input information such as the type of FPD used for imaging. As shown in FIG. 9, the detection system control panel 12 can specifically select the type of FPD used for photographing, and can also specify that the detection means used for photographing is a cassette. When the operator selects the FPD, the detection system control panel 12 sends information indicating that to the FPD control unit 13. The FPD control unit 13 controls the FPD 4 based on the transmitted information. Specifically, the FPD control unit 13 controls the FPD 4 to accumulate charges or read charges. The detection system control panel 12 allows the operator to input the type of detection means.

  The type determination unit 14 is configured to determine whether the detection means held in the drawers 2a and 8a is the FPD 4 or the cassette 10 based on the input made by the operator to the detection system control panel 12. Yes. The type determination unit 14 sends the determination result to the X-ray tube control unit 6. As will be described later, the X-ray tube controller 6 changes its operation in accordance with this input.

<Other configuration of X-ray imaging apparatus>
Other configurations of the X-ray imaging apparatus will be described. The console 26 is provided for the purpose of inputting an operator's instruction such as an instruction to start X-ray irradiation. This console 26 is used to input an operator's instruction to the apparatus main body, and is independent of the detection system control panel 12. In the apparatus according to the present invention, the control system related to the FPD 4 is different from the control system related to the apparatus main body, and the console is also independent correspondingly. The reason why the control system of the FPD 4 is independent is that the FPD 4 is independent from the X-ray imaging apparatus 1 as an apparatus. With this configuration, the FPD 4 can be removed from the apparatus main body and replaced. However, when photographing, the control system of the apparatus main body and the control system of the FPD 4 are linked with each other. The console 26 corresponds to input means of the present invention.

  The main control unit 27 (see FIG. 1) is provided for the purpose of comprehensively controlling each control unit belonging to the apparatus main body other than the FPD 4. The main control unit 27 is constituted by a CPU, and realizes the X-ray tube control unit 6 and the image generation unit 11 by executing various programs. Further, each of the above-described units may be divided and executed by an arithmetic device that takes charge of them. The storage unit 28 stores all information related to device control. The display unit 29 is provided for the purpose of displaying captured images. The FPD control unit 13 is realized by a CPU different from the CPU that realizes the main control unit 27.

<Operation of X-ray imaging apparatus>
Next, the operation of the X-ray imaging apparatus according to the present invention will be described with reference to FIG. The apparatus according to the present invention can capture the subject M in the supine position or the subject M in the standing position. Here, the operation regarding the imaging in the supine position will be described. In order to capture an X-ray image using the X-ray imaging apparatus according to the present invention, the subject M is first placed on the top 2 (subject placement step S1).

  After placing the subject M, the operator pulls out the drawer 2a provided on the top 2 and places the detection means (FPD 4 or cassette 10) on the drawer 2a. Then, the surgeon pushes the drawer 2a into the top 2 and sets the detection means below the subject M (detection means setting step S2).

  When the setting of the detection means is completed, the surgeon operates the detection system control panel 12 to set the detection means used for imaging. At this time, the surgeon inputs to the detection system control panel 12 clearly indicating whether the detection means used for imaging is the cassette 10 or the FPD 4 (detection means type input step S3).

<Mode setting step S4>
In the configuration of the present invention, the shooting mode is changed depending on the type of detection means used for shooting. That is, when the surgeon sets the cassette 10 to be used for imaging through the detection system control panel 12, the imaging mode is set to the cassette mode. When the surgeon sets the FPD 4 to be used for imaging through the detection system control panel 12, the imaging mode is set to the FPD mode. The mode setting is executed by the main control unit 27 that has received the output of the detection system control panel 12. The type determination unit 14 sends a signal indicating the type of detection means corresponding to the set mode to the X-ray tube control unit 6. The signal transmitted from the type determination unit 14 to the X-ray tube control unit 6 can be regarded as a signal indicating the type of imaging mode.

  When the surgeon instructs to start imaging through the console 26, the X-ray tube 3 irradiates the subject M with X-rays. The irradiated X-rays pass through the subject M and enter the detection means provided in the top 2 (imaging step S5).

  When imaging is performed in the cassette mode, the X-ray tube control unit 6 that has received a signal indicating that the cassette 10 is set in the apparatus from the type determination unit 14 instructs the X-ray tube 3 to perform X-ray irradiation. After giving, it waits until the signal which shows that replacement of the cassette 10 which replacement detection sensor 2s1 outputs was transmitted. On the other hand, when imaging is performed in the FPD mode, the X-ray tube control unit 6 that has received a signal indicating that the FPD 4 is set in the apparatus from the type determination unit 14 instructs the X-ray tube 3 to perform X-ray irradiation. , And wait until a re-shooting instruction is given.

  In the apparatus of the present invention, the operator can give an instruction for re-shooting through the console 26 after the end of shooting. This re-imaging is performed, for example, when the subject M moves during the imaging and needs to be taken again, or when another part of the subject M needs to be imaged (re-imaging instruction step S6). ).

<The most characteristic configuration of the apparatus of the present invention>
Here, the most characteristic configuration of the apparatus of the present invention will be described. That is, in the X-ray imaging apparatus 1 of the present invention, the operation after the re-imaging instruction is given differs depending on the imaging mode. That is, when imaging is performed in the cassette mode, the X-ray tube control unit 6 is configured not to cause the X-ray tube 3 to perform X-ray irradiation unless the replacement of the cassette 10 is detected.

<Operation related to cassette mode>
An operation when the set shooting mode is the cassette mode will be described. The cassette mode X-ray tube 3 is in a state where X-ray irradiation is prohibited by the X-ray tube control unit 6. This restriction of X-ray irradiation is actually made after the end of imaging according to imaging step S5, and is not released until the replacement of the cassette 10 is detected. As described above, when the detection means used for imaging is the cassette 10, the X-ray tube control unit 6 according to the present invention irradiates X-rays even if there is an instruction to start irradiation unless a cassette replacement is detected. The X-ray tube 3 is controlled so as not to occur.

  Therefore, even if the surgeon instructs re-imaging before replacing the cassette 10, X-ray irradiation is prohibited, so the X-ray tube 3 does not emit X-rays. Instead, the X-ray tube control unit 6 sends a signal indicating that the operator has instructed re-imaging to the display unit 29 before replacing the cassette 10. In response to this, the display unit 29 displays that an incorrect operation has been performed.

  When the operator notices that the cassette 10 has not been replaced, and performs the replacement operation of the cassette 10, the replacement detection sensor 2s1 detects the replacement of the cassette 10, and sends a signal indicating that to the X-ray. It is sent to the pipe control unit 6 (cassette replacement detection step S7). Then, the X-ray tube control unit 6 cancels the restriction on the X-ray irradiation prohibition imposed on the X-ray tube 3.

  In this state, when the surgeon again instructs the re-imaging instruction through the console 26, X-rays are emitted from the X-ray tube 3, and re-imaging is executed (re-imaging execution step S8). Since this re-imaging is performed with the cassette 10 replaced, the imaging does not fail by irradiating the same cassette twice with X-rays. The cassette 10 is removed from the top plate 2 and the operation relating to the cassette mode is completed.

<Operations related to FPD mode>
Next, an operation when the set shooting mode is the FPD mode will be described. The X-ray tube 3 in the FPD mode is not prohibited from being irradiated with X-rays by the X-ray tube controller 6. Therefore, when the surgeon instructs re-imaging, X-rays are emitted from the X-ray tube 3 (re-imaging execution step S8). As described above, when the detection means used for imaging is the FPD 4, the X-ray tube control unit 6 according to the present invention irradiates X-rays even if the detection device replacement is not detected if there is an instruction to start irradiation. Thus, the X-ray tube 3 is controlled.

  Once the FPD 4 is set in the apparatus, photographing can be repeated without replacement. Therefore, the imaging does not fail when the same FPD 4 is irradiated twice with X-rays. The X-ray image P generated based on the detection signal of the FPD 4 is displayed on the display unit 29, and the operation related to the FPD mode is completed.

  Note that in the above description of the operation, an example of photographing related to the supine position is described. The apparatus of the present invention has the same configuration for shooting in a standing position. Of course, when photographing in the standing position, the cassette 10 or the FPD 4 is set in the drawer 8a of the cover 8 in the detection means setting step S2. In addition, when imaging is performed in the cassette mode, the X-ray tube control unit 6 gives an instruction for X-ray irradiation to the X-ray tube 3 and then the cassette 10 output from the replacement detection sensor 8s1 is replaced. It waits until the signal which shows this is transmitted.

  As described above, according to the present invention, it is possible to provide the X-ray imaging apparatus 1 that can suppress imaging failure even when the cassette 10 and the X-ray detector are used in combination as detection means. That is, according to the present invention, imaging is performed using either the cassette 10 or the FPD 4 as detection means. When imaging is performed with the cassette 10, an instruction to start irradiation is issued unless a cassette replacement is detected. However, X-rays are not irradiated. With such a configuration, the same cassette 10 is irradiated with X-rays twice and imaging does not fail. Further, according to the present invention, the FPD 4 that does not need to be exchanged can be continuously irradiated with X-rays. This is because when the detection means used for imaging is the FPD 4, X-rays can be irradiated even if the replacement of the detection device is not detected.

  The present invention is not limited to the above-described configuration, and can be modified as follows.

  (1) Although the above-described embodiment is configured to recognize the type of detection means based on an operator's input, the present invention is not limited to this configuration. A type detection sensor for recognizing the type of detection means may be provided. The left side of FIG. 12 shows a state in which the type detection sensor 2s2 is provided on the drawer 2a of the top plate 2. The type detection sensor 2s2 can distinguish whether the detection means set by the operator on the drawer 2a is the cassette 10 or the FPD4. Similarly, the right side of FIG. 12 shows a state in which the type detection sensor 8s2 is provided on the drawer 8a of the cover 8. The type detection sensor 8s2 can distinguish whether the detection means set by the operator on the drawer 8a is the cassette 10 or the FPD4. The main control unit 27 switches the mode based on the signal specifying the type of the detection means sent from the type detection sensors 2s2 and 8s2 in the mode setting step S4. As described above, the configuration according to this modification includes the type detection sensors 2s2 and 8s2 that detect the type of the detection unit set in the apparatus, and the type determination unit 14 detects based on the outputs of the type detection sensors 2s2 and 8s2. The type of means is determined, and the X-ray tube control unit 6 changes the operation based on this determination.

  How the type detection sensors 2s2 and 8s2 identify the type of detection means will be described. FIG. 13 shows a cassette 10 according to this modification. A magnet 10a is attached to a portion of the cassette 10 that faces the type detection sensors 2s2 and 8s2. Since the type detection sensors 2s2 and 8s2 are composed of magnet sensors, when the cassette 10 is set in the drawers 2a and 8a and the magnet 10a approaches, it can be detected. On the other hand, the FPD 4 is not provided with the magnet 10a. Therefore, the type detection sensors 2s2 and 8s2 can identify the type of detection means set in the drawers 2a and 8a. Note that the configuration according to this modification can be realized even if a magnet is attached to the FPD 4 and no magnet is attached to the cassette 10.

  (2) According to the above-described embodiment, the FPD is a direct conversion type that directly converts X-rays into electric charges, but the present invention is not limited to this configuration. An indirect conversion type FPD that converts X-rays into fluorescence and detects this can also be used to realize the present invention.

2a, 8a Drawer (holding means)
2s1, 8s1 Replacement detection sensor 2s2, 8s2 Type detection sensor 3 X-ray tube (radiation source)
4 FPD (detection device)
6 X-ray tube control unit (radiation source control means)
10 cassette 14 type determination unit (type determination means)
26 Console (input means)

Claims (4)

A radiation source that emits radiation;
Input means for inputting an instruction to start irradiation with the radiation;
Holding means capable of detachably holding the radiation detecting means for detecting the irradiated radiation and converting it to an image, and capable of opening and closing ;
Type determination means for determining whether the radiation detection means held by the holding means is a cassette that needs to be replaced every time radiation irradiation or a detection device that does not need to be replaced every time radiation irradiation, and
A replacement detection sensor for detecting whether or not the radiation detection means held by the holding means has been replaced by monitoring the opening and closing of the holding means ;
Wherein the type determination means, when the radiation detecting device used for photographing is determined to be a cassette, as long as the undetected opening and closing of the holding means by the detection sensor, the radiation even if an instruction to start morphism irradiation Controlling the radiation source so as not to irradiate,
If it is determined by the type determination means that the radiation detection means used for imaging is the detection device, if there is an instruction to start irradiation, radiation is detected even if the opening / closing of the holding means by the detection sensor is not detected. A radiation imaging apparatus comprising radiation source control means for controlling the radiation source so as to irradiate. The radiographic apparatus according to claim 1,
The radiographic apparatus according to claim 1, wherein the type determining unit determines the type of the radiation detecting unit based on an operator's input indicating the type of the radiation detecting unit. The radiographic apparatus according to claim 1 or 2,
The type determination unit includes a type detection sensor for detecting the type of the radiation detection unit held in the holding unit, and determines the type of the radiation detection unit based on an output of the type detection sensor. Radiography equipment. The radiographic apparatus according to any one of claims 1 to 3,
  A display unit for displaying information;
The radiation source control unit causes the display unit to display that an erroneous operation has been performed when an instruction to start irradiation is received when the detection sensor does not detect opening / closing of the holding unit. Radiography equipment.

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