SE512202C2 - Digital bucky where ion chambers and breaks can be removed from the detector - Google Patents

Abstract

An X-ray radiographic system (1) includes a digital bucky that has a fixed or a movable raster. The bucky is comprised of a rectangular box (2) which houses an image receptor (3) in the form or a digital detector that is connected electrically, magnetically or optically to an image presentation unit in the form of a computer (5) and associated screen (5a). The upper part of the box (2) includes an ion-chamber in addition to the raster. The detector (3) can be withdrawn from the box to enable free exposures of smaller objects (10) to be taken. In this respect, the radiation source is arranged so that it can be focused on the detector (3) in its withdrawn position. The box and the detector are also provided with a latching device (2b, 3c) which releaseably blocks the box in the withdrawn position of the detector, and damping means are also provided for taking-up any impact forces to which the detector may be subjected.

Description

ia 512 202 2 single fixed formats and, unlike the image plates, are usually permanently wired with the equipment for image production.

The image plates, like the film cassettes, must be moved to the X-ray equipment for exposure and then to the imaging unit used, which is both ergonomic and time-consuming.

With permanently mounted detectors in a digital bucky, this inconvenience is avoided. However, the large format, based on the largest format of the image plate / cassette and the raster, means that the so-called free exposures cannot be implemented.

Free exposures have hitherto been performed with loose film cassettes or image plates and without breaks on smaller objects such as hand, foot, elbow, knee, etc., which do not generate the image-deteriorating scattering radiation. Because the object can be placed directly on the image field, optimal image quality is achieved with a low radiation dose.

FIELD OF THE INVENTION The invention relates to a digital bucky with a fixed or movable grid and more particularly of the type specified in the preamble of claim 1.

A digital bucky of this kind can be partially adapted to free exposures by removing the raster, ie taking it out of the field of view. However, the disadvantage of the large object-film distance remains. Furthermore, there is a great risk of damage when handling the fragile screen, which - when it is reintroduced on site - can cause deteriorating image quality.

Object of the invention Based on the above-mentioned problem, an object of the invention is to avoid free exposures of small objects, even with a bucky equipped with a digital detector of this type, while avoiding a large object-film distance and risk of damage to the screen. 512 202 3 Another object is to enable free exposure with the detector in a defined or arbitrary position in relation to the bucky and connected to an image production unit via cable or wirelessly and without the detector having to be removed for transmission of stored image information after exposure. Detailed description of the invention These and other objects are achieved with a digital bucky of the type indicated by being given the features specified in the characterizing part of claim 1.

By providing the bucky box with exposing means of the specified type, it becomes possible to place the object directly on the detector so that the desired free exposure is allowed. in one embodiment, the indicated means can be realized in that the box has a movable, e.g. folding or swiveling, lids containing ion chambers and breaks.

In this embodiment, no adjustment with re-centering of the radiation source needs to be undertaken. Instead, a light cross shines against the detector's exposed image field, which light cross indicates where the focus hits the object. The same applies if, according to another embodiment, the bucky box is movable, e.g. displaceable relative to the detector.

An alternative, in practice preferred embodiment, is characterized in that the detector is displaceable or pullable out of the box and that the radiation source is arranged to allow focusing towards the detector in its extended position.

In this embodiment, the ion chamber and the fragile grid thus remain in place inside the bucky box and thus do not have to be exposed to any risks which may deteriorate the future image quality.

In different types of devices, the detector can be extended to one or more predefined positions or also to an arbitrary position depending on the size of the object to be exposed.

In the first case, the radiation source can be displaced by mechanical or manual means to a position corresponding to the assumed position of the detector.

When the detector is pulled out to any position, the position of the radiation source can be set manually by means of the above-mentioned light cross or an automatic control system can be used, which sets the radiation source depending on the detector's occupied position.

To avoid the risk of damage to the detector, it is preferred that the box has a locking device for the detector arranged to prevent the detector from being completely pulled out of the box, which locking device is also arranged to releasably block the detector in an inwardly extended position. The locking device is furthermore suitably arranged to come into operation automatically when the drawer is tilted. Such a skew can e.g. occur if the bucky from a position under a patient table, ie a position for vertical radiation, is swung up e.g. to a vertical position next to the patient table, ie to receive horizontal radiation. In one embodiment, the locking device cooperates with a sensor which on a control panel for the system indicates that the locking device has been activated.

The locking device can be designed in different ways depending on the present circumstances. In a preferred embodiment, the locking device is in the form of a rack arranged next to the extendable detector, which co-operates with an engaging member present on the box which engages between two teeth on the rack.

In practical use of a bucky according to the invention it is to be expected that the extendable detector will be subjected to certain not insignificant stresses, e.g. when loading a foot to be imaged. -512 202 5 Other types of more or less unpredictable loads may also occur in practice, e.g. that the detector in the extended position is hit or subjected to another type of load.

An embodiment of the invention is therefore characterized in that there are control means between the box and the detector, e.g. side rails, set up to occupy reasonable against the detector in the extended position exerted stress.

For corresponding purposes, it is also preferred that the detector is resiliently attached to the buckle box, so that support stresses in the directions of movement present are absorbed.

For this purpose, the detector can have a damping device active in its direction of movement which dampens shocks against the detector and allows it to be suspended under load in its direction of movement inwards and outwards.

In a more developed arrangement, wherein the detector has sensors cooperating with the radiation source which allow accurate centering of the radiation source relative to the detector in one or more extraction positions, said damping device can be arranged to deactivate said sensor at the same time when performing its damping function.

In the event that the detector should be exposed to unpredictable stresses, it can at least be ensured that the control and setting device of the radiation source is not exposed to the risk of being damaged.

The digital detector is suitably connected via cable in electrical, magnetic or optical connection to the image production unit, which preferably consists of a computer with a monitor.

However, the detector can also be connected wirelessly to the image production unit, which in some cases can offer greater flexibility. Correspondingly, the control of the movements of the radiation source in dependence on the current extraction position for Ei ..__ l .. ~ à \ ii H,. 512 202 6 detector can also be done wirelessly, although even here a cable connection will normally be preferred.

The radiation source may possibly be pillar-supported, although it is generally preferred that it is roof-supported, as this provides greater flexibility and the opportunity to cover a larger area.

Inside the box there is suitably a grid cover in the form of a sheet of acrylic, plexiglass or carbon fiber.

The image field of the detector is a fragile component in the detector and in order to protect it from mechanical impact and other damage, a thin plate of carbon fiber is suitably placed on it. Carbon fiber is mechanically resistant and has low absorption of X-rays.

Some embodiments of the invention will be described below in connection with the accompanying schematic drawings.

Brief description of the drawing figures Fig. 1 is a perspective view showing the principal components of a plant equipped with a digital bucky according to the invention for X-ray photography.

Fig. 2 is a perspective view of the digital bucky of the plant according to Fig. 1 with the digital detector in the inserted position in its box.

Fig. 3 is a view corresponding to Fig. 2 with the detector in an extended position.

Fig. 4 illustrates the so-called free exposure of hand with the digital bucky in extended horizontal position.

Fig. 5 is an example of free exposure, namely of foot, with the detector in the extended, inclined position.

Figs. 6 and 7, finally, show a column stand with a pivotable arm supporting the bucky, the box of which is displaceable for exposing the detector. 512 202 7 Description of Preferred Embodiments Referring primarily to Fig. 1, a digital bucky X-ray photographic apparatus having a fixed or movable screen consists of a rectangular box arranged under a patient table 9 whose dimensions are determined by the field of view in question. size. This must be at least 24x35 or 43 cm. Included in the box is an image receptor in the form of a digital detector, which via cable 4 is in electrical connection with an image production unit in the form of a computer 5 with a screen 5a.

Furthermore, there is a movable radiation source 8 which emits X-rays towards the image field of the detector.

The rectangular bucky box 2 is shown in more detail in Figs. 2 and 3. The box 2 has a lid or an upper part 2a which occupies an ion chamber and a fixed or movable grid (not shown).

The digital detector 3, which is provided with an upper protective layer 3a of carbon fiber, is extendable relative to the box 2 and for this purpose is provided with a handle 3b.

The detector and the box are provided with a cooperating locking device in the form of a rack 3c which is arranged along one short side of the detector. The box in turn has an engaging member in the form of a pin 2b which engages between two teeth of the rack 3c to releasably lock the detector 3 in an engaged position. The locking device is further arranged to automatically come into operation in the event that the box is pivoted to an inclined position, ie so that the detector under the influence of gravity would tend to fall out of the box.

The blocking device cooperates with a sensor (not shown) which on a control panel for the system (not shown) indicates when the blocking means is activated.

Extending along the side edges of the detector are guide strips 3d which are included in correspondingly shaped grooves in the box. These 3d guide strips and the corresponding grooves in the box are designed to take up reasonable stresses exerted on the detector in the extended position.

The detector 3 is also elastically resiliently attached to the box so that shock stresses in the current direction of movement in resp. out can be recorded. Fig. 2 shows a small pneumatic cylinder 12 which is included in this motion damping arrangement.

When the detector is pulled out, a corresponding setting of the radiation source 8 must take place. This setting can be done manually, whereby the operator can use the light cross that the radiation source emits towards the detector and which indicates where the focus of the radiation source is. Alternatively or in addition, the radiation source may be arranged to be able to assume a limited number of predetermined positions, each of which corresponds to a predetermined extraction position for the detector 3.

In a more sophisticated arrangement, an automated control system is used which ensures exact setting of the radiation source depending on the current position occupied by the detector and where the radiation source is also arranged for horizontal resp. inclined beam path when the detector occupies vertically resp. inclined position. Fig. 5 shows such an inclined position of the detector 3 at so-called free exposure of a smaller object such as a foot.

Fig. 4 illustrates free exposure of the hand with the detector extended in the horizontal position, the radiation source 8 being arranged in the usual manner for vertical beam path.

The detector 3 can have sensors cooperating with the radiation source (not shown) which allow accurate centering of the radiation source relative to the detector in one or more extraction positions. The damping device 12 is then arranged to deactivate said sensor at the same time when exercising its damping function.

Figs. 6 and 7 show an alternative embodiment of the bucky box 2, where this is supported on an arm 12b pivotable about a horizontal axis 12a to a pillar frame 12. The bucky box 2 itself, together with ion chambers and gratings, are hereby displaceable from that in Fig. 6. to the position shown in Fig. 7 so that the digital detector 3 is exposed for exposure by means of the radiation source 8, which in this case does not have to change position in connection with the displacement movement of the box.

Claims (11)

iimi i ._. niin m. -... (¿_fi m.. M ä flfi 512 202 10 Patent claim Digital bucky with fixed or movable raster, comprising a) a preferably rectangular box (2) of predetermined dimensions, b) an image receptor accommodated in the box in the form of a digital detector (3), which wirelessly or via cable (4) is in electrical, magnetic or optical connection with an image production unit, e.g. a computer (5) with a monitor (Sa), c) an ion chamber and a fixed or moving grid in the box between the detector and an external object (10), d) a moving radiation source (8) which emits X-rays to the detector's field of view, k ä characterized in that the box (2) has means for exposing the detector (3) from ion chambers and grids, so that free exposure of smaller objects (10), e.g. foot, knee or the like, directly on the detector is allowed. Digital bucky according to claim 1, characterized in that the box (2) has a movable, e.g. fold-up or swivel-out, lid (2a) containing ion chambers and breaks. Digital bucky according to claim 1, characterized in that the box (2) and / or the detector (3) are movable, preferably displaceable relative to each other. Digital bucky according to claim 3, characterized in that the detector (3) is displaceable or pullable out of the box (2) and that the radiation source (8) is arranged to allow focusing towards the detector (3) in its extended position. Digital bucky according to claim 4, characterized in that the box (2) has a locking device (2b, 3c) for the detector (2) arranged to prevent the detector from being completely pulled out of the box and releasably blocking the detector in an inlet. taken extended position. Digital bucky according to claim 5, characterized in that the locking device (2b, 3c) is arranged to come into operation automatically when the box is tilted. Digital bucky according to claim 5 or 6, characterized in that the blocking device (2b, 3c) cooperates with a sensor which on a control panel for the system indicates that the blocking device has been activated. Digital bucky according to any one of claims 1-7, characterized by control means arranged between the box (2) and the detector (3), e.g. guide strips (3d) set up to record reasonable against the detector in the extended position exerted stresses. Digital bucky according to any one of claims 1-8, characterized in that the detector (3) is elastically resiliently attached to the box (2), so that shock stresses against the detector are absorbed. Digital bucky according to claim 9, characterized in that the fastening device of the box comprises damping means (12) arranged to dampen shocks against the detector and allow suspension thereof in the event of overload in its direction of movement inwards resp. outwards. Digital bucky according to claim 10, wherein the detector has a sensor cooperating with the radiation source (8) which allows accurate centering of the radiation source relative to the detector in one or more extraction positions, characterized in that the attenuation device (12) is arranged to attenuation function at the same time deactivating said sensor.