EP1776046A1

EP1776046A1 - X-ray device provided with an entrained scattered ray protection device

Info

Publication number: EP1776046A1
Application number: EP05779213A
Authority: EP
Inventors: Kerstin Barkow; Franz Beimler
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2004-08-13
Filing date: 2005-08-04
Publication date: 2007-04-25
Also published as: WO2006018395A1; DE102004039411A1; US20080031422A1; US7744278B2

Abstract

The invention relates to an X-ray device (1) provided with an effective scattered ray protection device (20) that is easy to handle. Said X-ray device (1) comprises an X-ray emitter (2), an image receiver (3) arranged in a radiation direction (9) at a distance from the X-ray emitter, and a patient's bed (4) arranged between the X-ray emitter (2) and the image receiver (3). The relative position of the X-ray emitter (2) and the image receiver (3) in relation to the patient's bed (4) can be adjusted in at least one spatial direction (16,17). The scattered ray protection device (20) can be fixed, as a reference object, in a fixed relative position in relation to the image receiver (3) and/or the x-ray emitter (2), by means of a coupling unit (21), in such a way that when the reference object (3) is adjusted in relation to the patient's bed (4), the scattered ray protection device (20) is entrained with the reference object (3).

Description

description

X-ray device with entrained anti-scatter device

The invention relates to a particular medical X-ray device with an X-ray source, with a distance from them in a direction of radiation arranged image receiver, and having disposed between the X-ray source and the image receptor patient support, wherein the relative position of the X-ray source and the Bildempfän ^¬ gers with respect to the patient support in at least one, perpendicular to the direction of radiation or oblique, spatial direction is adjustable.

Such an X-ray device is known, for example, from WO 02/00116 A1.

In certain medical X-ray examinations, more particularly sondere at screening methods using con- trastmitteln and interventions at X-ray-based interventions and In¬, the treating physician must during treatment ^¬ radiation reside in close proximity to the irradiated patients, and is thus a relatively strong Stray radiation is exposed from the patient's body.

In order to minimize the radiation exposure for the be¬ acting doctor under these conditions, the wearing of radiation protection clothing, especially lead apron, thyroid protection, etc. is prescribed for such treatment. In addition, the use of mobile radiation shields is recommended

Lead acrylic glass known. Such a shield is usually attached to ei ^¬ nem one or more articulated arm on the ceiling or a wall of the examination room and can be placed freely in space to a limited Um ^¬ fang. Such protective radiation is in size and weight but generally relatively bulky and thus hindered the investi ^¬ monitoring activities of the treating physician. Another obstacle alteration caused such a radiation shield in particular ^¬ sondere in that it bezüg at a position change in the X-ray beam, the image receptor or the patient needs to be frequently moved ^¬ Lich of the treating physician manually to protect the doctor against the change scattered radiation field wei ^¬ terhin. In addition, a conventional Strahlen¬ shield is often an adjustment of the X-ray device in the way.

The invention has for its object to design a Röntgenvor ^¬ direction such that an effective Streu¬ radiation protection for the attending physician is achieved in a particularly easy-to-handle manner, in particular obstruction of the examination of the doctor by the antiscattering should be avoided as far as possible.

This object is achieved by the features of claim 1. Thereafter, the X-ray device comprises an X-ray source, an image receiver arranged at a distance therefrom in a radiation direction, and a patient support arranged between the X-ray emitter and the image receiver. In the image receiver is insbeson particular to a functional unit for positioning and Zentrie ^¬ tion of a film cassette. Alternatively, a carrier unit for an X-ray image intensifier or a digital X-ray detector can also be used as the image receiver. The patient storage is, in particular, a patient bed.

The X-ray emitter and the image receiver are mutually and / or individually adjustable relative to the patient support in at least one spatial direction perpendicular or oblique to the radiation direction, preferably both in the longitudinal direction and in the transverse direction, relative to the patient support. Alternatively or additionally, the patient support can be arranged to be adjustable, so that in turn the respective Relative position of the X-ray source and the image receptor relative to the patient support is changeable.

According to the invention an anti-scatter protection is now provided which is relative to the image receiver and / or the coupler Röntgenstrah¬ sition as a respective reference object in a fixed, at least in an adjustment of the reference object Relativpo ^¬ fixable. The fixation is designed such that upon adjustment of the reference object (ie, depending on the embodiment of the image receiver and / or the Röntgenstrah¬ lers) with respect to the patient positioning and the Streustrahlen¬ protection is adjusted accordingly to the patient positioning.

The invention is based on the finding that the intensity of the scattered radiation at a spatial point in the vicinity of an X-ray device essentially depends on the relative position of the observed point in space to the point at which the central ray of the X-ray penetrates a treated patient, this location again depends on the OERTLI ^¬ chen arrangement of the X-ray source and image receptor. Thus, it is known that the scattered radiation field "migrates" in an adjustment of the image receiver and / or Röntgen¬ radiator with respect to the patient's positioning in the rule. By the scattered radiation protection according to the invention coupled pfänger to the Bildem¬ and / or the X-ray as a reference object ge, therefore a investi ^¬ monitoring, in particular also during the adjustment of the Refe ^¬ shall at all times ence object consistent protective effect for the loading acting doctor achieved.

The anti-scatter protection is positioned in this case in particular such ge ^¬ genüber the reference object, that it is arranged in the main field of the expected stray radiation. A suitable relative position of the antiscatter protection is by

Determination of the central ray of the of the X-ray source in Direction of the image receiver emitted primary beam field to definable.

Conference will object by the entrainment of the scattered radiation protection with the same refer- significant Handhabungsver ^¬ simplification for the treating physician achieved. In particular, eliminates the need for manual adjustment of the radiation ^¬ radiation protection during the investigation. By the scattering ^¬ is radiation protection carried with the reference object, also a possible collision of the scattered radiation protection with other components of the x-ray device is at a Ver¬ the latter position eliminated easily.

Preferably, the antiscattering is designed as a self-supporting, in particular substantially rigid screen.

This makes it possible to use the same antiscattering in different orientations of the X-ray devices, in particular with horizontally and vertically aligned Patien ^¬ tenlagerung. In contrast, for example, a trained from lead slats anti-scatter shielding, as it is commonly used, collapse in a shift ^¬ tion of the table position in itself.

In a preferred embodiment of the invention, the scattered radiation protection has a substantially flat body field for protecting the upper body of the attending physician. The plane of this body field is in this case aligned approximately parallel to a front edge of the patient support, so that the body field is approximately perpendicular to a lying surface of the patient support or slightly inclined over this. Appropriately, a visual field is placed on an upper edge of this body field, which is angled from the body field in the direction of the patient support. The field is be ^¬ vorzugt integrally carried out in particular in one piece with the body panel. The field of view allows the attending physician to bend over the patient's support over the body field during the examination without being affected Head area to be exposed to increased radiation exposure. Thus, the field of view allows the doctor to take a similarity ^¬ Liche investigation attitude as he would also take in the absence of the scattered radiation protection usually, and thus promotes the handling of the X-ray device. As the upper edge of the body panel (un ^¬ depending on the actual orientation of the body panel in the surrounding space) is referred to the edge of the body panel facing away from the lying surface of the patient support.

Of the adjoining this upper edge side edges of the body panel at least one side edge is provided with a concave recess or recess. The thus shaped body field thus has a laterally waisted shape. The recess formed by the or each waist Kör ^¬ perfeldes facilitates the gripping of radiation protection currency ^¬ rend a medical treatment combined with good radiation protection for the lower body and the head and shoulder region of the attending physician.

A further improvement in this regard is achieved by arranging a movable sliding panel on at least one edge of the body field, in particular on one or both side edges. The or each sliding panel is positioned such that it increases in a normal position, the shielded by the body panel surface to optimize the beam ^¬ protection, but on the other hand, this Normalpo ^¬ sition is displaceable in an at least partially retracted in the surface area of the body panel release position to again an embrace of the body field to facilitate. Such a sliding panel is arranged in particular such be ^¬ that in the normal position one in a Seiten¬ of the body panel provided indentation edge part at least partially covers ^¬.

With regard to a further handling simplification for the attending physician with at the same time particularly good protection function is provided that the or each sliding field ge ^¬ gen a restoring force elastically aus¬ from the normal position aus¬ is steerable, and thus returns in particular when released itself ^¬ active from the deflected state back to the normal position. Such automatic reset of the or each sliding panel is re ^¬ alisiert in a particularly simple manner by the or each sliding eccentric, ie at a distance from its center of gravity, is pivotally mounted, so that acting on the sliding panel gravity acts as a restoring force and the sliding panel at Pushes back deflection to normal position.

Alternatively or additionally, the or each Schiebe¬ field is preferably associated with a spring element which generates the restoring force or optionally reinforced. Through the optionally provided spring element in particular ge ^¬ is ensured that the or each sliding panel is adjusted also during rotation of the radiation protection, particularly if the patien ^¬ tenlagerung from a horizontal to a vertical position, is always returned to the normal position. Again, additionally or alternatively, is the or each slide box fixing, in particular in the form ei ^¬ ner fixing screw, a magnet attachment, or a snap lock, associated with means of which the or JE the shift field at least in the normal position, optionally also other totally or partially retracted positions , is fixable.

In order to further simplify the handling of the X-ray device during a radiation break, it is advantageously provided that the antiscattering device can be removed from the relative position with respect to the relative object (ie the image receiver and / or X-ray emitter). This facilitates, in particular, the carrying out of medical treatment steps and other actions to be carried out before or after the actual irradiation phase, in particular, the bearings of a patient on the Patientenla ^¬ delay, but also the cleaning of the X-ray apparatus, etc.

In order to realize the removal of the antiscattering device from the relative position, it is optionally provided that the coupling unit permits a pivoting of the antiscattering device out of or into the relative position. Preferably the coupling unit is designed such, however, that the scattering radiation protection ^¬ can be completely removed from the reference object. A detachable connection of the anti-scatter protection ^¬ zes is structurally particularly simple realized by a connector designed as a plug connection unit.

A further improvement in the handling of the X-ray apparatus is preferably achieved by arranging operating and control elements for the X-ray apparatus on the front side of the antiscattering device facing the behan¬ delnden doctor ange¬.

To get a good view of the attending physician to the patient to behan ^¬ delnden to ensure the protection Streustrahlen¬ is at least substantially made of a transparent röntgenstrahlungsabsorbierenden material. As hier¬ for particularly suitable material in particular lead acrylic glass is used for the production of anti-scatter protection.

Embodiments will be explained in more detail with reference to a drawing ^¬ tion. Show:

1 shows in a perspective view on the front ^¬ side an X-ray device with held on a common tripod, an X-ray emitter, an image receiver, a horizontally aligned patient positioning and with an entrained with the BiId- receiver antiseize, 2 shows a perspective view of the X-ray device in a stand position rotated by 90 °, corresponding to a vertical arrangement of the patient support,

3 shows a schematic front view of the stray beam contactor of the x-ray device according to FIG. 1, FIG.

4 in accordance with a section line IV-IV (FIG 3) partially cross-sectional side view of the Streustrahlen¬ protection according to FIG 3,

5 shows an illustration according to FIG. 3 of an alternative embodiment of the anti-scattering device,

6 shows a front view of the X-ray device according to FIG. 1 with an image receiver displaced on the foot side with respect to the patient support and correspondingly guided anti-scattering device, FIG. 7 shows the X-ray device with an image receiver displaced on the head side relative to the patient support and corresponding anti-directional anti-scatter device, FIG.

FIG. 8 in a representation according to FIG. 6 the X-ray device according to FIG. 1 with a dashed line

Measuring surface for a test measurement of the scattering radiation characteristic of the X-ray device with and without antiscattering and

9 shows a diagram of the device according to FIG. 8 with and without antiscatter protection

Scattered radiation dose at different points of the measuring surface according to FIG. 8

Corresponding parts and sizes are always provided with the same reference numerals in all figures.

The X-ray apparatus 1 shown in FIG 1 in a perspective front view includes an X-ray source 2, an image receiver 3 and a patient support 4. The image receiver 3 is embodied here as a functional unit, in which a (not shown), an X-ray film contained ^¬ tend film cassette positioned is. To introduce the Film cassette is the image receiver 3 on a front side 5 provided with a corresponding insertion slot 6 for the Filmkas¬ sette. The patient support 4 is designed as a patient ^couch , whose lying surface 7 in the illustration according to FIG. 1 is oriented horizontally.

The X-ray source 2, the image receiver 3 and the patient support 4 are supported on a common stand 8 in such a way that the image receiver 3 faces the X-ray source 2 at a distance, as seen in a radiation direction 9, and that the lying surface 7 of FIG Patient positioning 4 between the image receiver 3 on the one hand and the X-ray source 2 on the other hand is arranged. In the arrangement according to FIG. 1, the lying surface 7 is aligned essentially perpendicular to the radiation direction 9.

The X-ray source 2 is fastened, together with a depth diaphragm 10 connected upstream in the direction of radiation 9, to a galgenar-like radiator support 11 of the stand 8.

The stand 8 further comprises a plate by means of a Boden¬ 12 fixedly mounted stand base 13 and a Drehge ^¬ vice 14 which is pivotally mounted on the stand base 13 about a horizontal and transverse with respect to the support surface 7 of the patient support 4 extending axis of rotation 15 °. The bogie 14 carries the patient support 4, the Liegeflä ^¬ che 7 can be adjusted by pivoting the bogie 14 in particular from the horizontal position shown in FIG 1 in a vertical position as shown in FIG 2. The bogie 14 also carries the image receiver 3 and the radiator support 11 with the X-ray emitter 2, which consequently rotate in the described pivoting of the bogie 14 with the patient support 4, so that even the radiation direction perpendicular to the surrounding space according to FIG 9 pivoted in a horizontal orientation (FIG 2) is. The patient support 4 is held adjustably both in a longitudinal direction 16 and in a transverse direction 17 on the bogie 14 of the stand 8. The longitudinal direction 16 and the transverse direction 17 are defined here with respect to the lying surface 7. In addition, the image receiver 3 and the radiation carrier 11 with the X-ray emitter 2 are held independently adjustable in the longitudinal direction 16 on the bogie 14. If the image receiver 3 and the X-ray emitter 2 are longitudinally displaced relative to the patient support 4, then a central ray Z of the X-ray radiation R generated by the X-ray emitter 2 is merely displaced relative to the lying surface 7 (FIG. 6). In the case of different longitudinal positioning of the image receiver 3 and of the X-ray emitter 2 with respect to the patient support 4, on the other hand, the radiation direction 9, and thus the central ray Z, will tilt out of the vertical orientation with respect to the lying surface 7 (FIG. 7). By a coupling element 18 mechanically connecting the image receiver 3 to the X-ray emitter 2, the X-ray emitter 2 is pivoted in such a way that the central ray Z is always directed onto the image receiver 3.

The X-ray device 1 furthermore comprises a scattered radiation protection 20, which is designed as a substantially flat protective screen and at least essentially consists of transparent, but X-ray-absorbing lead acrylic glass. The anti-scatter device 20 is connected by means of a Koppel¬ unit 21 fixed to the image receiver 3 and is consequently forcibly entrained in an adjustment of the image receptor 3 relative to the patient support 4 and / or with respect to the X-ray source. The image receiver 3 thus serves as a reference object, to which the Streustrah ^¬ lenschutz 20 in the longitudinal direction 16 assumes a predetermined Relativpo ^¬ position.

In this relative position of the scattered radiation shield 20 is approximately aligned the image receiver aligned with the front side 5 3 out ^¬, it that a front edge 22 of the support surface 7 with Flanked by a small distance. The anti-scatter shield 20 is aligned approximately perpendicular to the rotation axis 15 and thus also approximately perpendicular to the lying surface 7 and extends - starting from the image receiver 3 - in the direction of the X-ray source 2, so that it formed between the image receptor 3 and the X-ray source 2 space area shields to the front of the X-ray device 1 out.

3 and 4 in a schematic front view or in a cross section IV-IV (FIG. 3), the scattered radiation ^shield 20 again shown comprises a flat central body ^¬ field 30, which has a waisted shape. The edge of the body panel 30, which faces the image receiver 3 in the installed position, is referred to here as the lower edge 31. Correspondingly, the remote in the installed position of the image receptor 3 edge of the body panel 30 as an upper edge 32 indicated ^¬ net. The edges connecting the lower edge 31 to the upper edge 32 on both sides of the body panel 30 are referred to as side edges 33. Each side edge 33 is in this case provided with a concave indentation 34, through which the waisted shape of the body panel 30 comes about.

On the upper edge 32 of the body panel 30, a union in Wesent ^¬ trapezoidal flat face panel 40 connects, which likewise made of transparent, röntgenstrahlungsabsorbierendem Ma¬ TERIAL, in particular consists of lead acrylic and so ge ^¬ is angled genüber the body panel 30 that it is in Rich ^¬ tion on the patient support 4 protrudes. The visual field 40 allows a treating physician to bow to a certain extent over the body field 30 in the direction of the patient support 4 during the treatment, without being exposed to increased stray radiation load, in particular in the head area. The attending physician has thus insbeson ^¬ particular a relatively good attention to the lying surface 7 and a patient supported on it. On each side edge 33 of the body panel 30, a sliding panel 41 is further movably mounted. Each sliding panel 41 is in turn made of radiation-absorbing, preferably also transparent material, in particular again made of lead acrylic glass, and has an approximately banana-like shape. Each sliding field 41 is hereby arranged in a normal position P with respect to the body field 30 in such a way that it substantially covers the surface saved by the indentation 34 of the associated side edge 33 and thereby enlarges the surface shielded from the body field 30 towards the side edges 33.

In the embodiment of the scattered radiation guard 20 shown in FIG. 3, each sliding field 41 is mounted rotatably about the body 42 on an axis 42, the axis 42 being arranged above the indentation 43, ie in a region of the body field 30 adjoining the upper edge 32 , About this axis 42 can each sliding panel 41 in a Freigabepo ^¬ sition P ^Λ be pivoted, in which the deflected sliding panel 41 is largely retracted into the abge of the body panel 30 ^¬ shielded area, so that the recessed from the corresponding recess 34 face substantially is released.

By means of the indentations 34 it is achieved that the treating doctor can grasp around the anti-scatter guard 20 in a comparatively simple and unobstructed manner in the course of the treatment of a patient supported on the lying surface 7, wherein the indentations 34 are flexibly covered by the movable sliding panels 41, and thus simultaneously to the

Handling simplification a particularly good radiation protection for the attending physician is achieved.

The rotatable suspension of each sliding panel 41 in the upper region causes, at least as long as the Patientenlage ^¬ tion 4 is aligned horizontally, a torque caused by gravity on the from the normal position P. deflected sliding panel 41. This torque manifests itself in a restoring force F, which automatically drives the back ^¬ deflected sliding panel 41 when released to the normal position P. In order to prevent that, according to FIG 2 one of the shift fields falls in the vertical positioning of the patient support 4 41 through the now sidewardly acting gravity into the free ^¬ transfer position P ^Λ, each sliding panel 41 is a Fixier¬ element assigned 43, by means of which the respective sliding leaf 41 is fixable in the normal position P or if necessary fixed automatically.

In the illustrated embodiment, the fixing element 43 is designed as a magnetic closure with two corresponding magnets 44 and 45. In this case, the magnet 44 is arranged in each case on the sliding field 41 and the magnet 45 in each case at a corres ^¬ dierenden point of the body panel 30, which is selected such that in the normal position P of the sliding panel 41, the magnets 44 and 45 are applied in parallel poled together that due to the magnetic attraction of the magnets 44 and 45, the sliding panel 41 is held in the normal position P. Alternatively, one of the magnets 44 and 45 may also be replaced by a ferromagnetic element. Furthermore, instead of a magnetic closure, a snap-in closure, a fixing screw or the like can be used as the fixing element 43. A sliding panel 41 each associated stop 46 prevents the body panel 30, that the sliding panel can be pivoted 41 through the normal position P addition Wegge of the body panel 30 ^¬.

FIG. 3 further shows in greater detail the coupling unit

21, which serves for the relative fixation of the anti-scatter shield 20 with respect to the image receiver 3. The coupling unit 21 is designed as a plug-in connection in order to be able to easily and quickly remove the scattered radiation protection 20 from the image receiver 3 as needed, in particular outside the actual irradiation phase. The coupling unit 21 in this case comprises ei ^¬ nen pin 47, approximately in extension of a side edge 33rd protrudes beyond the lower edge 31 of the body panel 30, and a corresponding with the pin 47 bushing 48 which is fixed to a side surface 49 of the image receiver 3 and in which the pin 47 can be inserted. In order to prevent rotation of the anti-scatter device 20 in the inserted state about the axis of the pin 47, the pin 47 and the corresponding receptacle of the bush 48 preferably have a polygonal cross-section.

The bushing 48 is in turn adjustably mounted on the image receiver 3 by means of egg ^¬ ner linear guide in the transverse direction 17, so that the anti-scatter shield 20 can be performed nach¬ with a transverse displacement of the patient support 4 with respect to the image receptor 3. The cross-verifiability of the scattered radiation protection 20 with respect to the image receiver 3 further serves to be able to flexibly guide the antiscatter protection 20 around interfering edges of the stand 8 or the patient support 4, eg handles, etc. By suitably rounding off or starting the side edges of the anti-scatter guard 20, it is advantageously achieved that the anti-scatter guard 20 automatically deflects when it abuts against such a disturbing edge in the case of a longitudinal displacement relative to the patient support 4. A corresponding effect can also be achieved, for example, by one or more guide elements assigned to the antiscattering device 20.

As an alternative to the unilateral positioning of the antiperspirant protection 20 on the image receiver 3 shown in FIG. 3, a corresponding pin-socket pair can also be provided on each side of the antiscattering device 20 or image-receiving device 3.

In terms of further handling simplification, the anti-scattering device 20 is preferably designed as a carrier for a number of operating and control elements 50, eg, command buttons, etc. The these operating and control elements 50 zu¬ ordered (not shown) signal lines are preferably contacted via the pin 47 and the corresponding sleeve 48. The pin 47 and the socket 48 are designed for this purpose as an electrical plug-socket pair. Additionally or alternatively, the pin 47 and the corresponding socket 48 may be assigned an electrical safety contact, which only permits the switching on of the X-ray radiation R when the anti-scatter shield 20 is attached to the image receiver 3.

In FIG 5, an alternative embodiment of the Streustrah¬ lenschutzes wherein the shift fields is shown 20, 41 non-rotatably hung on the body panel 30, but cher in seitli ^¬ direction are slidably guided thereon by means of guide rails 51st Each sliding panel 41 is associated here with a (schematically indicated) spring element 52 which pretensions the respective sliding panel 41 in the normal position P or opposes a deflection of the sliding panel 41 with a restoring force F directed sideways, which automatically actuates the sliding panel 41 from the release position P ^Λ returns to normal position P. This restoring force F causes, in particular, that the respective sliding field 41, as long as it is not manually deflected by overcoming the restoring force F, regardless of the orientation of the anti-scattering device 20 in the surrounding space always in the normal P position. Against an excess of the normal position P Auslenkeung of each sliding panel 41 in ^¬ We kung direction of the restoring force F of each sliding panel 41, in turn, chert gesi¬ by stops 46 of the guide rails 51st

With reference to Figures 6 and 7 connected to ^¬ plugged scattered ray protection 20 show the X-ray apparatus 1, respectively in front view, is again illustrates that by effected by the coupling element 21 relative fixing of the Streustrah- lenschutzes 20 with respect to the image receiver 3 of the Streustrah ^¬ lenschutz 20 always and automatically with the image receiver 3 is thereby always positioned in the central field of X-ray scattering radiation.

6 shows in this regard the image receiver 3 and the scattered radiation protection 20 in relation to the patient support 4 foot side arranged position. The X-ray source 2 is hier¬ automatically moved along with the image receptor 3, so that the Strah¬ lung direction 9 with respect to FIG 1 unchanged perpendicular bezüg is oriented 7 ^¬ Lich of the lying surface, the central ray Z of the primary x-ray radiation R is but shifted in accordance with the foot side.

FIG. 7 shows the image receiver 3 and the antiperspirant shield 20 in the position displaced with respect to the patient support 4 at the head end, wherein the X-ray emitter 2 is left in a central position with respect to the patient support 4 in analogy to FIG. By action of the coupling element 18 in this case the X-ray source 2, and thus the radiation direction 9, tilted such that the central beam Z is in turn approximately centrally aligned with the image receiver 3.

Subsequently, the effect of the stray radiation protection ^¬ 20 according to the invention is based on a test measuring the Streustrah¬ lencharakteristik the X-ray apparatus 1 with and without stray radiation protection 20 shows. On the basis of such

Test measurements can in particular also the expedient Dimensio ^¬ discrimination of scattered radiation protection be determined 20th

The measuring conditions on which the test measurement is based are explained with reference to a schematic front view of the X-ray device 1 according to FIG. In this illustration ge ^¬ is dashed rectangular measurement surface 80 indicated, the horizontal extension 104 cm and whose vertical Erstre ^¬ ckung is 70 cm. The measuring surface 80 covers in the vertical direction a height range of 110 cm to 180 cm above the

Bottom plate 12, which essentially corresponds to the working height range in which in practice The upper body and head area of a treating physician, which is particularly exposed to scattered radiation, is, for example, of interest.

In FIG 8 of 20 occupied in a central positioning Flä¬ lenschutz of the Streustrah ^¬ is also shown in dashed lines chenbereich.

The measuring surface 80 is arranged parallel to the front edge 22 of the patient support 4, and this upstream by a distance of about 30 cm. The measuring surface 80 is thus located at a distance from the front edge 22 of the patient support 4, as is typically taken also em body of a physician during the treatment.

In particular, the measuring surface 80 is thus arranged such that the inserted anti-scatter shield 20 is interposed between the X-ray emitter 2, the patient support 4 and the image receiver 3 on the one hand and the measuring surface 80 on the other hand. The test measurement was performed on a Röntgenvorrich- processing of the "Iconos R 100" type (Fa. Siemens) at a throughput ^¬ leuchtungszeit of one minute, a field size of 20.7 x 20.7 cm, a tube voltage of 105 kV and a Röhren¬ current 1.1 mA. Instead of an irradiated patient, a pelvic phantom was placed on the lying surface 7 in the radiation field together with a 10 cm star-shaped water phantom as an artificial scattering body.

The scattered radiation dose D was measured at several gitterar- tig arranged within the measurement area 80 measurement points M. The thus measured scattered radiation dose D for purposes of comparison at each measuring point M on the one hand in Abwesen¬ integral of the scattered radiation protection 20 and the other hand with Zvi ^¬ schengeschaltetem scattered radiation shield 20 measured.

In FIG. 9, the result of this test measurement is shown in a diagram of the scattered radiation dose D as a function of the horizontal Deviation x from the vertical center line 81 of the measuring surface 80 is shown. The symbols of the diagram connected in each case by a common line thus represent the course of the scattered radiation dose D (x) along a horizontal line of measuring points M. Measured values are shown in this case by empty (ie bordered) symbols connected by dashed lines of the anti-scatter device 20 were measured. By filled symbols connected by solid lines, however, measured values are shown, which were measured in the presence of the anti-scattering device 20. The same symbol shape (square, circle, ...) corresponding to each ^¬ weils a common working height h. The eingetra ^¬ genes in FIG 9 curves are used for better labeling zusammengehö¬ engined measuring points.

From the graph of FIG 9 shows that in the absence of the anti-scatter protection 20, the scattered radiation dose D in the loading ^¬ reaching the center line 81 is particularly large, and with the horizontal deviation grow ^¬ x bell-shaped on both sides decreases. In this case, a particularly high scattered radiation dose D is measured at an average working height h "140 cm above the bottom plate 12, while the scattered radiation dose D is lower both at lower and higher working heights h.

FIG. 9 furthermore shows that, when the scattered radiation protection 20 is used, the scattered radiation dose D is reduced to a value of well below 10 μGy in a central region of approximately x. + -. 25 cm about the center line 81 for all working heights h. so that the attending physician in this central area by the antiperspirant 20 effectively shielded against scattered radiation.

Claims

claims

1. X-ray device (1) with an X-ray emitter (2), with a in a radiation direction (9) arranged at a distance to this image receiver (3) and with a between the X-ray source (2) and the image receiver (3) arranged patient support (4) wherein the Rela¬ tivstellung of the X-ray source (2) and the Bildemp ^¬ scavenger (3) of the patient support (4) least one spatial direction (16,17) with respect to in min- adjustable ge characterized by a scattered ray protection (20), wel ¬ cher by means of a coupling unit (21) in a fixed relative position with respect to the image receiver (3) and / or the X-ray source (2) is fixed as a reference object such that when adjusting the Refe ^¬ rence object (3) with respect to the patient support (4) of the anti-scatter (20) with the reference object (3) is guided ^¬ .

2. X-ray device (1) according to claim 1, characterized in that the anti-scatter shield (20) is designed as a self-supporting screen.

3. X-ray device (1) according to claim 1 or 2, characterized in that the anti-scatter shield (20) has a substantially flat body field (30) ^¬ whose plane is approximately parallel to a front edge (22) of the patient support (4) and about is aligned perpendicular to a lying surface (7) thereof.

4. X-ray device (1) according to claim 3, characterized in that on the side facing away from the Patientenla ^¬ gerung (4) upper edge (32) of the body field (30) of this in the direction of the Patientenlage- (4) angled field of view ( 40) is arranged.

5. X-ray device (1) according to claim 3 or 4, characterized in that at least one side edge (33) of the body panel (30) has a recess (34) on ^¬ .

6. X-ray device (1) according to one of claims 3 to

5, characterized in that at least one edge (33) of the body field (30) is a movable sliding field (41) is arranged, which in a normal position (P) increases the area of the body field (30), and from the normal position (P ) can be deflected in an at least partially retracted in the surface area of the body panel (30) free ^¬ transfer position (P ^Λ).

7. X-ray device (1) according to claim 6, characterized in that the or each sliding field (41) against a restoring force (F) from the Normalposi ^¬ tion (P) is deflected.

8. X-ray device (1) according to claim 7, characterized in that the or each sliding panel (41) is suspended eccentrically pivotable, that acts on the sliding panel (41) gravity acts as a restoring force (F).

9. X-ray device (1) according to claim 7 or 8, characterized in that the or each sliding field (41) by a restoring force (F) generating Federele ^¬ element (52) is biased in the normal position (P).

10. X-ray device (1) according to one of claims 6 to 9, characterized in that a fixing element (43) by means of which the or each sliding panel (41) in the normal position (P) can be fixed.

11. X-ray device (1) according to one of claims 1 to 10, characterized in that the anti-scatter shield (20) can be removed from the relative position predetermined by the coupling unit (21) with respect to the reference object.

12. X-ray device (1) according to claim 11, characterized in that the coupling unit (21) for releasably fixing the anti-scatter shield (20) is designed as a plug connection.

13. X-ray device (1) according to one of claims 1 to 12, characterized in that the anti-scatter shield (20) consists essentially of a transparent, X-ray absorbing material.

14. X-ray device (1) according to claim 13, characterized in that the X-ray absorbing material is lead acrylic glass.

15. X-ray device (1) according to one of claims 1 to 14, characterized in that the anti-scatter shield (20) as a carrier of a number of operating and control elements (50) is formed.