SE463237B - Installation for X-ray diagnosis or the like - Google Patents

Abstract

In an installation for X-ray diagnosis or the like, a radioactive source is used which can be supported by a pillar stand or overhead stand 2. The radioactive source can be set in various basic-setting positions for vertical and horizontal ray path. Beneath a patient table there is a cassette holder 7 which houses a receptor for vertical ray path. In addition, a cassette holder 8 having a receptor for horizontal ray path can be applied to the cassette holder 7. The stand supporting the radioactive source is mechanically connected to the holder 7 by members which bring about forcible horizontal movement of the radioactive source 4 upon horizontal displacement of the holder 7, but which allow relative movement in the vertical direction between radioactive source and holder. <IMAGE>

Description

O '\ (N PO (JJ in Sweden in so-called Primary Care Centers and in the USA so-called

Free Diagnostic Centers (FDC).

In a previously known roof or pillar stand cooperating with a patient table, a telescopic link arm is used which is connected via ball joints to a radiation source and a cassette holder, whereby, for example, when moving the radiation source . However, if you want to take pictures with a horizontal beam, another cassette holder must be used. Furthermore, the link arm must be removed, which means an extra complication. A further aggravating circumstance is that centered beam path cannot be maintained with consequent time-consuming and inconvenient manual adjustment and poorer image.

Another disadvantage that characterizes this and other known systems is that the operator achieves adjustment by influencing the radiation source itself, which is normally at a relatively high altitude. As a result, the operator must assume an uncomfortable and, from an ergometric point of view, unsuitable working position when working at shoulder height.

In other known types of X-ray stands cooperating with a patient table, for example of the type BRS (Basic Radiographic System according to the WHO specification), a wheel-mounted, mobile examination table in the form of a relatively tripod separate unit was used. When the table or stand is moved, for example in connection with setting movements, there is a risk of collision between the two units.

SE, C, 8506093-7 (AO Medical Products) describes a plant of the type in question here which has a more universal use and which can consequently be used for taking many different types of X-ray images. The plant is largely based on a developed electronic control system ro w -q between components included in this. The operator's work is significantly facilitated, but the costs for the plant as a whole will be comparatively high.

The above description shows that there is a need for a complete facility for X-ray or similar examinations, which without being too costly allows different types of examinations to be performed and which can effectively cooperate with an examination or patient table. .

Object of the invention Accordingly, an object of the invention is to provide a plant of the type indicated, which is constructively simple but which nevertheless has more or less universal use.

Another object is to provide a system which eliminates specified and other disadvantages of known column and roof racks and simplifies the operator's work-on '. setting with less risk of occupational injuries.

A further object is to provide a facility which enables the taking of images with both vertical and horizontal beam path using a single beam source with centered beam path and with "passive patient", so that the equipment moves relatively * the patient's who do not have to perform ktmplicerade'eïler risky tube readers associated with the survey.

Brief description of the invention These and other objects are fulfilled by a plant according to the invention which is of the type stated above and which is essentially characterized by measures specified in the characterizing part of claim 1.

A plant according to the invention becomes universal, ie.

Q! C: -l PC.) CN it can be used for1 flfl ïh of many different types of X-ray examinations.

In its two basic setting modes, the system can operate with a predetermined film-focus distance, so-called SID (= Source n Image Distance). Displacement of the primary and / or secondary cassette holder results in a corresponding displacement of the radiation source while maintaining the basic setting position.

When transferring a patient by lowering the table, the receptor can follow the movement without this having any effect on the radiation source. At the same time, the operator's most important task, which is the adjustment of the receptor, is facilitated, so that the correct exposure of the intended body part will be performed. In the application of the invention, this movement can take place at a comfortable working height, which also applies to the additional task that the operator has to perform between each exposure, namely changing the cassette in the cassette holder.

The operator also does not have to - as in some previously known plants - influence the radiation source at an uncomfortable working height, since the radiation source follows horizontal adjusting movements of the receptor performed by the operator, the radiation source always being directed for correct, centered radiation towards the receptor.

In this respect, the invention entails an important advantage in that the obtained image names will be of high quality, i.e. show great sharpness. The risk of the need for readmissions, which entails that the patient is exposed to an unnecessarily high X-ray dose, can thereby significantly reduce IaS.

A special advantage that the invention offers is that it is applicable to different types of facilities, such as for example to column stands resp. ceiling-mounted stands. Existing facilities can also be rebuilt with comparatively simple 463,237 means so that they become a facility according to the invention and thereby obtain its advantages.

Of particular advantage is that the patient is constantly passive during the examination, ie the patient does not need to be positioned in order for the required exposures to be performed.

In practice, it is preferred that the plant is designed as stated in claim 2, ie so that relative movement between the image receptor and the radiation source is also permitted in the Y-direction.

The means which enable said relative movements can be of different kinds. Possibly - when a system with a column stand is used - this can have a vertical slot in which the element which supports the primary and secondary cassette holder amounts. Inside the stand, there may be suitable coupling means that allow current relative movement.

However, the required means may instead be located on the outside of the column frame.

In the case of a roof-supported stand, the relevant members may have a different design. In some cases you can e.g. use a telescopic unit which is supported by the roof rack together with the radiation source and which in turn supports the cassette holder via a suitable coupling device.

This telescopic unit can also be adjusted in different inclination relative to the vertical line to ensure in this way that exposure with angled beam path can also be performed.

The radiation source can then be adjustable in a number of predetermined positions which form desired angles of incidence for 465 23? emitted rays to the respective receptor.

Further features of the invention will become apparent from the following description of some embodiments thereof. The description is made in connection with the attached drawings.

Brief description of the drawing figures Fig. 1 is a perspective view of a system equipped with a column stand for X-ray or similar examination, wherein the column is connected via a mechanical coupling to a holder for a receptor for X-ray radiation in connection with a patient or examination table.

Fig. 1a is a section along the line I-I in Fig. 1.

Figs. 2 and 3 are partial perspective views indicating something about the movement pattern of the radiation source during its conversion from vertical to horizontal radiation path.

Fig. 4 is a perspective view of the plant according to Fig. 1 in its basic setting position for horizontal beam path.

Fig. 4a is a front view of a secondary cassette holder adjustable for different cassette sizes for the column stand according to Fig. 4.

Fig. 5 is a perspective view of an embodiment with a roof-supported frame and with the radiation source in the basic setting position for vertical beam path.

Fig. 6 is a front view of the embodiment according to Fig. 5, wherein dash-dotted lines indicate the possibility of setting the radiation source for angled beam path.

Fig. 7, finally, is a side view of the roof-supported frame of Figs. 5 and 6, solid lines showing the source of radiation in the basic setting position for vertical beam and dashed lines the beam source in the basic setting position for horizontal beam.

Description of preferred embodiments Fig. 1 shows a system for X-ray diagnostics with a column frame 2 which is movably supported in a first direction, here called X-joint, along the long side of a patient table 3.

The column frame 2 is then supported by supporting and guided beams 5 arranged in connection with a wall in a room which occupies the plant.

The column frame 2 has a perpendicularly projecting arm 2a from which a downwardly movable beam 2b extending along the arm 2a emanates, which carries a radiation source 4 for X-ray or similar radiation.

The radiation source 4 is then movable relative to the column frame perpendicular to the longitudinal direction of the table, which direction is here referred to as the Y-joint.

The arm 2a can be movable in the vertical direction relative to the column frame 2, or the beam 2b can be telescopic, ie so that the radiation source 4 is movable in a corresponding manner in the vertical joint, here referred to as the Z-joint.

The radiation source 4 is consequently movable in the X, Y and Z directions.

However, the radiation source is also pivotable about a horizontal axis, with the arm 2a parallel to the axis, and further pivotable about a vertical axis, e.g. in that the vertical beam 2b is pivotable about the part 2c which supports the beam 2b on the arm 2a.

The different sources of movement of the radiation source 4 with displacement in the X-, Y- and Z-directions as well as pivotability about a horizontal and a vertical axis are marked with corresponding arrows in Fig. 1.

CF.

Lv., | FO C) J The table 3 which is supported by a frame 6 is movable in the vertical direction, ie Z-joint, to facilitate transfer of a patient from e.g. a stretcher. Under the table there is a holder 7 for a cassette which receives a receptor (not shown in Fig. 1) for radiation emitted by the radiation source 4.

This holder 7 is located close under the table 3 but is free-standing in relation to this.

The holder 7 is supported via an arm 2d bent at right angles by the column 2. The arrangement is then such that the arm 2d is movable in the vertical joint, ie Z-joint, relative to the column 2.

For this purpose, the column carries a mechanical coupling device that allows this possibility of movement.

The holder 7 has a part 7a which is moved around the table in relation to the far long side of the column 2 and which there forms an operating part for an operator who operates the plant.

This can, by actuating the part 7a, displace the holder 7 relative to the table 3 and a patient present thereon. When moving in the longitudinal direction of the table, ie X-joint, the column frame 2 and the radiation source 4 follow the movement.

Fig. 1 also shows that the column frame 2 is movable in the Y-direction relative to the table. For this purpose, the column frame is supported by a special bracket part with a portion 2i enclosing the support and guide beams 5 and another portion 2e projecting perpendicularly from the beams 5 and forming a guide for a number of rollers 2f stored in the column frame. This is then movable in the Y-direction.

The action of the operating part 7a in the X- and / or Y-direction thus causes P a corresponding displacement of the column frame 2 and thus the radiation source 4.

Fig. 1 shows the radiation source 4 set in a basic setting position for vertical, centered radiation path towards a cassette accommodated in the holder 7 with a receptor. nn The above-mentioned adjustment of the holder 7 by actuation of the operating handle 7a thus entails a corresponding displacement of the radiation source while maintaining the basic setting position for vertical beam path.

The column 2 also has an arm 2g on which a third or tertiary holder for a receptor (not shown) accommodated in a cassette (not shown) is pivotally mounted.

When taking e.g. lung images - when the patient table does not need to be used - the radiation source and this receptor holder 2h can be used. The column frame 2 can then possibly be displaced laterally from the table 3.

The beam source 4 has a telescopic operating arm 4a with a handle 4b with which it can - conveniently accessible to an operator - be made to perform the above-mentioned swinging movements in order to assume its various basic setting positions for vertical resp. horizontal beam path.

Fig. 2 and Fig. 3 then indicate some of the different movements which will be performed to move the beam source from the basic setting position for vertical beam path shown in Fig. 1 to the basic setting position for horizontal beam path shown in Fig. 4.

Fig. 4 shows, as mentioned above, the plant according to Fig. 1 in a basic setting position for horizontal beam path.

A secondary cassette holder 8 has been applied to the operating part 7a of the primary cassette holder 7, which can accommodate replaceable cassettes with associated receptors.

It can be seen that the conversion of the radiation source from the vertical beam path according to Fig. 1 to the horizontal beam path according to Fig. 4 has led to a certain lateral displacement of the focus, which necessitates a corresponding compensation of the secondary cassette holder 8. It should be noted that the cassette holder. \ 3 CN 'NJ 10 clean 8 allows the insertion of different sized cassettes, which also requires the possibility of lateral displacement of focus, ie so that the central beam from the radiation source always falls in the center of the current cassette 9. fl A basic design of a cassette holder that offers this possibility is shown in Fig. 4a. The cassette holder 8 then comprises two angular profiles 8a, 8b which are provided with resistors which form toothed portions which co-operate with an intermediate gear 8c.

Possibility of height adjustment of the cassette holder is also allowed. For this purpose, the angle profile part 8a occupies a holder part 8a! With a rack-provided portion. This is engaged with a gear 8d, which in turn is engaged with another gear 8e, the diameter of which is half the diameter of the gear 8d.

The gear 8e is engaged with a rack 8f connected to a hook element 8g. The hook element is arranged to cooperate with the telescopic control arm 4a of the radiation source.

By the presence of two gears 8d, 8e with specified diameter ratios, a displacement of the hook element 8g in a certain direction will cause a corresponding displacement of the cassette holder part 8a¿ in the same direction, and more precisely half as long a distance.

The telescopic operating arm Äa of the radiation source 4 is shown in Fig. 4, resting against the hook element 8g, and the cassette holder 8 is adjusted so that the center of the cassette coincides with the focus of the radiation source.

If it is assumed that the set position applies to a cassette measuring 18 x 24 cm, which is then to be replaced with a cassette measuring 30 x 40 cm, then the arrangement shown will mean that part 8a of the cassette holder will be displaced. half of the difference between the dimensions 18 and 30, ie 6 cm upwards in Figs. 4 and 4a. The cassette holder part 8b in turn will be displaced by half the difference between 24 and 40, ie 8 cm to the right in Figs. 4 and 4a.

Using the hook element 8g and the telescopic operating arm 4a, it is ensured that the radiation source undergoes a corresponding movement, so that the focus coincides with the center of the new cassette.

With the aid of another device, it is thus possible to ensure centering in both the Z-joint and the X-joint. The distance between the radiation source 4 and the secondary receptor in the cassette 9 determines the SID.

In different desired ways, e.g. by mechanical or electronic means, it can be ensured that SID receives a predetermined value.

The operating handle 7a can be used to provide a purely mechanical device for the intended purpose.

For the embodiment described here, it thus applies that an adjustment of the primary or secondary cassette holder by the operator grasping the cassette holder part 7a extending around the table edge and for this in X- and / or Y-direction, via the arm 2d, the existing cup the radiation source and the column frame 2 the radiation source to be imparted a corresponding displacement.

In other words, there is a mechanical connection between the radiation source and the receptor that makes this possible.

At the same time, the radiation source can be easily set in its basic setting positions for vertical resp. horizontal beam path without the need for more complicated electronics. -lë O \ (_: I h.) L- I 12 However, the plant may adopt certain electronics to facilitate and promote this desired effect.

Thus, there may be a control panel, e.g. in connection with the control part 7a. Some of e.g. the movements of the radiation source 4 can then be effected with the aid of electric motors. These are then controlled from the control panel.

In addition, there may be magnetic brakes for e.g. the pillar stand 2 and the arm 2a. Their switch-on can also be regulated from the control panel.

When the secondary cassette holder 8 is applied, which can be done in different ways, e.g. by swinging it or folding it up from a “parking position” under the table, this can also lead to automatic activation of certain electrical circuits that facilitate the operation of the system.

The above means that a plant according to the invention can be equipped with various electronic components which can be selected depending on the desired degree of automation.

Fig. 5 shows the application of the invention to a roof-supported stand. There is a carriage (not shown) which is movable in the roof in the X- and Y-directions and which via a vertical arm 2a with a vertical beam 2b connected to it supports the radiation source 4. This has the above-mentioned movement possibilities and can be adjusted by means of the control handle 4b.

The beam 2b is connected via a U-shaped element 10 to a telescopic pillar-like unit 11, the lower part of which, via a coupling device 12, supports the cassette holder 7 with its operating part 7a.

The various setting possibilities described for the embodiment in connection with Figs. 1-4 are also possible in this embodiment. Fig. 6 illustrates that this embodiment can also be used for angled beam path, in which case the telescopic pillar unit 11 is pivoted outwards. A suitable guide shaft 12å enables the cassette holder to be adjusted parallel to the table 3.

Fig. 7 illustrates further details in connection with this embodiment, and i.a. what different movement possibilities the constituent units have.

Dotted lines illustrate the basic setting position for horizontal beam, whereby a secondary cassette holder 8 is placed on the operating part 7a as in the embodiment according to Figs. 1-4.

Claims (7)

JP »O \ C) I PO O! <1 14 Patent claims An apparatus for X-ray diagnostics or the like comprising a) a patient table (3) supported by a frame (6), b) a relative table (3) in its longitudinal and transverse direction, here called X- resp. Y-joint, movable primary holder (7) for a receptor with a horizontal basic setting position for vertical, centered beam, c) a secondary holder (8) applicable to the holder (7) for a receptor with a vertical basic setting position for horizontal centered beam path, d) a beam source (4) supported by a stand (2), movable in X-, Y- and Z-direction for operation of both receptors, which beam source (4) is also pivotable about at least a horizontal axis and arranged to emit vertical and horizontal centered radiation towards a receptor in the primary and a receptor in the secondary holder (7: 8), e) means connecting the primary holder (7) to the radiation source (4) supporting frame (2), so that a displacement of the holder relative to the table (3) causes a movement of the radiation source, characterized in that the frame (2) supporting the radiation source (4) is mechanically connected to the primary holder (7) via means which provide for forced controlled horizontal movement of straw The l-source when the holder (7) is moved horizontally in the X-direction, but allows relative movement in the Z-joint between the radiation source and the holder. Plant according to claim 1, characterized in that said means when displacing the holder (7) in the Y-direction also allows relative movement in this direction between the radiation source (4) and the holder (7). 15 Plant according to claim 1 or 2, characterized in that said means are arranged to maintain a set basic setting position for vertical beam path between beam source (4) and receptor in the case of horizontal displacement of the holder and also to allow such vertical movement between the holder (7) and the beam source (4) that, after application of the secondary holder (8) and rotation of the beam source about the horizontal axis, the beam source can be caused to assume a basic setting position for horizontal beam path towards the secondary holder ( 8) receptor, which the latter basic setting position is maintained by forced movement of the radiation source during horizontal movement of either holder. Plant according to one of Claims 1 to 3, characterized in that the radiation source (4) is adjustable in a number of predetermined positions which form the desired angles of incidence for emitted rays towards the respective receptor. Plant according to Claim 4, characterized in that in the predetermined setting positions of the radiation source (4) there is one or more of these activatable contact functions between the radiation source and the respective receptor unit. Plant according to one of Claims 1 to 5, characterized in that the radiation source (4) is supported by a column frame. Plant according to one of Claims 1 to 5, characterized in that the radiation source is supported by a roof rack.