DE19904554A1 - Orthesis has distal and proximal rails, linkage, spring arrangement, traction or thrust element, link point and force transmission element - Google Patents

Abstract

Distal and proximal rails (1,1a,2,2a) are fixed to the distal or proximal body limb, and are re joined by a linkage (5,5a) so as to swivel on a swivel axis (6). A spring arrangement (7) acts between the distal and proximal rails , with a spring which exerts pre-tensioning force on the rails. The spring arrangement is fixed to a rail and cooperates with a traction or thrust element (8) linked to a link point (10) on the other rail or to a force-transmission element (9) on the other rail.

Description

The invention relates to an orthosis for reducing Stretching and / or flexion deficits, for example one Elbow or knee orthosis, according to the preamble of Claim 1.

In particular, joint capsules and / or connective tissue have for example after ligament surgery, accidents, ignition extensions etc. often have a stretch or flexion deficit. This means that a distal limb, for example a Forearm, no longer completely in its normal Extension or flexion position with respect to a proximal one Limb, for example an upper arm can be.

To counter such an extension or flexion deficit As is known, attempts are made to counteract the shrinkage  again by stretching the distal limb with respect to the proximal limb by means of a so Quengel device mentioned in a certain Quengel fixed position or in this Quengellage by spring is biased by force.

Such known Quengel devices work in one Direction, d. H. either in flexion or in extensions direction. A patient has both a flexion as well Extension deficit, the Quengel device must a certain treatment time, during the example was tormented in the direction of flexion, otherwise places or be converted to also in the extension direction to whine.

The invention has for its object to an orthosis create the most simple and effective Way the simultaneous treatment of flexion as well Extension deficits enabled.

This object is achieved by the features of Claim 1 solved. Advantageous embodiments of the Invention are specified in the further claims.

In the orthosis according to the invention, the swiveling comprises range of rails and an extension swivel range section as well as an immediately adjacent one Flexion swiveling section, the Federeinrich with the rails within the extension swivel section in one of the rails in extensions  direction and within the flexion swivel range section in a be the rails in the flexion direction is in an active connection and the Rails continuously from extensions to flexions swivel range section or from the flexion to the extents Sions swivel range section are transferable.

According to the invention, an orthosis is thus created whining in two directions, d. H. as well in Extension and flexion direction. Are located the rails in the extension swivel area section, see above the distal limb, for example the forearm, pushed in the direction of extension. By bending the forearm against the biasing force of the spring, the shooting can now NEN are so angled that a certain dead center is achieved by neutralizing the preload will, d. H. neither in the extension nor in the flexion direction works. This dead center also represents the limit of the Extension swivel range section. Is the dead center slightly exceeded, d. H. the rails will continue angled, the rails step into the flexion swivel area section in which the rails and thus the Forearm of the patient by the biasing force of the spring be pushed further in the flexion direction. Conversely it is possible for the patient to stretch the splints of the forearm from the flexion swiveling section into the To transfer extension swivel section.

The orthosis according to the invention thus enables a run des, continuous switching between Quengeln in Exten  direction and whining in the direction of flexion. The effect In many cases, treatment can be slow be significantly increased. Furthermore, it is not required need to rebuild the rail or put it in a different way, if changed between the two Quengel directions shall be.

According to an advantageous embodiment of the invention is a pulling or pushing element, for example a pulling or push rod, such on a power transmission element ment, for example at a different shooting position on a rail lockable dial, attached directs that the articulation point in the flexion swivel realm section with respect to one by the pivot axis and the spring position determined neutral level on a other side than in the extension swivel area section located. Here, he is only a single spring required to the rails in both extensions and to preload in the flexion direction. Furthermore, he can orthosis according to the invention on very compact and optically speaking manner.

An adjustment mechanism is preferred, for example in the form of a worm wheel / worm drive, with which the relative position of the setting wheel can be changed is.

According to a further advantageous embodiment the spring device one of the spring in the biasing direction urged spring guide element, the movement  of the spring guide element actuated by means of an outside blockable blocking element and the pull or push element when the spring guide element is blocked by the spring guide Rungselement is detachable. This makes it easy Way possible, the biasing force of the spring from the shooting uncoupling. This can relieve the patient and be advantageous for swivel range adjustment work. The invention is described below with reference to the drawings exemplified in more detail. In these show:

Fig. 1 is a schematic, somewhat shortened Dar position of an orthosis according to the invention for the elbow area, where the brace is at the extension end stop,

Fig. 2 is a partially broken side view of the orthosis of Fig. 1, wherein the BEFE stigungsbänder are omitted,

Fig. 3 is a partially broken side view of the orthosis of Fig. 1 in the maximum flexed position,

Fig. 4 is a horizontal section through the front shown in FIG. 1 Orthesenbestandteile,

FIG. 5 shows an enlarged illustration of the region of the orthosis of FIG. 4 near the pivot axis, and

Fig. 6 is an exploded view of the front orthotic components shown in Fig. 1.

The orthosis according to the invention has, as can be seen from FIG. 1, a distal pair of rails with distal rails 1 , 1 a and a proximal pair of rails with proximal rails 2 , 2 a. The rails 1 , 2 and 1 a, 2 a are placed on opposite sides of the elbow joint to be treated, the distal rails 1 , 1 a using two spaced fastening straps 3 on the lower arm and the proximal rails 2 , 2 a using two be spaced fastening straps 4 are attached to the upper arm. Of the two fastening straps 3 , 4 only one fastening strap 3 , 4 is shown for the sake of clarity. The fastening straps 3 , 4 can be closed in a known manner, for example by means of Velcro fasteners.

The rails 1 , 2 are connected by means of a rail joint 5 and the rails 1 a, 2 a by means of a rail joint 5 a ge articulated together. When bending or stretching the forearm relative to the upper arm, the distal rails 1 , 3 a are pivoted about a pivot axis 6 relative to the proximal paint rails 2 , 2 a.

In order to be able to treat a flexion and / or extension ability restricted by injuries, operations, inflammation, etc., the orthosis according to the invention has a spring device 7 which interacts with a force transmission device 9 via a rod-shaped thrust element 8 . The power transmission device 9 is designed as a disk-shaped setting wheel 9 a, which is connected to the proximal splint 2 in a rotationally fixed manner.

The thrust element 8 is pivotally articulated on the adjusting wheel 9 a at a pivot point 10 spaced from the pivot axis 6 . The other end of the thrust element 8 is gelig kig attached to a coupling element 11 which is held together with a spring guide element 12 in the form of a spring guide sleeve 12 a longitudinally displaceable in a bore 13 of a spring housing 14 . The spring guide sleeve 12 a receives in its interior a spring 16 in the form of a spiral compression spring. The spring 16 rests with its front end on an inwardly projecting shoulder 17 of the spring guide sleeve 12 a. At its rear end, the spring 16 is abge based on an abutment 15 . The abutment 15 is in turn longitudinally displaceably held bar within the spring housing 14 , the position of the abutment 15 to change the Federvor voltage can be changed by means of an adjusting screw 18 protruding beyond the spring housing 14 . It can be seen that the spring preload increases the further to the left ( FIG. 4) the abutment 15 is.

The coupling element 11 has on its front side an enlarged head 19 and an adjoining shaft 20 with a reduced diameter. The shaft 20 is slidably guided in an axial bore of the spring guide sleeve 12 a. Furthermore, the shaft 20 is about twice as long as the front region of the spring guide sleeve 12 a, in which the shaft is guided. Through the front of the spring tension 16, the spring guide sleeve 12 a to the front, ie in Fig. 4 to the left, urged so that it rests against the plane formed by the head 19 shoulder of the couplers coupling member 11, the coupling member 11 to gether with the thrust element 8 pushes forward. In this way, in the position shown in FIGS. 1 and 2, the distal rails 1 , 1 a in a clockwise direction with respect to the proximal rails 2 , 2 a, ie in the direction of extension, biased.

The rotationally fixed connection between the setting wheel 9 a and the proximal rail 2 is given in that the setting wheel 9 a leads out as a worm wheel with spur gearing which engages with a worm 21 held on the proximal rail 2 . The screw 21 is rotatably mounted in a screw holder 22 , which in turn is screwed to a projecting retaining tab 23 of the proximal rail 2 (see also FIG. 6).

By turning the screw 21 , the relative rotational position of the setting wheel 9 a can be changed relative to the proximal rail 2 ver. Since the worm / worm gear is a self-locking gear, the set position is retained without any additional locking means. As can be seen from FIG. 1, the position of the articulation point 10 changes relative to the proximal splint 2 when the adjusting wheel 9 a is rotated about the pivot axis 6 . In this way, in particular the position can be changed from which the orthosis merges from quenching in the extension direction to quenching in the flexion direction, as will be described below.

In the position shown in FIGS. 1 and 2, the orthosis is in an extension swiveling section, ie the distal splint 1 and thus also the forearm is urged clockwise relative to the proximal splint 2 due to the pushing force 8 transmitted by the pushing element 8 , so that the forearm is fully extended. As can be seen, a slight hyperextension, ie an extension of over 180 °, is possible by adjusting the orthosis accordingly. Now the patient bends his forearm and thus the dista len rails 1 , 1 a counterclockwise to come into the position shown in Fig. 3, he must first overcome the biasing force of the spring 16 , since with this movement the thrust element 8 Pushes the spring guide sleeve 12 a backwards and thereby compresses the spring 16 .

The compression of the spring 16 continues until a pivot angle is reached at which the articulation point 16 and a spring-side articulation point 24 of the thrust element 8 and the pivot axis 6 lie in a common plane, which can be referred to as a neutral plane. In this neutral plane, the spring force of the spring 16 acts neither in the extension nor in the flexion direction, since the spring force passes directly through the pivot axis 6 .

If the forearm and thus the distal splints 1 , 1 a are pivoted further in the direction of the position shown in FIG. 3, then the dead center lying in the neutral plane is overcome and the biasing force of the spring 16 acts in the direction of flexion, ie counterclockwise ( Fig. 3).

The thrust element 8 is thus articulated on the proximal splint 2 in such a way that the articulation point 16 is in the flexion swiveling region section with respect to the neutral plane on a different side than in the extension swiveling region section. The rails 1 , 1 a, 2 , 2 a can be continuously transferred from the extension into the flexion swiveling section or from the flexion into the extension swiveling section.

As can be seen, the spring 16 in the swiveling section section after overcoming the dead center in the neutral plane continuously expand again, so that the spring guide sleeve 12 a and thus the coupling element 11 with the thrust element 8 pushed to the front.

In order to be able to decouple the spring preload from the thrust element 8 , the spring device 7 has a locking device 25 with which the longitudinal movement of the spring guide sleeve 12 a can be blocked. The locking device 25 includes in the illustrated embodiment, a spring housing 14 rotatably mounted pivot lever 26 with which an inner, not shown locking bolt can be pivoted to the extent that it comes with the spring guide sleeve 12 a in locking engagement. The locking can only take place in a position in which the spring guide sleeve 12 a is shifted a certain amount to the rear, ie when the spring 16 is compressed. Since the spring guide sleeve 12 a is present only in its front end on the wide linearized with the ver head 19 of the coupling member 11 shoulder formed and the coupling element 11, moreover, is guided longitudinally displaceably within the spring guide sleeve 12 a, the coupling member 11 can now guide sleeve without a spring 12 a, and be forward, that is, moved so freely without loading by the spring 16 in FIGS. 2 and 4 to the left. The coupling element 11 is pulled out of the spring guide sleeve 12 a a bit, but remains in guide engagement with the spring guide sleeve 12 a due to the rearward elongated shaft 20 .

If the locking device 25 is released again, the pre-tensioning force of the spring 16 is again transmitted via the spring guide sleeve 12 a to the coupling element 11 and thus to the thrust element 8 .

This avoids that the spring guide sleeve 12 a after the release of the locking device 25 soars forward, the removal of the locking effect is advantageously only achieved when the spring guide sleeve 12 a has been pushed slightly further back by means of the coupling element 11 ver.

In order to indicate the biasing force of the spring 16 , the spring housing 14 has a lateral longitudinal slot 27 into which a display pin 28 of the abutment 15 protrudes from the outside.

In the following, with reference to FIGS. 1, 5 and 6, the Ge staltung of the orthosis in the pivot axis region near explained in more detail.

The pivot axis 6 is formed by a central axis element 29 on which the setting wheel 9 a is rotatably mounted. At the setting wheel 9 a connects a washer 30 made of brass. Adjacent to this is a circular disk-shaped stop disk 31 rotatably mounted on the axle element 29 to limit the flexion pivoting area. The stop disc 31 has an arcuate longitudinal slot 32 into which a transverse pin 33 , which can be seen in FIG. 5 and which is fixed in the distal rail 1 , projects. One end of the longitudinal slot 32 forms the stop for the cross pin 33 to limit the pivoting range in the flexion direction, as shown in Fig. 3.

In the embodiment shown, the stop disk 31 is in turn designed as a worm wheel, the spur toothing of which engages with a worm 34 which is rotatably mounted on the proximal rail 2 by means of a worm holder 35 . By turning the screw 34 , the relative rotational position of the stop disc 31 relative to the proximal rail 2 and thus the position of the longitudinal slot stop can be changed.

The distal splint 1 adjoins the flexion stop disc 31 and is likewise pivotably mounted on the axis element 29 .

Immediately next to the distal splint 1 , the proximal splint 2 is pivotably mounted on the axis element 29 . The proximal splint 2 has an arcuate longitudinal slot 36 through which the cross pin 33 passes. This longitudinal slot 36 is dimensioned such that the cross pin 33 freely moves within the longitudinal slot 36 who can.

At the proximal splint 2 is a circular washer 37 made of brass.

A stop disk 38 is rotatably mounted on the axle element 29 adjacent to the washer 37 . At this washer 38 serves to limit the extensions swivel range and for this purpose has an arcuate longitudinal slot 39 into which the cross pin 33 protrudes. At the end of the extension swivel range, the cross pin 33 strikes, as shown in Fig. 2, at one end of the longitudinal slot 39 , so that further movement in the direction of extension is prevented.

The extension stop disk 38 is in turn designed as a worm gear with spur teeth. A worm 40 is engaged with this spur toothing. This screw 40 is fixed to the proximal splint by means of a screw holder 41 . By turning the screw 40 , the relative rotational position of the stop disc 38 relative to the proximal rail 2 can be changed.

As can be seen from FIG. 1, it is sufficient if the orthosis is provided with the spring device 7 on one side. The rails 1 a, 2 a lying on the other side of the joint can be connected to one another in a simple manner by means of a rail joint without spring preload. However, it is also readily possible to mount rails on both sides of the joint which correspond to the rails 1 , 2 .

Claims (8)

1. Orthosis for reducing stretching and / or flexion deficits of a distal limb compared to a proximal limb articulated to the distal limb, with

• - distal and proximal splints ( 1 , 1 a, 2 , 2 a), which can be attached to the distal or proximal limb,
• - a rail joint ( 5 , 5 a), which connects the distal and proximal rails ( 1 , 1 a, 2 , 2 a) so that they can pivot about a pivot axis ( 6 ),
• - A spring device ( 7 ) acting between the distal and proximal rails ( 1 , 2 ) with a spring ( 16 ) which exerts a prestressing force on the rails ( 1 , 2 ) in order to pivot them relative to one another within a specific swiveling range,

characterized in that the swivel area comprises both an extension swivel area section and an immediately adjacent flexion swivel area section, the spring device ( 7 ) with the rails ( 1 , 2 ) within the extension swivel area section in one of the rails ( 1 , 2 ) in the extension direction and within the Flexionsschwenkbereichs portion in a the rails (1, 2) in Flexionsrich tung acting manner and is operatively connected to the rails (1, 2) are continuously guided by the Extensions in the Flexionsschwenkbereichsabschnitt or flexion of the extension swiveling range section. 2. Orthosis according to claim 1, characterized in that the spring device ( 7 ) is fixed to a rail ( 1 ) and cooperates with a pulling or pushing element ( 8 ) which is at a pivot point ( 10 ) objected to the pivot axis ( 6 ) ) is articulated on the other rail ( 2 ) or a force transmission element ( 9 ) connected to the other rail ( 2 ) in a rotationally fixed manner. 3. Orthosis according to claim 2, characterized in that the pulling or pushing element ( 8 ) in such a way on the other rail ( 2 ) or the force transmission element ( 9 ) is deflected that the articulation point ( 10 ) in the flexion swiveling section with respect to one the pivot axis ( 6 ) and the spring position certain neutra len level is on a different side than in the extensions swivel range section. 4. Orthosis according to claim 1 or 3, characterized in that the force transmission element ( 9 ) consists of a locking wheel ( 9 a) which can be locked in different rotational positions on the rail ( 2 ). 5. Orthosis according to one of claims 2 to 4, characterized in that an adjustment mechanism is provided with which the relative position of the force transmission element ( 9 ) to the associated rail ( 2 ) can be changed. 6. Orthosis according to claim 5, characterized in that the force transmission element ( 9 ) consists of a worm wheel and the adjustment mechanism consists of a worm wheel in engagement with the worm ( 21 ). 7. Orthosis according to one of claims 2 to 6, characterized in that the spring device comprises a tension or compression spring held on a rail ( 1 ) and the tension or push element ( 8 ) consists of a pull or push rod. 8. Orthosis according to one of claims 2 to 7, characterized in that the spring device ( 7 ) has a spring guide element ( 12 ) urged by the spring ( 16 ) in the biasing direction and the movement of the spring guide element ( 12 ) by means of an outside Sper operable means (25) is blocked, wherein the pull or push element (8) is releasably locked in the spring guide element (12) from the spring guide element (12).