DE817186C - Joint bracing for prostheses - Google Patents

Description

Joint bandages for prostheses Addition to patent 811 714 The 811 patent 714 relates to joint bandages for the parts of artificial limbs that move together. These joint bandages consist of suitably shaped bodies made of flexible, elastic deformable building materials such as rubber or similar synthetic bodies o. solid solutions that are adhesively bonded to the rigid parts of the artificial limbs. The shape of the joints and the degree of their hardness is chosen so that Large angular positions in certain directions of movement and small angular positions in other directions of movement given the mutual mobility of the connected individual parts of the artificial limbs are and that the return spring forces that occur are within the desired range There are limits.

The invention relates to a further structural embodiment of the Joint bandages according to the patent 8i 1 714. The inventive shaping of the elastic body, prosthetic joints can be produced, which in their mode of action come as close as possible to the natural human joints; of this becomes fundamentally determines the usefulness of the entire prosthesis.

The invention consists in that the molded body is made of elastic material the joints are adhesively connected to the rigid components in such a way that by preferably Circular-arc-shaped constrictions of the exposed outer surfaces of the molded bodies such a reduced central cross-section is created that all of them are on the shaped body forces acting as deformation flowing from this weakest cross-section distribute over the whole body and especially lace tensions on the adhesive surfaces and especially in their edge zones avoided even in the event of overload will. Much like the natural joints of the human limbs, diverse are formed, the artificial joint bandages according to the invention receive a different design.

Three joints are used for lower limb prostheses, namely the metatarsal (Toe), ankle and knee joints.

The drawing serves to further explain the invention. In the Fig. I to IO are for example and schematically different embodiments of the invention shown.

Abbot). 1 is the vertical longitudinal cross-section through the front part of an artificial foot.

Al) h. 2 is a section along line A-B in Fig. I.

Fig. 3 shows the device according to Fig. I in a loaded position.

Between two flat metal plates I and 2, which can be in any and known way with the artificial foot parts made of wood or other building materials, namely the toe part 4 and the metatarsal part 5, connected, e.g. B. expedient are embedded therein, the articulated rubber body 3 is adhesive in a known way, z. B. by vulcanizing attached. This joint is required to be I. makes the toe part 4 movable upwards, so that it unrolls when walking the tread of the foot takes place; 2. that a restoring force is effective, the one when rolling the increasing load by moving forward shifting body weight of the prosthesis wearer counteracts to such an extent that an unnaturally wide bending of the foot (toe part) upwards is avoided, while at the same time the restoring force must be sufficient to keep the artificial foot against the Return the effect of the shoe worn over it to the rest position; 3. When walking on uneven terrain, the toe part 4 is not only about its to the running surface parallel axis can be rotated, but the tread of the toe part itself Rotate into a certain angular position transversely to the running surface of the foot part 5 at the same time leaves. Because the metatarsal joint has this on all sides, but by restoring forces allows appropriately limited mobility between the metatarsus and forefoot, it fulfills the organic conditions of walking.

This is achieved according to the invention in that, as in the patent 811 714, length, width and thickness of the rubber body of approximately rectangular cross-section as well as the hardness of the rubber compound (i.e. its spring effect) selected accordingly be that further the shape of this rubber ikörpers the occurrence of peak voltages on the adhesive surfaces and edges thereby avoids that approximately circular arc-shaped Constrictions narrow the central cross-section of the rubber body to such an extent that in the Mean cross-section the most shape-changing forces in the articulated movement come into effect and therefore with increasing stress from this evenly distribute in the body and with the lowest specific loads up to affect the adhesive surfaces and their edge zones.

It can be used on the train only, parallel to the tread of the foot lying side 6 of the rubber body a wave-shaped design of the surface are advantageously used in which the outwardly directed thickening 7 is deformed in the manner shown in Fig. 3, so that here in the maximum Angle the surface of the rubber body below a flat circular arc shape approaches, while at the top it assumes the compression shape that the unloaded rubber body pointed down.

This design of the external shape of the joint body is crucial Significance for its functional properties such as its durability in continuous operation, because this also enables unavoidable overloads to be withstood without breaking and remain without any after-effects on the joint action.

An embodiment of the ankle joint according to the invention is shown, for example Figs. 4, 5, 6, 7 and 8. Figs. 4 and 5 show a joint in which between two circular metal plates 8 and 9, one also circular in horizontal cross-section Rubber body 10 is adhesively attached, which has a circular arc-shaped constriction 1 1 shows in its vertical cross-section.

An ankle joint of this type results in flexibility in all directions between the lower leg part 12 and foot part I3 of the prosthesis with restoring forces, which in turn depend on the thickness, diameter and degree of hardness of the rubber body and can be freely selected depending on the design.

The foot part I3 can thus extend to the lower leg part on all sides Set I2, depending on the load and condition of the running surface, by restoring forces limited angular deflections and determined by the effective loading forces; it automatically returns to its resting position after discharge.

In many cases there is now a different degree of mobility between lower leg and foot part required, such. B. slight bending of the foot part backwards when stepping on the ball of the heel (heel of the shoe), at the same time Limited mobility forwards due to the right-angled position of the lower leg to the foot part, while at the same time the lateral mobility in the longitudinal axis of the foot part should be limited by stronger restoring forces, such that the foot part also meets the conditions of walking in this lateral mobility uneven terrain sufficient, but not too largely adapts.

In place of the in Ahh. 4 and 5 shown rubber body of circular horizontal cross-section then occurs according to a further embodiment of the invention an oval (Fig. 6) or oblong rectangular (. \ kl). 7) with al) gerttll (leten Corners and horizontal cross-sections similar to those in Fig. 4 or 8 are analog. With these forms, all of the previously described effects and Achieve conditions.

Also through asymmetrical training, e.g. B. according to Al> 1 ,. 8, lets the degree of mobility and the size and characteristics of the return spring forces vary widely and train according to the requirements, whereby also in place of flat l adhesive surfaces spatially deformed, such as B. spherical etc., can be chosen.

In a similar way, the knee joint for prostheses can also be used according to the invention form.

The design of such knee joints can, however, according to the invention go even further can be varied. In addition to the ones described above, the following design is also advantageous: After the embodiment shown in Fig. G and 10 comes a rubber torsion spring for use, which consists of the tube 14 and the inner cylinder 15. These two Parts are coaxially adhesively connected to one another by means of rubber I6 0. The outer tube 14 is through z. T3. a support arm I7 with the lower leg I9, the inner cylinder 15 attached to the thigh 20 of the prosthesis by means of two lateral support arms 18 or the other way around. By dimensioning the overall length of this torsion spring joint accordingly as well as the diameter of the outer and inner cylinder and the thickness and hardness of these The various functional possibilities can be found in the rubber body achieve this knee joint in prostheses. One of the latest findings in orthopedics A largely corresponding training is achieved in that a) the joint is mounted between the thigh and lower leg in such a way that the leg is in the rest position the knee pushed back through the front instead of the kneecap Stops 21 and 22 is held rigid and thereby acts as a stand; H) this pushing through to the rear takes place automatically by means of the appropriate setting of the joint, the torsional spring forces acting in it affect the upper and lower leg turn to the front knee stop; c) by pressing forward the thigh stump against the restoring torque described in b), the rigid (standing) position is canceled and posterior buckling of the knee joint under the influence of body weight takes place, wherein d) the torsion spring force is kept so great that he is an angular position from about 450 (bent position of the knee) between the upper and lower leg the entire Body weight of the prosthesis wearer is resiliently supported.

The middle part can be made using simple, well-known constructive dimensions 15 of the torsion spring joint can be adjusted with its support arms I8, undcn, such as B. by external and internal teeth between part 15 and the bearings in part I8, so that the function of the respective wishes of the prosthesis wearer and in particular is regular according to his body weight.

A leg prosthesis equipped by means of the rubber joints according to the invention has the following properties and advantages: 1. So far unattainable simple, light, Durable and maintenance-free design, especially when it comes to the execution of the metal parts in light metal, the technological peculiarities of which are characterized by the rubber adhesive bandages preserve and use in an excellent way. The z. B. only possible to a limited extent All light metals can be welded and soldered as a connecting means through the Adhesive bond with rubber can be significantly improved. Furthermore, any lubrication falls away.

2. All that are necessary in the joints of the usual type of prosthesis Springs, stops, buffers, etc. are unnecessary because the restoring forces of the invention Joints perform all of these secondary functions. This simplification is of of fundamental importance for the mode of operation, durability and in particular for the crucial moment of weight saving.

3. The ideal elastic assembly of the rigid parts of the prosthesis the joint bandages according to the invention make the function of the prosthesis soft and complete noiseless, so it has a gentle effect on all parts and especially on the Amputation stump. The ugly roar when walking is excluded; self hard occurrence is transferred and absorbed softly, so that in particular Overloads caused by jumps, stumbling and falling, break-free and without permanent Deformations of the rigid parts are absorbed, as a result of the high elastic Deformability and work of the bandages made of rubber or the like.

4. Functionally is one equipped with joints according to the invention Prosthesis far more closely resembles the mode of action of the natural joints in the human leg than any previously executed and no matter how complicated known design with mechanical or even hydraulic joints. The dynamics and kinematics of the corridor with the natural According to the invention, the human leg can largely be imitated in a prosthesis, whereby the walking safety of the prosthesis wearer increases as well as his effort and thus his fatigue will be reduced.

These apparent functional advantages are also added a substantial reduction in generation costs.

Claims (5)

PATENT APPEAL: I. Joint bandages for prostheses according to patent 811 714, in which adhesives are produced directly or indirectly according to known processes Moldings made of rubber o. The like. Are used, characterized in that the Shaped bodies are adhesively connected to the rigid components in such a way that by preferably Circular-arc-shaped constrictions of the exposed outer surfaces of the molded bodies such a reduced central cross-section arises that all - forces acting on the molded body as deformation of this weakest Distribute cross-section fluently over the whole body and especially peak tensions on the adhesive surfaces and especially in their edge zones, even in the event of overload, avoided will. 2. Joint bandages according to claim I, characterized in that the Cross-section of the moldings oval or elongated rectangular, expediently with rounded ones Corners is formed so that the occurring at angular positions in these joints Restoring forces are small in one direction and large in the other, depending on requirements come and limit the flexibility accordingly. 3. Joint bandages according to claim I and 2, characterized in that that the moldings are designed asymmetrically, such that their adhesive surfaces in Rubelage are at an angle to each other or with spherical, convex or concave or otherwise spatially shaped rigid components are adhesively connected, the spherical or other types of spatially designed adhesive surfaces as well can be designed asymmetrically or with mutually offset central axes. 4. embodiment of the joint bandages according to claim I to 3, characterized characterized in that the molded body is designed as a rubber torsion spring in which in a cylindrical outer sleeve a cylindrical inner part adhesively in rubber or the like. Like. Is stored and these outer and inner parts by means of holding parts with the prosthetic limbs are rigidly connected. 5. embodiment of the joint bandages according to claim 4, characterized in that that this in one of the holding and connecting parts or in both with the prosthetic limbs is adjustably mounted so that the restoring forces can be adjusted as required.