The invention relates to an insert for a clamping element for clamping a rod-shaped element of an articulated connection, particularly for a clamping element of an articulated connection for stabilizing bone fractures. Furthermore, the invention relates to an articulated connection having two clamping elements and having a locking element. In particular, the invention relates to an insert for optimizing the fixation of round rods in an external fixation system.
An articulated connection is known from U.S. Pat. Nos. 5,741,252, 5,752,954, 6,080,153, 6,342,054, 6,616,664, and 6,702,814, respectively, which consists of two or four individual clamping jaw elements and a central shaft or screw. In the case of this articulated connection, it is possible to introduce one or two rod-shaped elements into the corresponding cavities from the side. In U.S. Pat. No. 5,752,954, a spring is disposed between the two center clamping jaw elements, and it is possible to clip the rod-shaped elements in, counter to its spring force, and thereby hold the articulated connection in place against the rod-shaped elements, before it is locked in position. In U.S. Pat. No. 6,616,664, narrow lever arms disposed on the side are provided, in order to hold rod-shaped elements that have been inserted from the side in place before the articulated connection is locked in position.
These known articulated connections are particularly used with frame-type systems for external treatment of bone fractures, also referred to as external fixators. By means of a suitable material pairing of the clamps of the articulated connection and of the rods, for example steels of different hardness or a combination of steel and aluminum, or also by means of suitable surface structures of the interior surface of the clamp and the mantle surface of the rod, the result can be achieved that the rod-shaped elements are sufficiently secured against rotation and axial displacement after the locking screws have been fixed in place.
It is desirable to construct such external fixators using non-metallic materials, for example plastic materials, particularly in order to achieve a weight reduction of such a system. If the modules or parts of such a clamp are made of plastic injection-molded materials, there may be the difficulty in finding suitable material pairings with which sufficient fixation can be achieved. This is a problem particularly because many plastics are characterized by negative creep behavior, which causes connections that have been tightened to gradually come loose, i.e. to lose their gripping power.
Another problem that arises with such configurations is the high pressure stress on the plastic parts when the screw connection has been tightened, and this stress can result in stress cracks due to irregular stress on the plastic structure. This is particularly dangerous because such defects only occur after a certain period of time, and are not clearly evident optically.
It is an aspect of the present invention to provide an insert for a clamping element that allows insertion of rod-shaped elements from the side, and whereby the clamping element, used double, can be inserted directly as an articulated connection, whereby the aforementioned elements of the clamping element can consist of a non-metallic material, for example plastic, without any impairment of the safety of the resulting articulated connection in an external fixator.
Furthermore, it is an aspect of the present invention to provide a simple clamping element designed for use of such inserts.
Yet another aspect of the invention is an improved articulated connection.
It is one goal of the invention to offer a suitable system that allows an optimal and, to the greatest extent possible, a direct friction lock between the connecting clamp and the rod-shaped elements, which remains constant. At the same time, the locking does not result in overly great stress on the plastic parts and therefore helps to prevent structural damage. The permanent stability of frame configurations for external fixators, which are predominantly made of plastic, is guaranteed, in other words the reliability known from previous metal designs is assured. Furthermore, this design should be a design that can be easily produced and advantageously assembled, in order to obtain a relatively inexpensive product.
These and other aspects of the present invention are accomplished by a clamping element for engaging a rod of an external fixation system. The clamping element has a first jaw member having a bore therethrough and a rod receiving cavity spaced radially from the bore. The cavity may be part cylindrical shape extending along an axis. The clamp includes a second jaw member having a bore therethrough and a rod receiving cavity spaced from the bore. A locking shaft extends through the bores of the first and second jaw members in a direction generally perpendicular to the axes of the cavities in the jaw members. The locking shaft may be threaded at one or both ends to allow for the tightening of the clamping elements against the rod. The clamping element includes an insert having a first part with a bore or recess for receiving the locking shaft and a second part extending into the rod receiving cavity of at least one of the jaw members. The second part has a tapered or pointed edge for engaging an outer circumferential surface of the rod received within the cavities of the first and second jaw members. Once the jaws are tightened by the use of the locking shaft and any associated threaded locking element coupled thereto the tapered edge bites into the outer surface of the rod fixing it axially within the cavities. In addition, the insert takes part of the load clamping the rod between the jaw members.
The insert may be either angled or L-shaped The first part of the L-shaped including a bore for receiving the locking shaft with the second L-shaped portion extending through a passageway in at least one of the jaw members and into engagement with the cavity housing the rod. The tapered edge of the insert may be in the form of a plurality of points or may have a roughened surface for better biting into and engaging the rod and preventing its motion. The tapered engagement edge can extend both axially along the rod and perpendicular thereto to better prevent axial motion of the rod within the cavity. The insert may include an anti-rotation feature to prevent the insert from rotating out of alignment with the axis of the cavity. This can be accomplished by having a portion of the insert in the region of the bore engaging the locking shaft or a portion of the insert engaging a recess in the jaw member. Preferably, the passageway runs from the outside of the jaw member through the jaw member in a direction that is perpendicular to the axis of the cavity and through a surface that delimits the cavity so that the first part of the insert clamp can lie against the clamp outer surface with the second part extending generally at 90° thereto extending into the cavity which receives the rod. In a preferred embodiment of the outer side of the jaw with the insert has a recess extending along the face of the jaw member and recessed in the direction of the passageway to receive the first part of the jaw. The recess is sized to receive the first part of the insert as a press-fit so that the insert is retained on the outer side of the jaw member and is prevented from rotation with respect thereto. Also in the preferred embodiment the bore in the first part for receiving the locking shaft may be oblong so that the jaw member with the insert press-fit therein can be moved apart when a rod-shaped element is inserted in a direction perpendicular to the axis of the cavity. In a second embodiment the jaw member may have a beveled surface for engaging a beveled surface on the insert to provide support for the insert when engaging the rod.
In particular, an insert according to the invention allows a direct transfer of force from the screw or another locking element to the rod, in order to relieve stress on the plastic component.
In other embodiments, it is also possible to achieve the inserts as extrusion-coated parts. In this case, metallic parts are laid into the injection-molding mold and then coated with plastic by extrusion coating. This is a common technique, but it requires a complicated and accordingly expensive production process (robot-controlled placement of the metal parts or manual placement). A disadvantage of such a solution is that extrusion-coated parts are also subject to the creep phenomena mentioned.
The invention will now be explained in greater detail, making reference to the drawings, using exemplary embodiments. These show:
Referring to
Each clamping element 10 has two clamping jaws 12 and 13 that lie opposite one another and have a cavity 11 for accommodating a rod-shaped element 101. Rod 101 may be formed of a polymeric or composite material such as carbon fiber reinforced PEEK. The clamping jaws 12 and 13 have a groove with a longer curvature portion 14 and having a short curvature portion 14a that runs crosswise, in each instance, at their free ends 15, which grooves together define the cavity 11. At the free ends 15, the outer edges 16 of the sides of the clamping jaws 12 and 13 that face one another are rounded, in order to facilitate the insertion of a rod-shaped element from the side. Opposite the cavity 11 and the free ends 15, a hinge means 17 is provided, which can be seen in
Clamping elements 10 have a solid cross-section in their center region, forming two lateral cross-ribs 21, which are particularly marked in the upper region of clamping jaw 12. The region between cross-ribs 21 is recessed towards the front edge 16, with the exception of a rectangular insert accommodation or recess 18 that can be seen in the top view of
In the inner or lower clamping jaw 13, cross-ribs 21 end in a ring flange 22, which can have a flat, recessed, ring-shaped segment, for example, which can be followed by a recess that saves weight and material and is advantageous for injection-molding production, in the center of which a bore is provided. This continuous bore is oriented to align with the aforementioned continuous bore in the upper clamping jaw 12. In the clamping element 10, it runs perpendicular to the axis of the cavity 11 and parallel to the back of the hinge means 17. However, it could also run at a slant. The ring flange 22 can be a carrier of engagement elements such as radial teeth, in order to prevent rotation of the clamping elements 10 relative to one another. A separate rotation element for insertion between the two clamping elements 10 can also be provided.
In the representation of
In the preferred embodiment an insert 50 is inserted into insert accommodation or recess 18; the former consists of an L-shaped profile that will be described in greater detail in
The lower clamping jaw 13 has a flat contact surface on its underside, on which the inner side 86 of the insert 80 rests (in contrast to the riffled or serrated flange 22 shown in
Furthermore, the clamping element 20 has a slit bore 29 that corresponds to slit bore 19, and opens into groove 14 of clamping jaw 13, analogously. The insert 80 is structured in U shape, and, similar to insert 50, has a plate surface 81 that is configured here to be round, and is flattened on the side of the engagement side 83. In the embodiment shown, two teeth 84 having engagement edges 85 which may be tapered to a pointed edge, are provided. It is clear that other configurations corresponding to the above second and third exemplary embodiments can also be implemented.
On the side lying opposite the engagement side 83, a locking bar 88 is provided, which runs essentially parallel to the engagement side 83. The locking bar 88 runs in a slit of clamping elements 20 that runs parallel to the bore that accommodates the screw, and has a locking projection 89 that can press into the material of clamping element 20 in the depth of the slit.
In this embodiment variant, two inserts 80 come to rest on one another directly, between the two parts of the clamping elements 20, which are made of plastic, for example, and additionally take on the function of a rotation lock 87 of clamping elements 20. In this case, the plastic parts do not have any teeth on the underside. Preferably, the insert is produced as a die-punched part. The radial teeth of rotation lock 87 engage into one another when the screw 103 is tightened, and, in order to improve the rotation lock, the insert additionally has a locking bar 88 that engages into clamping jaw 13 of plastic part 20.
In addition, this insert 80 can be configured with hooks 89 and engagement side 83, as a clip or snap, and this simplifies assembly, since the parts can thereby be clicked onto the clamping element 20. In this variant, as well, the teeth that engage in the rods 101 can be configured in the most various forms, of which the exemplary embodiments shown only form an advantageous selection. For example, round conical points can also be provided, instead of teeth 54, 64, 74, 76, 84, or in addition to them. These are engagement elements, in each instance. Any such means that can be referred to as a means for generating high friction forces can be viewed as being an engagement element. This can simply have a rough surface, one or very many carpet-like little points can be present, or the engagement element can assume other embodiment forms mentioned in the specification and in the claims.
It is clear that insert 50 according to the first embodiment can also be equipped with a locking bar 88, if a corresponding recess is provided in clamping jaw 12.
It is directly evident that two inserts 80 and 90, respectively, provided for the inner clamping jaws 13, have a round bore 82, while the inserts 50, 60, and 70, respectively, provided for the outer clamping jaws 12, have rectangular bores or oblong bores. This is due to the fact that in order to insert the rods 101, the clamping jaws 12 and 13 must be pressed apart. In doing so, clamping jaws 12 move about a pivot point of hinge part 17 and thereby relative to screw 103 or nut 106, thereby making it necessary for a corresponding clear space to be present for the path of the screw 103 or nut 106. Instead of the closed bore, a U-shaped slit can also be provided, which at least partially surrounds a clamping element 103, 106.
Insert 190 is configured to be rectangular with rounded corners, and, similar to insert 50, has a plate surface 51 that makes a transition into the engagement side 93 on one side, at a slant. This can be achieved by means of punching, for example. The angle between the surface 51 and the engagement side 93 can be 45 degrees, for example, but other values, advantageously between 30 and 60 degrees, are also possible. An oblong hole 92 is disposed in the surface 51; its longitudinal direction is oriented perpendicular to the punch line of the engagement side 93. The smaller diameter of the oblong hole 92 essentially corresponds to the diameter of the screw 103 provided for the clamping element 30 according to
In the exemplary embodiment shown, two lateral teeth 94 are provided with engagement edges 95. This can also be described as an engagement edge 95 that is set back in the center region. It is clear that other engagement configurations, in accordance with the above first through fifth exemplary embodiments, can also be implemented.
On the side lying opposite the engagement side 93, no locking bar is provided here, which would run perpendicular to the surface 51. Such a locking element, similar to the locking bar 88, is, of course, possible, in order to support the locking effect.
In this embodiment variant, the two inserts 190 come to rest directly between the two clamping jaws 12 and 13 of each clamping element 30. For this purpose, the clamping jaw 12 has a bevel 38 that can rest against the engagement side 93. In this context, the screw 103 passes through the opening 92, which is configured as an oblong hole, in order to allow a movement of insert 190 crosswise to the orientation of rod 101.
In the lower part of
In the case of this variant, as well, the teeth that engage in the rods can be configured in the most various shapes, of which the exemplary embodiments shown form only an advantageous selection. For example, round conical points can also be provided, instead of the teeth 54, 64, 74, 76, 84, in each instance, or in addition to them. They are engagement elements, in each instance.
In the case of all the exemplary embodiments shown, the insert forms an angled support that directly engages on a rod, with a friction lock. Therefore the clamping elements 10, 20, or 30 are now used only as a guide and spacer part; they are therefore subject to less stress. This permits an even greater material selection for the clamping elements 10, 20, 30. In this context, the insert 50, 60, 70, 80, 90 or 190 engages in the locking element, here 103, 106, on the other side.
The inserts 50, 60, and 70 are shown fitted into a recess 18. This recess 18 can be configured, in particular, in such a manner that inserts 50, 60, and 70 have no play in it, but rather fit into a press fit. They can then not fall out, and form a single-piece unit for the user. The same can also be achieved for the insert 80, by means of a corresponding deformation of the lower clamping jaw 13. As a result, a similar effect as that of the locking bar can also be achieved with reference to the rotation lock, particularly if the insert 90 is configured to be angular rather than round, whereby the characteristics that prevent rotation, for example radial grooves, are provided on the side lying opposite the flat side 86.
Finally, the inserts can also be provided as injection-coated parts in a clamping element.
The exemplary embodiments shown in the drawings, and the characteristics of various exemplary embodiments mentioned in the present description, respectively, should not necessarily be understood as embodiments independent of one another. Instead, it is possible that each characteristic described in one of the exemplary embodiments can be combined with one or more of any other characteristics of other exemplary embodiments, so that other exemplary embodiments result, which are not literally described or shown in the drawings, but lie within the scope of protection claimed in the present claims.
Number | Date | Country | Kind |
---|---|---|---|
05100926 | Feb 2005 | EP | regional |
Number | Name | Date | Kind |
---|---|---|---|
1785870 | Marles | Dec 1930 | A |
2856214 | Schrimshaw | Oct 1958 | A |
3023989 | White | Mar 1962 | A |
3466712 | Behney | Sep 1969 | A |
4043688 | Humlong | Aug 1977 | A |
4310209 | Fleming et al. | Jan 1982 | A |
4707051 | Hall | Nov 1987 | A |
4772153 | Huang | Sep 1988 | A |
5030220 | Howland | Jul 1991 | A |
5358350 | Oertle | Oct 1994 | A |
5727899 | Dobrovolny | Mar 1998 | A |
5741252 | Mazzio et al. | Apr 1998 | A |
5752954 | Mata et al. | May 1998 | A |
5888221 | Gelbard | Mar 1999 | A |
6080153 | Mata et al. | Jun 2000 | A |
6340361 | Kraus et al. | Jan 2002 | B1 |
6342054 | Mata | Jan 2002 | B1 |
6616664 | Walulik et al. | Sep 2003 | B2 |
6692177 | Crudele et al. | Feb 2004 | B2 |
6702814 | Walulik et al. | Mar 2004 | B2 |
20040044344 | Winquist et al. | Mar 2004 | A1 |
Number | Date | Country |
---|---|---|
38 23 746 | Jan 1990 | DE |
1522267 | Apr 2005 | EP |
1661523 | May 2006 | EP |
964114 | Aug 1950 | FR |
2029490 | Mar 1980 | GB |
Number | Date | Country | |
---|---|---|---|
20060177263 A1 | Aug 2006 | US |