BACKGROUND OF THE INVENTION
The invention pertains to a clamping element for the clamping of a rod-shaped element of an articulation, element particularly a clamping element of an articulation element for the stabilization of bone fractures. The invention also pertains to an articulation element with two clamping elements and with one at least two-piece locking device.
EP 1 184 000 describes a single-piece clamping element with two opposing cavities and one laterally open cavity to receive a clamping jaw forming a rod-shaped element and a hinge, which is arranged opposite the cavity, connecting the clamping jaws so that they are movable on top of each other, with each clamping jaw having one bore each aligned flush with one another.
This clamping element has the advantage that an articulation can be produced with two identical clamping elements arranged next to one another, inserting a connecting screw through the bore, which is screwed into an internally threaded nut to close the clamping jaws.
One disadvantage of the known device is that the rod-shaped elements can be inserted into the receiving cavities only lengthwise from their ends.
From U.S. Pat. No. 6,277,069 another clamping element is known with a lateral opening. This permits the lateral insertion of a first rod-shaped element. A second rod-shaped element can be inserted in a closed sleeve connected with the clamping lever.
From U.S. Pat. No. 6,616,664 and U.S. Pat. No. 5,752,954 an articulation is known consisting of four individual clamping jaw elements and one central screw. This articulation allows the lateral insertion of one or two rod-shaped elements into the corresponding cavities. U.S. Pat. No. 5,752,954 has a spring arranged between the two center clamping jaw elements, which spring tension allows the clipping in of the rod-shaped elements and holding the jaw elements on the rod-shaped elements before the articulation element is blocked. U.S. Pat. No. 6,616,664 provides for narrow lateral lever arms to hold laterally inserted rod-shaped elements before the articulation is blocked. U.S. Pat. No. 6,342,054 has an external spring.
Based on this state of technology, it is one role of the invention at hand to indicate a simple single-piece clamping element which allows the lateral insertion of a rod-shaped element and which, when utilized dually, is directly applicable as an articulation element.
Another goal of the invention is the creation of a cost-effective disposable clamping element, particularly made of a synthetic material (such as plastic) injection molding, which does not have the structural disadvantages of X-ray transparent clamping elements as in EP 1 184 000.
Based on the known state of technology, another role of the invention is also to provide an improved articulation element.
SUMMARY OF THE INVENTION
A one-piece clamping element is provided comprising two opposing first and second clamping jaws forming a laterally open cavity to receive a rod-shaped element. At least one hinge element is arranged opposite the cavity connecting the two opposing clamping jaws to one another and thereby making them movable towards and away from one another. Each clamping jaw has a bore, aligned with one another. The hinge is resilient and the bores are arranged between the cavity and hinge. A first clamping jaw has an anti-rotation device on its exterior or a receptacle for receiving an anti-rotation device. The hinges include a resilient hinge wall, which merges into two parallel ribs formed in the first and second clamping jaws, which ribs run past the bore and which end in the area of a free end of at least one of the clamping jaws or which merge into the body of the one clamping jaw. The hinges include two resilient lateral bars, which each merge into the first and second clamping jaws. The lateral bars include a semi-circular centerpiece, followed by a transition bar at the transition into the first clamping jaw and followed by a longer bar at the transition into the second clamping jaw. The longer bar in the area of a wall adjacent to the cavity is connected with the second clamping jaw as a rib. The lateral bars are separated laterally from the clamping jaws by a slit. The hinges have a resilient and primarily C-shaped bar on the side of the clamping element opposite the cavity, each of which merges into the first and second clamping jaws. The hinges also have complementary stops which allow a pre-determined deflection about an axis of the resilient lateral bars before the stops come into contact. The bore in the first clamping jaw is cylindrical and has three or more longitudinal alignment ribs. The bore in the second clamping jaw conically narrows in the direction of the first clamping jaw and has an enlarged diameter step to receive the head of a screw or a nut. The bore has a lateral recess to receive an anti-rotation device of the nut.
An articulation element can be formed from two clamping elements in which the clamping elements are arranged on top of one another with their first clamping jaws adjacent one another. The articulation element has one at least two-piece locking shaft with a first part of the locking shaft insertable through a bore of the second clamping jaw of one clamping element, and with a second part of the locking shaft insertable through a bore of the first clamping jaw of the other clamping element. One or the other or both parts of the locking shaft being able to be brought in contact with one another through the bores in the first clamping jaws. The first and second clamping jaws of the clamping elements can be blocked with the locking device. The articulation element has an anti-rotation device is arranged between the first clamping jaws that are arranged on top of one another, the anti-rotation device having a central bore. The anti-rotation device is preferably a plate whose material is preferably harder than the material of the clamping elements and which has ridges formed on both sides of the plate. The anti-rotation device can also be a cylinder whose material in a floor and a lid area thereof is preferably harder than the material of the clamping elements, and which preferably consists of a flexible, compressible material in the solid material part, in particular synthetic foam. The locking device includes a cylindrical screw and a conical nut, the conical nut preferably has a stop shoulder for a self-locking screw, which can be inserted in an internal thread in the cylindrical screw. A hollow spring enveloping the locking device is used as an anti-rotation device or as an additional anti-rotation device. The clamp for clamping the rods of the external fracture fixation system can be a one-piece molded polymeric first and second jaw elements each having an axial bore therethrough. The jaw elements are connected on a first side of said axial bore by an integrally molded hinge element and each jaw element having a groove spaced from the axial bore on a second side thereof for receiving the rods.
By equipping the single-piece clamping elements with functionally different first and second clamping jaws, two clamping elements can be placed on top of one another each with their first clamping jaws, to form an articulation element in a simple manner.
BRIEF DESCRIPTION OF THE FIGURES
Now the invention is more closely described with reference to the drawings and with the aid of design examples:
FIG. 1 shows a perspective view of a first design example of a clamping element according to the invention,
FIG. 2 shows a lateral view of the clamping element per FIG. 1,
FIG. 3 shows a rear view of the clamping element per FIG. 1,
FIG. 4 shows another perspective view of the clamping element per FIG. 1,
FIG. 5 shows a perspective view of a second design example of a clamping element according to the invention,
FIG. 6 shows a lateral view of the clamping element per FIG. 5,
FIG. 7 shows a top view of the clamping element per FIG. 5,
FIG. 8 shows another perspective view of the clamping element per FIG. 5,
FIG. 9 shows a top view of an anti-rotation device for an articulation element per FIG. 11 below,
FIG. 10 shows a perspective view from the bottom of the anti-rotation device per FIG. 9,
FIG. 11 shows a perspective exploded view of an articulation element per a first design example of the invention,
FIG. 12 shows a perspective illustration of the articulation element per FIG. 11 when blocked with two clamped in place rod-shaped elements,
FIG. 13 shows a lateral view of an articulation element per a second design example of the invention when blocked with two clamped rod-shaped elements,
FIG. 14 shows a top view of the articulation element per FIG. 13,
FIG. 15 shows a partially sectioned lateral view of a part of a locking screw, a nut and a self-locking bolt for an articulation element per one of the FIG. 11 to 14,
FIG. 16 shows a perspective view of a third design example of a clamping element per the invention,
FIG. 17 shows a top view of the clamping element per FIG. 16,
FIG. 18 shows a rear view of the clamping element per FIG. 16,
FIG. 19 shows another perspective view of the clamping element per FIG. 16,
FIG. 20 shows a perspective view of a fourth design example of a clamping element per the invention,
FIG. 21 shows a top view of the clamping element per FIG. 20,
FIG. 22 shows a lateral view of the clamping element per FIG. 20,
FIG. 23 shows another perspective view of the clamping element per FIG. 20,
FIG. 24 shows a perspective exploded view of an articulation element per a third design example of the invention,
FIG. 25 shows a perspective illustration of an articulation element per a fourth design example when blocked with two clamped rod-shaped elements,
FIG. 26 shows a top view of an articulation element per a fifth design example,
FIG. 27 shows a bottom view of a clamping element per a fifth design example according to the invention,
FIG. 28 shows a lateral view of the clamping element per FIG. 27,
FIG. 29 shows a top view of the clamping element per FIG. 27,
FIG. 30 shows a sectioned lateral view of the clamping element per FIG. 27,
FIG. 31 shows a perspective view of the clamping element per FIG. 27,
FIG. 32 shows a perspective view of a clamping element according to a sixth design example per the invention,
FIG. 33 shows a lateral view of the clamping element per FIG. 32,
FIG. 34 shows a perspective view of a clamping element according to a seventh design example of the invention in a variation of the element per FIG. 16,
FIG. 35 shows a lateral view of an articulation element according to a sixth design example of the invention, constructed with two clamping elements per FIG. 34,
FIG. 36 shows a perspective view of a clamping element according to an eighth design example per the invention for the utilization of another anti-rotation device for an articulation element,
FIG. 37 shows a perspective exploded view of an articulation element according to a seventh design example of the invention,
FIG. 38 shows a lateral view of a clamping element according to a ninth design example per the invention, and
FIG. 39 shows a top view of the clamping element per FIG. 38.
DETAILED DESCRIPTION
FIGS. 1 to 4 show a first embodiment of a clamping element 10 per the invention. FIG. 1 shows a perspective view at an angle from the top. The clamping element 10 has two opposing cavities and one cavity 11 to receive clamping jaws 12 and 13 forming a rod-shaped element. On their free ends 15, clamping jaws 12 and 13 each have a transversely running grooves 14, which together clamp to form the cavity 11. At the free ends 15, the outer edges 16 of the side facing clamping jaws 12 and 13 are slanted to simplify the lateral insertion of a rod-shaped element. Across from the cavity 11 and the free ends 15, a hinge 17 is arranged, connecting clamping jaws 12 and 13 in a single piece. When the clamping element 10 is intended for a rod with 4 to 6 millimeters in diameter, the opening at the free ends has a diameter of, for instance, 2 millimeters in a resting position.
When clamping element 10 is made of synthetic material, hinge 17 is a thinned material section, followed by a recess 18 running laterally and thus parallel to the cavity 11, which has a large radius of curvature on the side facing hinge 17 or, in other words, that the material cross section of hinge 17 increases only slowly. This can be seen particularly well in FIG. 2.
FIG. 2 shows a lateral view of clamping element 10 per FIG. 1. When the material cross section is measured with reference to the radial direction of the curve, it will double up to an angle of 45 degrees. Up to an angle of 90 degrees, to wit, in the direction of the outside of clamping jaws 11 and 12, the material cross section will triple or sextuple. The latter material cross section has been referenced as 19 for clarification purposes. There is a slit 27 between the two clamping jaws 11 and 12, which shows a constant width, for instance in the resting position of clamping element 10. On both ends, slit 27 merges into the widening of grooves 14, respectively into recess 18.
FIG. 3 shows a rear view of clamping element 10, i.e. of hinge 17. It is narrower than the width of the clamping jaws 11 and 12 in the area of free ends 15. The entire material cross section 19, as indicated above, exists only in the area of the cross ribs 21, which are particularly distinct in the figures in the upper area of the clamping jaw 12. There, the area between cross ribs 21 has been excluded with the exception of a round screw receptacle 23 in the top view. Screw receptacle 23, for instance, has a conical shoulder area or a step shoulder, whose purpose will be described later, which merges into a continuous bore in the top clamping jaw 12, which cannot be seen in FIG. 3.
Another perspective view of the clamping element 10 per FIG. 1 is illustrated in FIG. 4, this time at an angle from the bottom. In the lower clamping jaw 13 cross ribs 21 end in a ring flange 22, which, for instance, may have a flat recessed ring shaped step 24, where a weight and material saving recess 25 advantageous for injection molding can be connected, with a bore 26 in the center. This continuous bore 26 is aligned flush with the above-mentioned bore (reference 31 in FIG. 7) in top clamping jaw 12. At the clamping element 10, it runs vertically to the axis of the cavity 11 and parallel to the backside of hinge 17. However, it could also run at an angle. The bore 26 is cylindrical and in its interior, it has four guide ribs 32 arranged in regular intervals, illustrated in FIG. 7 and FIG. 30. Of course, three or five ribs 32, for instance, could be used as well.
FIG. 5 to 8 show a second embodiment of a clamping element 20 according to the invention. The same characteristics are identified with the same reference numerals. FIG. 5 shows a perspective view, at an angle from above. The only difference between the two clamping elements 10 and 20 per FIG. 1 and FIG. 5 is that clamping element 20 is intended to receive a rod-shaped element larger in diameter. This means that the grooves 14 are larger. The center axis of cavity 11, however, is still at the same height of slit 27. Here, the grooves 14 are so large that the free ends 15 form only a rounded area 28 to the outside, which simplifies a lateral insertion of rods. Like the fender 29 the groove 14, respectively the recess 18, is spanned to ensure the rigidity of the clamping element 20 (or 10). If the clamping element 20 is intended for a rod with a diameter of 12 millimeters, the opening at the free ends has a diameter of, for instance, 9 millimeters in a resting position.
FIG. 6 and 8 again show clamping element 20 in a lateral view, respectively in a perspective view at an angle from below.
FIG. 7 shows a view of clamping element 20 from above. Adjacent to conical shoulder 23 is a central continuous bore 31. The guide ribs 32 distinguishable here are a part of the interior wall of the bore 31. The bore 31 can be cylindrical as well; however, preferably it is conical, as illustrated in FIG. 30.
FIG. 9 shows a top view of an anti-rotation device 90 for an articulation element per FIG. 11. Anti-rotation device 90, for instance, is a thin metal plate with a central bore 91, a hub 92 and spokes 93. The outer rim 94, for instance, has successive punctured ridges 95 and recesses 96. For instance, they are arranged so that recesses 96 are always arranged opposite the six spokes 93 in this case, with each of the ridges 95 located intermittently.
FIG. 10 now shows this anti-rotation device 90 at an angle from below. It can be seen that ridges 95 are here in the area of spokes 93. This permits the utilization of a simple punching process to manufacture the plates of the anti-rotation device 90. Punctured ridges 95 and recesses 96 can be round, pyramidal or polygon shaped. They can run radially side by side in several rows, in a larger number than in FIG. 9 etc. In another alternate design, radial ribs can be used as well. If clamping elements 10, 20 have no recess 25, but only the step 24, the anti-rotation device 90 can also be a solid material plate with corresponding ridges/recesses. The importance of the function of the anti-rotation device 90 will be shown from the following description of a beneficial articulation element 100. Such an anti-rotation device 90 can also be achieved through the design of the material of the first clamping jaw 13.
FIG. 11 shows a perspective exploded view of a preferred articulation element 100 according to a first embodiment of the invention. FIG. 12 shows articulation element 100 per FIG. 11 in a blocked state with two clamped rod-shaped elements 101 and 102. The rod-shaped element 101 is a small diameter connector and the rod-shaped element 102 is a larger diameter fastening rod. Articulation element 100, on the preferred embodiment, is comprised of five parts. These are two identical clamping elements 10 or 20 or one clamping element 10 each for a smaller rod-shaped element 101 and a clamping element 20 for a larger rod-shaped element 102. These are positioned with their sides with the flange 22 facing each other. The anti-rotation device 90 is arranged between these two flanges 22.
Through the then aligned bores 31, 91 and 26 a screw 103 is inserted, which can sit on the conical screw receptacle 23 with its conical flange 104. For tightening, screw 103 for instance has a square drive head 105. It is clear that instead of a square, a hexagon or a slit etc. can be utilized. Preferably, the shoulder 104 is designed to be complementary to the receptacle 23. A nut 106 is attached from the other side. The nut 106 has a slightly conical sleeve 107 and a conical flange 108 as a covering cap. The shape of flange 108 corresponds to the shape of screw receptacle 23 of clamping element 10 or 20. The sleeve 107 is inserted in bore 31 and, to the best advantage, protrudes into bore 26 and/or through it. The sleeve 107 is fitted in the press fit; additionally, it can also have an external thread. It can be designed as a fit for one of the internal threads used in bore 26.
In another design version, not illustrated in the drawings, a clamping element is equipped with a tilting, but torsion rigid, bearing for the nut. The clamping jaw 12 again has the conically opening bore 31. This bore 31, however, has a recess on the side facing away from the cavity 11, which can be a rectangular slit in particular. During the assembly, the cylindrical nut is inserted in the recess. Otherwise, the fastening can be designed as illustrated in FIG. 15. A tolerance exists through the cylindrical nut, so that when a rod 102 is clipped into cavity 11 the top part 12 of the clamping element can be tilted as well. In order to ensure the fixation of screw 103 and to design the nut torsionally rigid, it has an appendage or projection, which protrudes into the said recess with lateral tolerance. In a lateral view of the clamping element, the projection has a tolerance in the recess to permit the tilting motion of top part 12. In addition to the nut with projection, other design versions are possible, for instance, an L-shaped flattened nut, which, for example, has wobble rivets and is punched, so that an appendage protrudes into a corresponding nut in top part 12 and produces the torsion rigidity.
The nut 106 has an internal thread that fits the complementary external thread of screw 103.
FIG. 12 then shows the assembled articulation element 100 with a clamping element 10 for a thin rod 101 and a clamping element 20 for a thicker rod 102. Through the tightening of screw 103 opposite nut 106, the two clamping elements 10 and 20 are pulled together, since the forces exerted by hinges 17 move the two lower clamping jaws 13 of the clamping elements 10 or 20 towards one another.
Then, by exerting pressure, a rod 101 or 102 can be inserted laterally in the respective cavity. Since the diameters of rod 101 or 102 are larger than the opening at the free ends 15, it is protected from falling out. Through a roughening of grooves 14, not illustrated in the drawings, it is also protected from a simple longitudinal displacement.
The two hinges 17 also exert pressure on anti-rotation device 90, so that clamping elements 10 or 20 themselves are protected from a slight rotation against each other around the axis of screw 103. The ridges 95 press themselves, i.e. according to the description of FIG. 9 and 10, in both directions vertically to the plate level into the ring-shaped step 24. This protects each of clamping jaws 13, and, with that, clamping elements 10 or 20 from a slight twisting.
If screw 103 is tightened further, clamping jaws 12 and 13 are moved closer towards one another against the resetting force of hinges 17 and are finally completely blocked in their angled position through the use of the plate of anti-rotation device 90 placed between the clamp elements. At the same time, this fully secures the rods 101 and 102 in grooves 14 against longitudinal displacement as well as against twisting by minimizing the cavity 11. While self-locking screw 109 is illustrated only in connection with FIG. 13, it can be utilized here as well. Preferably the nut 106 is designed as a continuous sleeve.
When screw 103 is opened, nut 106 remains in the one clamping element. The anti-rotation device 90 has impressed itself into the softer material of step 24. This speaks for—with the exception of an immediate tightening of the screw in this or another place an external fixator clamping element which is for a single use by a patient. The material used for the clamp may be PEEK (Poly Esther Ether Ketone), and may have chopped carbon fiber reinforcement for extra strength. This allows a one-piece polymeric clamp to be injection molded. The pressed in traces of the anti-rotation device in the step 24 is a sign of use for the clamping element, so that the user can see that the reuse of the product can be excluded.
FIG. 13 shows a lateral view of an articulation element 110 according to a second embodiment of the invention in blocked condition with two clamped thick rod-shaped elements 102. Therefore, two clamping elements 20 per FIG. 5 have been utilized in this design example.
FIG. 14 shows a top view of the articulation element per FIG. 13, where two rods 102 have been arranged twisted to one another at a 90-degree angle.
FIG. 15 shows a partially sectioned side view of a self-locking screw 103, a nut 106 and a self-locking screw 109 for an articulation element 100, 110 according to one of the FIG. 11 to 14. The cone 107 of the nut 106 can be smooth; however, it can also have a thread. Then bore 31 is preferably equipped with a thread as well. The sleeve of nut 106 has a continuous bore with a first narrower section 111, with an internal thread to receive the external thread of screw 103. A connected broad second section 112 has a shoulder 113, where the screw head of the self-locking screw 109 can sit. Self-locking screw 109 is intended to screw into an internal thread 114 in the tip of screw 103. For this purpose it can be used in particular, for instance with glue or another material, so that after a prior assembly of an articulation element 100 or 110, the self-locking screw 109 cannot be loosened from the thread 114 anymore, thereby ensuring the unity of articulation element 100 or 110.
FIG. 16 to 19 show a third design example of a clamping element 30 according to the invention in a perspective view, a top view, a rear view and another perspective view. The difference between the first two design examples and the ones now following is that hinge 17 is connected directly to the body of clamping jaws 12 respectively 13 in the first two design examples and directly passes into ribs 21. Clamping jaws 12 respectively 13 are connected to one another on the entire backside of clamping element 10 or 20.
In the clamping element 30, the two clamping jaws 12 and 13 are connected only via two lateral connecting bars 33. The connecting bars 33 each include a lower short transition bar 34 into lower clamping jaw 13 and a long bar 35, running parallel to upper clamping jaw 12, before it merges into upper clamping jaw 12 in the area of the wall 41 of cavity 11. A dividing slit 39 is located between each of the two connecting bars 33 and the upper clamping jaw 12, so that the two opposing elements 36 and 38 are separated from the upper or lower clamping jaw 12 or 13. On the upper clamping jaw 12, a semi-cylindrical portion 36 is included, opposite a complementary groove 38 at a distance corresponding to, for instance, half or one third of the height of slit 27. Semi-cylindrical portion 36 and complementary groove 38 are divided in the center by a slit 37 in two sections each separate from one another. The illustrated design examples can also be designed without slit 37, so that a semi-cylindrical portion 36 and a groove 38 are located opposite one another. Then the bearing is not divided in the center. It is not necessary that a clamping element has a receptacle for an anti-rotation device according to the third or fourth design example.
The other characteristics of lower clamping jaw 13, i.e. the receptacle 24 for anti-rotation device 90 and bore 26 with the guide ribs 32, and upper clamping jaw 12, i.e. the receptacle 23, the conical bore 31 and the ribs 21 can be designed in the same manner as in the first two and the last design embodiment. For ribs 21, one difference is that they represent a direct extension of hinge 17 for clamping elements 10 and 20. For the clamping elements 30 and 40 hinges are formed through connecting bar 33 in a resting position, which is connected only indirectly to the ribs 21 via the wall 41 of cavity 11.
FIG. 20 to 23 show a fourth design example of a clamping element 40 according to the invention in a perspective view, in a top view, in a lateral view and in another perspective view. Here, cavity 11 is designed large to receive a thick rod-shaped element 102. In the FIGS. it can be seen how the long upper bar 35 merges into wall 41 and, in almost a quarter circle, remains spatially separated from the rib 21.
FIG. 24 shows a perspective exploded view of an articulation element 120 according to a third embodiment of the invention. FIG. 25 shows a perspective illustration of an articulation element 130 according to a fourth embodiment in a locked condition with two clamped thin rod-shaped elements 101, and FIG. 26 shows a top view of an articulation element 140 according to a fifth embodiment. The structure of these articulation elements 120 and 130 corresponds to the one of the first two design examples of the articulation elements 100 and 110. If two equally strong rod-shaped elements 101 or 102 must be clamped, the same two clamping elements 30 or 40 are used, with the lower clamping jaws 13 opposite one another. Another anti-rotation device 90 is again located between these clamps. For different clamping strengths one clamping element 30 and one clamping element 40 each are used.
In the resting position of the clamping elements 30 and 40, clamping jaws 12 and 13 are held by the spring force of the two lateral bars 33 at the distance of the slit 27. When screw 103 is tightened, the slit is minimized. Through the central transfer of force via the screw and nut elements 104 and 108 on the identical areas 23, the slit 27 is minimized in its thickness until the nut 14 contacts the rod 101 or 102 in the cavity 11. Then the (upper) clamping jaw 12 with the ribs 21 deviates around the rod 101 or 102 and the semi-cylindrical region 36 touches down on the complementary area 38. When screw 103 is tightened further, the blocking effect sets in as of this time and the unit semi-cylindrical region 36—complementary area 38 takes over the hinge function of bar 33 and avoids too much stress on the same.
For instance, this can also be solved as shown in FIGS. 32 and 33, which will be described later.
FIGS. 27 to 31 show a clamping element 50 according to a fifth design example per the invention, in a bottom view, a lateral view, a top view, a sectioned lateral view and in a perspective view. This clamping element 50 is intended for use with a large diameter rod-shaped element 102. Of course, it can also be modified so that it can receive a smaller diameter rod-shaped element 102. An important difference between the clamping element 40 (or 30) and clamp 50 is that the upper long bars 35 go off directly from the body of clamping jaw 12 and with that limit the outer edge of clamping element 50. The bars 35 in particular are not shaped as ribs on wall 41 of cavity 11. The semi-cylindrical portion 36 and complementary groove 38 are not separated by a slit 37. The semi-circular passages of the long bars 35 and short transition bars 34 into the semi-cylinders 36 and complementary groove 38 are wider and extend over them by the entire radius of the passage. The short transition bar 34 here includes a passage step 42, which corresponds to almost the material thickness of the bar 33. The bar 33 is here, as in the other design examples, for instance between 1 and 5, preferably between 2 and 3 millimeters thick. The design of bores 26 and 31, which can be seen in the cross section of FIG. 30, can have the following dimensions. A cylindrical bore 26 in the lower clamping jaw 13 has a diameter of 6.5 millimeters, with the ribs 32 minimizing the diameter to 5.8 millimeters. The conical bore 31, for instance, has an angle between 5 and 10, and preferably 8 degrees, and assumes a diameter of 8.5 millimeters in depth. The angle of the conical screw receptacle 23, for instance, is between 45 and 75, preferably 60 degrees; the height for instance is 2 millimeters.
FIG. 32 shows a perspective view of a clamping element 60 according to a sixth design example per the invention, with FIG. 33 showing a lateral view of this clamping element 60. This design example also shows the arrangement of non-skid elements 99. They are pyramidal ridges at regular intervals on the surface of the groove 14. These ridges 99 can also be designed in a nub shape. It is important that they protect particularly the thicker rod-shaped elements 102 from twisting or longitudinal slipping in the clamp.
The sixth design example per FIG. 32 and 33 has the semi-cylindrical portion 36 and the groove 38. As mentioned previously, these elements can also be located across from one another. It is important that the hinge element 97 has a smaller distance 98 upon its passage into the clamp halves 12 and 22 than at 118 close to cavity 11. The distance 118 is substantially greater than the distance 98. This ensures that upon the tightening of a screw and the closing of the clamping jaws the distance 98 first reduces to zero, so that the load of the clamping from this time on is taken over by the contact point or the contact line of the complementary elements 36 and 38 and the deviating axis is moved into this contact line. With that, the spring action is converted and effectively increased.
Hinge element 97 in the sixth design example is a resilient almost closed cylinder at a distance behind the contact line. It opens particularly to the top, so that it does not protrude over the underside of clamp half 22 of clamping element 60.
FIG. 34 shows a perspective view of a clamping element 70 according to the seventh design example per the invention in a variation of the element per FIG. 16.
FIG. 35 shows a lateral view of an articulation element 150 according to a sixth design example of the articulation element of the invention, consisting of two clamping elements 70 per FIG. 34. The anti-rotation device 190 is comprised of radial prisms 191 arranged at one level, with the continuous bore 26 in the center. In another design version, the radial prisms 191 can also be arranged conically, so that with the complementary prisms 191 in a second clamping element a self-centering articulation element 150 is created. The design example illustrated in FIG. 34 and 35, however, has the advantage that the two anti-rotation devices 190 of identical clamping elements 70 can directly engage in one another.
For the articulation element 150 per FIG. 35, a spiral or coil spring 119 is arranged between the two clamping elements 70, which is supported by the spring receptacle 121. The spring receptacle 121 can form a hemispherical area as in FIG. 34; it can also be level and smooth; in particular, it can be rough to ensure a greater resistance of the spring 119 against twisting. The spring 119 pushes the two clamping elements 70 away from one another and is intended to secure the twisting of the two clamping elements 70 against one another. It does not secure the forcing apart of the jaws 12 and 13; for this purpose the resilient hinges 17, 33 and 97 are intended, which open against the forces acting upon the clipping in of the rods 101 and 102 in a radial direction with respect to grooves 14. The spring 119 can also be a disk spring package or another resilient element.
In particular, it can also be a flexible synthetic foam element 199 as per FIG. 36. Only upon the tightening of screw 103 the anti-rotation devices 190 interlock and determine the angle position of the articulation element 160 as per FIG. 37.
FIG. 36 shows a perspective view of another anti-rotation device 199 for an articulation element in interaction with an eighth design example of a clamping element 80 equipped for this purpose. This is a flexible cylindrical element 199 with a central bore 198 for receiving screw 103. It can be used in the place of an anti-rotation device 90. The advantage is that its material on the bottom and lid surfaces 197 is harder and, in particular, can also be structured or span hard inserts to engage in the ring-shaped step 24. The clamping element 80 is designed here according to the design example per FIG. 1, only the depth and the sidewalls are intended to receive the anti-rotation device 199. In the cylinder area, the element 199 is flexible to be compressed when screw 103 is tightened. In doing so, the undersides of the clamping element 80 of an articulation element 160 per FIG. 37 might touch. The anti-twisting device is beveled and has conical slants 196 between the surface 195 and the lid or the floor area 197.
It is advantageous that the material in the floor and lid area of the anti-rotation device 199 is harder than the material of the clamping elements utilized, and in the solid material preferably consists of a flexible, compressible material, particularly synthetic foam.
FIG. 37 shows a perspective exploded view of an articulation element 160 according to a seventh design example of an articulation element of the invention.
FIG. 38 shows a lateral view of a clamping element 180 according to a ninth clamp design example per the invention with a related nut 116, and FIG. 39 shows a top view of the clamping element 180 per FIG. 38. Bore 126 in the clamping jaw 13 has a greater diameter than in the other previously mentioned design examples. The bore 131 in the clamping jaw 12 is slightly conical, with the smaller diameter in the area of the outer port, which can be better seen in FIG. 39. The port ends in the nut head receptacle 122, which is preferably hemispherically concave, with the ball diameter approximately corresponding to the lower radius of curvature of the backside of the nut head 123 of the nut head 117 of nut 116. Nut 116 has a cylindrical sleeve 124, which has an internal bore and has an internal thread 125 to receive the fastening screw 103. The bore of the sleeve 124 can be continuously equipped with a smaller diameter 125 to receive the self-locking screw 109 per FIG. 15.
It is important that nut 116 with its head 117 in the receptacle 122 is movable against the clamping element 180, in a similar manner as screw 103 with its clamping element. This simplifies the clipping open of rods 101 or 102, particularly of thick rods 102. The nut head receptacle 122 in the area of the port of bore 131 is designed asymmetrically, i.e. the spherical recess has an oblong design in two opposite directions according to the reference 128 and corresponds to an oval or elliptical receptacle, so that nut head 117 cannot twist with respect to clamping element 180. Thus, with the determination of the orientation of the jaws 11 and 12 for the axes to receive the rods, it can be ensured that nut 116 does not over rotate when screw 103 is tightened. On the other hand, nut 116 permits the tipping of the clamping element 180 opposite its position, as does the opposite screw 103 for the related clamping element.
The diameter of the anti-rotation device 90 is 30 millimeters and the contact surface (radial width) for the outer rim 94 is 3 millimeters. Instead of placing the ridges on element 90, the structures (ridges) can also be integrated in the material of the clamping jaw 13, for instance radial grooves.
The ribs 21 of clamping jaws 12 are intended particularly for the purpose of introducing half the force in vertical direction, i.e. lengthwise to screw 103, as a pressure force into the spring element, i.e. hinge 17 or 33.
Instead of semi-cylindrical portion 36 and complementary groove 38, level opposing areas can be utilized as well. These opposing areas should be arranged only in the resting position of the clamping element at a distance from one another at less than the slit distance 27. Complementary deviation stops 36, 38 in this sense are also two raised ribs on clamping jaws 12 and 13, since these also form a pivoting lever. With that, the hinges of the third and fourth design example have been divided in resilient bars 33, 34 and 35 as well as pivoting lever forming stop media 36, 38. Such deviation stops can also be used in for the clamping elements of the first, second and fifth design examples.
Instead of a screw 103, another locking device can be used, for instance a clamping lever or a bayonet catch.
It is emphasized that the term design example in the previously mentioned description does not mean that only the elements described with respect to the respective clamping element or articulation element are subject of the invention. In particular, these are also combinations of the characteristics described in objects of various embodiments and FIGS. For instance, a clamping element is an object of the invention, which has the bore and nut per FIG. 38, the wide spring braces 33 per FIG. 27 to 31, a counter nut 109 per FIG. 15 and non-skid elements 99 for the rods per FIG. 32 or a part thereof. A corresponding articulation element can be comprised of any two random above-mentioned clamping elements, if they can be utilized for the selected anti-rotation device.
Although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims.