DE8800197U1 - Surgical drilling tool - Google Patents

Description

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Description

Surgical drilling tool

The innovation concerns a surgical drilling tool with a cutting element surrounded by a tissue protection sleeve over a partial length.

It is known that bone fragments can be connected to one another using screws that can be screwed into them. To do this, holes must first be made in the bone fragments using twist drills and then threads must be made in these using thread-cutting drills to accommodate screws. The depth of the holes or threads required must be determined in a laborious manner using measuring devices. It goes without saying that the measuring processes require a great deal of time and effort, which leads to an undesirable extension of operation times.

The aim of the innovation is to enable the production of holes and threads in bone fragments in the short term with reliable depth determination.

According to the innovation, the cutting element is a drill bit _, at the end of which facing away from the cutting edge a cylindrical shaft is formed, which has a number of ring grooves or ring groove sections at a distance from each other as borehole depth markings and carries a freely movable tissue protection sleeve, the end of which on the cutting edge forms a stop. The cutting element can equally be replaced by a

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The cutting element can be formed by a twist drill or a thread cutting drill. In this way, the cutting element is prepared for a predetermined depth, whereby the respective drill hole depth can be read off the markings on the clamping shaft by means of the displacement of the tissue protection sleeve. It corresponds to the innovative idea that the cutting element can be inserted equally into aligned bone fragments as a whole or into bone fragments in which parts have prepared glide holes for the screws.

It is understood that the tissue protection sleeve is either mounted on the drilling tool in a freely movable manner, so that when the stop is applied to bone fragments or known bone plates used for reinforcement, the tissue protection sleeve moves on the clamping shafts of the twist drill or thread cutting drill, or the tissue protection sleeve has a locking device on the clamping shaft end and can be fixed to the clamping shaft by means of the locking device in order to enable the depth of the drill hole to be determined by the locked tissue protection sleeve coming into contact with the bone fragments. The locking device is preferably formed by a clamping lock, e.g. a ball lock, the locking balls of which are arranged in a recess extending transversely to the longitudinal axis of the clamping shaft in a widening of the tissue protection sleeve, are attached to the clamping shaft by spring force and can be fixed in the contact position by means of an adjusting ring that spans the widening. The locking devices arranged in the clamping shaft expediently take up

Ring grooves or ring groove sections at least partially contain the locking balls, in which the locking balls are held by the adjusting ring. The adjusting ring is preferably provided with recesses which, when placed opposite the locking balls, allow them to be lifted out, e.g. under the influence of a pushing force acting on the cutting element, while when the concentric sections located between the recesses are assigned, the locking of the tissue protection sleeve is achieved by holding the locking balls in the ring grooves or ring groove sections. In the locked state, the tissue protection sleeve automatically stops the advance of the cutting elements by resting on the bone fragments or bone plates. This provides the user with a mechanically tangible measure for determining the depth of the drill or threaded holes, which means that additional reading of markings is no longer necessary.

It is also intended that the adjusting ring on the widening can be partially rotated between the release and locking positions and that the release position and the locking position of the adjusting ring can be determined by stops arranged on it and a pin fixed to the tissue protection sleeve that is guided between the stops. The interaction of the stops and the pin provides a mechanically adjustable limitation of the partial rotations of the adjusting ring to the loosening or locking processes of the tissue protection sleeve on the cutting element.

Finally, it is planned that the tissue protection

sleeve has a collar on the end facing the cutting edges of the cutting elements as a stop. The peripheral surface of the collar can be of any shape, e.g. cylindrical, obliquely straight, convex or concave.

The invention is explained using exemplary embodiments. They show:

Fig. 1 a twist drill in side view,

Fig. 2 a twist drill according to Fig. ] with a tissue protection sleeve,

Fig. 3 a twist drill with a tissue protection sleeve of a different design, perspective,

Fig. 4 a thread cutting drill in side view

Fig. 5 is a partial section of a thread cutting drill of Fig. 4,

Fig. 6 a tissue protection sleeve of another design in section, enlarged,

Fig. 7 a part of a tissue protection sleeve of Fig. 6 and

Fig. 8 shows a tissue protection sleeve of Fig. 6 in bottom view.

In Fig. 1, 1 designates a spiral drill, at the end of which facing away from the cutting edges 2 a cylindrical clamping shaft 3 is connected. The clamping shaft 3 has a number of markings 4 at intervals as depth indications. The clamping shaft 3 accommodates, as can be seen in Fig. '*, a tissue protection sleeve 5 slidably. The end 6 of the tissue protection sleeve 5 facing the cutting edges 2 serves as a stop, which can be supported on

Bone fragments 7 or bone plates 8 (Fig. 3) during drilling processes, which leads to displacement movements of the tissue protection sleeve 5 on the clamping shaft 3. The tissue protection sleeve 5 interacts with the markings 4 at its end facing away from the cutting edges 2 and allows the respective drilling or cutting depth to be read from these. It goes without saying that the tissue protection sleeve can also have a collar 9 serving as a stop at its end facing the cutting edges 2 for better support and to reduce the surface pressure. It is also possible to see the markings 4 for determining the drilling or cutting depth via a window 10 incorporated in the tissue protection sleeve 5.

In Fig. 4, a thread cutting drill 11 with cutting teeth 26 is shown, which also has a cylindrical clamping shaft 3 at the rear end. A number of ring grooves 12 are formed in the clamping shaft 3 at an axial distance, which preferably work together with a tissue protection sleeve 5 for depth determination. The tissue protection sleeve 5 has a ball lock. The ball lock 13 makes it possible to lock the tissue protection sleeve 5 on the clamping shaft 3 of the thread cutting drill. The ball lock 13 accommodates freely movable locking balls 16 in recesses 14 of a widening 15, which are under the influence of helical springs 19 supported on pins 18 and under whose influence can be moved in the direction of the ring grooves 12. The extension 15 carries an adjusting ring 20, which can be adjusted on the extension 15 by partial rotations. The adjusting ring 20 has recesses 21, which when assigned to the locking mechanism»

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balls 16 allow the locking balls 16 to emerge from the ring grooves 12 under the influence of a component acting on the cutting element transversely to the displacement force, while when the cylindrical intermediate sections 22 are assigned to the locking balls 16, the locking balls 16 are locked in the ring grooves 12. The partial rotations of the adjusting ring 20 can be limited by a groove 23 - pin 24 arrangement (Fig. 7). The groove 23 is incorporated in the adjusting ring 20 for this purpose, while the pin 24 is firmly arranged on the fabric protection sleeve 13. The partial rotations of the adjusting ring 20 can be limited by the pin 24 running into the ends 25 of the groove 23.

To create a threaded hole, a drill hole 27 must first be made in the bone fragments 7 using the twist drill 1 (Fig. 1) (Fig. 3). The depth of the drill hole 27 can be read off according to the displacement of the tissue protection sleeve 5 on the clamping shaft 3. The tissue protection sleeve 5 can also be connected to the twist drill by locking it by means of a partial rotation of the adjusting ring 20 and the locking balls 16 fixed in an annular groove 12, and the depth of the hole is determined by the mechanical support of the tissue protection sleeve 5 (Fig. 3) on the bone fragments.

By subsequently using the thread cutting drill 11, it is possible to produce threads. The depth of the thread can be read by sliding cooperation of the tissue protection sleeve 5 m;.t markings 4 on the clamping shaft 3, or when locked

Tissue protection sleeve 5 can be determined by contacting it with bone fragments 7 or bone plates 8.

Claims (8)

G 88 OO 197.0 " " Heinz-Jürgen List, D 7990 Friedrichshafen Protection claims 1. Surgical drilling tool with a cutting element surrounded over a partial length by a tissue protection sleeve, characterized in that a drill serves as the cutting element, at the end of which facing away from the cutting edge (2) a cylindrical shaft (3) is formed, which has a number of ring grooves (12) or ring groove sections at a distance from one another as borehole depth markings and carries a tissue protection sleeve (5) that can be freely moved, the tendon-side end of which forms a stop (6). 2. Surgical drilling tool according to claim 1, characterized in that a twist drill (1) or a thread cutting drill (11) serves as the cutting element. ' 3. Surgical drilling tool according to claim 1, characterized in that the tissue protection sleeve (5) has a locking device (13) at the clamping shaft end and can be fixed on the clamping shaft (3) by means of the locking device (13). ^v 4. Surgical drilling tool according to claim 2, characterized in that the locking device (13) is formed by a Velcro lock. &ngr; 5. Surgical drilling tool according to claim 4, characterized in that a ball lock serves as the locking mechanism, the locking balls (16) of which are arranged in a direction transverse to the Longitudinal axis of the clamping shaft (3) in a widening (15) of the tissue protection sleeve (5) extending "" recess (14) and by spring force (19) to the clamping shaft (3) and that the locking balls (16) by means of a widening (15) f overarching adjusting ring (20) in the installation position &iacgr; can be fixed. ^ 6. Surgical drilling tool according to claim 5, characterized in that the annular grooves (12) or annular groove sections arranged in the clamping shaft (3) locking balls (16) partially and that the \ locking balls in the ring grooves or ring groove sections are held by means of the adjusting ring (20). ^ \ \ 7. Surgical drilling tool according to claim 5, characterized ; characterized in that the adjusting ring (20) on the widening (15) is partially rotatable between a release position and a locking position and that the release position and the locking position of the adjusting ring (20) are determined by stops (25) arranged on it and a fabric protection guided between the stops (25). ; sleeve-fixed pin (24) can be determined. J 8. Surgical drilling tool according to claim 1, characterized in that the tissue protection sleeve (5) at the end facing the cutting edges (2) of the cutting element has a collar (14) adjoining the front surface as a stop, which is circumferentially surrounded by cylindrical, obliquely straight or convex or concave curved surfaces is limited. J