DE29619246U1 - Surgical instrument with a scissor handle - Google Patents

Description

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PATENT ATTORNEYS- EUROPEAN PATENT ATTORNEYS

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WEINMANN GmbH surgical instruments

Lupfenstrasse 3 D-78606 Seitingen-Oberflacht

Surgical instrument with a scissor handle

The invention relates to a surgical instrument with a scissor handle according to the preamble of claim 1.

A large number of surgical instruments have a scissor handle that consists of two handle branches that can be pivoted against each other to operate the instrument. Examples of such instruments are microsurgical instruments, in which one handle branch is firmly connected to an instrument shaft, while the second handle branch can be pivoted in order to axially displace a pulling or pushing element relative to the shaft and to operate engagement elements arranged at the distal end of the shaft, such as scissors, punches, grippers, forceps and the like.

It is desirable to make such instruments dismantable for cleaning and sterilization. For this purpose, it is known to make the pivoting bearing of the two handle branches detachable. For this purpose, the bearing bolt that passes through the two handle branches at the pivot point can be fixed by means of a thread in one of the handle branches, while the other handle branch is freely rotatable on the bearing bolt. Dismantling and reassembling the scissors handle is not that easy, since a screwdriver is needed to unscrew the bearing bolt and screw it back in again, whereby gripping the device

D-78048 VS-Viilingen ■ Waldstrasse 33 ■ Telephone 07721 56007 ■ Fax 07721 55164

wind occasionally causes difficulties and damage to the thread is possible.

The invention is based on the object of improving a surgical instrument of the type mentioned at the beginning so that the disassembly and reassembly of the scissors handle is simplified.

This object is achieved according to the invention by an instrument with the features of claim 1.

Advantageous embodiments of the invention are specified in the subclaims.

The basic idea of the invention is to use a bearing bolt with a spring-loaded locking device instead of a screw-in bearing bolt. To assemble the instrument, the bearing bolt only needs to be pressed into the hole that runs through the two handle branches at the pivot point. The bearing bolt then locks into place and the pivot bearing is installed. To disassemble, the bearing bolt only needs to be pulled out, overcoming the locking effect. No tools or other aids are required for disassembly or assembly. Likewise, no special dexterity or sensitivity is required to insert and remove the bearing bolt, so that these operations can be carried out without any problems in routine clinical work.

Since the swivel bearing is only subjected to stress in the plane perpendicular to the axis of the bearing bolt, the bearing bolt does not have to absorb any significant axial forces during use of the instrument. The locking force with which the bearing bolt is held in the assembled state does not therefore have to absorb any significant axial forces. The locking force must therefore only be dimensioned to be strong enough to ensure that the bearing bolt is reliably held in the handle branches. Inserting and removing the bearing bolt while overcoming this locking force therefore presents

no difficulties.

In a structurally simple and reliable design, the locking device is formed by a spring-loaded locking ball, which engages in a corresponding locking groove. This is easy to manufacture if the locking ball and the spring that loads it are inserted into the bearing bolt and the locking groove is formed in the wall of the hole. To simplify manufacture, the locking groove can be designed as a recess in the hole in one or both handle branches.

The invention is explained in more detail below using an embodiment shown in the drawing.

Figure 1 is a side view of a surgical

Instruments,

Figure 2 the instrument in disassembled condition and

Figure 3 shows a section through the instrument in the area of the pivot point of the handle branches.

In the drawing, the invention is explained using a microsurgical punch. The punch has a shaft 10 on which an actuating part 12 is mounted so that it can be moved longitudinally, for example by means of a dovetail guide. Punching jaws 14 are formed on the distal ends of the shaft 10 and the actuating part 12. A first handle branch 16 is formed in one piece on the proximal end of the shaft 10 and is angled against the axis of the shaft 10. A second handle branch 18 is pivotably mounted on the first handle branch 16 and engages the proximal end of the actuating part 12. For this purpose, a slot 20 is provided, for example, at the end of the second handle branch 18, which engages around a cross pin arranged in the actuating part 12. By pivoting the second handle branch 18 against the first handle branch 16, the actuating part 12 is thus axially positioned relative to the shaft 10

moved in order to move the punching jaws 14 against each other. Spreading springs 21 hold the handle branches 16 and 18 in the spread-apart position and thus the punching jaws 14 in the open position.

In this respect, the instrument is conventionally designed and is only given as an example of application for the invention. The invention consists in the design of the pivot bearing of the two handle branches 16 and 18 described below and can be used with any other surgical instrument with a scissor handle.

In order to connect the two handle branches 16 and 18 to one another in a pivotable and dismantable manner, the first handle branch 16 is forked in the area of the pivot point, i.e. the first handle branch 16 has a continuous slot 22 running transversely to the pivot axis. The second handle branch 18 reaches through this slot 22 of the first handle branch 16 with a flattened end section 24. The slotted area of the first handle branch 16 and the flattened end section 24 of the second handle branch 18 are penetrated at the pivot point by a bore 26 which has a constant diameter throughout. A bearing pin 28 is inserted into the bore 26. The bearing pin 28 has a cylindrical section whose axial length corresponds to the material thickness of the first handle branch 16 and whose outer diameter corresponds to the inner diameter of the bore 26. This axial section is followed by a collar 30 of larger diameter on one end of the bearing pin 28, on which an external knurl 32 is formed. If the bearing pin 28 is inserted into the bore 26 until the collar 30 rests against the outside of the first handle branch 16, the cylindrical section of the bearing pin 28 is completely received in the bore 26. The two handle branches 16 and 18 can be pivoted against each other about this bearing pin 28.

In the axial section of the bearing pin 2 8, a blind hole 34 is arranged perpendicular to its axis.

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34 is a compression spring 3 6 and a locking ball 3 8 is inserted into it. The diameter of the locking ball 3 8 corresponds to the diameter of the blind hole 34. After inserting the compression spring 3 6 and the locking ball 3 8 into the blind hole 34, its edge is caulked inwards so that the locking ball 3 8 is held captive in the blind hole 34, whereby it protrudes beyond the circumference of the bearing pin 28 under the load of the compression spring 3 6. The blind hole 34 is arranged in the bearing pin 2 8 in such an axial position that when the bearing pin 28 is inserted it falls into a plane in which the first handle branch 16 and the second handle branch 18 touch. The bore 26 is countersunk in the surfaces of the first handle branch 16 and the second handle branch 18 that touch each other in this plane, so that the countersunk recesses in the first handle branch 16 and the second handle branch 18 together form a circumferential locking groove 40 formed in the circumference of the bore 26.

To assemble the instrument, the handle branches 16 and 18 are pushed into one another until the bore 2 6 of the two handle branches 16 and 18 are axially aligned. The bearing pin 28 is then pressed into the bore 26, whereby the locking ball 3 8 is pressed into the bearing pin 28 against the force of the compression spring 3 6. When the bearing pin 28 has reached its end position, the locking ball 38 snaps into the locking groove 40 formed by the recesses in the bores 2 6. The bearing pin 2 8 is thus held locked in the bore 2 6. To disassemble the instrument, the bearing pin 28 is pulled axially out of the bore 26 using the knurls 32, whereby the locking force of the locking ball 3 8 locked in the locking groove 40 must be overcome.

It is obvious that the locking groove 40 can also be designed as a recess in the bore 26 in only one of the handle branches 16 or 18. It is also possible to design the locking groove 40 not as a recess in the bore 26 on the surface of the handle branches 16 or 18, but as a recess in the wall of the bore 26 in the handle branch 16 or the handle branch 18.

Claims (6)

WESTPHAL- jVlJLJegi3hjUCJ PATENT ATTORNEYS * EURCDPEAN*PAT*ENTfATTC)RNEYS wanOOl PROTECTION CLAIMS 1. Surgical instrument with a scissor handle, consisting of a first handle branch and a second handle branch, which are pivotably mounted relative to one another for operating the instrument, with a bearing bolt passing through the two handle branches in a bore arranged at their pivot point and being axially fixable in this bore, characterized in that the bearing bolt (28) can be fixed in at least one of the handle branches (16, 18) by means of a spring-loaded locking device (34, 36, 38, 40) arranged radially to its axis. 2. Instrument according to claim 1, characterized in that the locking device has a spring-loaded locking member (3 8) which locks into a locking groove (40). 3. Instrument according to claim 2, characterized in that the locking member (38) is arranged in the bearing bolt (28) and the locking groove (40) is formed in at least one of the handle branches (16, 18). 4. Instrument according to claim 3, characterized in that the locking member is a locking ball (38) which is arranged in a blind bore (34) of the bearing bolt (28), that the blind bore (34) runs perpendicular to the axis of the bearing bolt (28) and that a compression spring (36) is inserted into the blind bore (34) for spring loading. D-78048 VS-Vil!ingen · Waldstrasse 33 · Telephone 07721 56007 ■ Fax 07721 55164 5. Instrument according to one of the preceding claims, characterized in that the one handle branch (16) has a slot (22) running perpendicular to the pivot axis in the region of the pivot point and that the second handle branch (18) is inserted into this slot (22) with a flattened end section (24). 6. Instrument according to one of claims 3 to 5, characterized in that the locking groove (40) is formed by at least one depression of the bore (26) receiving the bearing bolt (28) in the abutting surfaces of the handle branches (16, 18).