CH702066B1 - Coupling device between a motor shaft of a surgical instrument and a tool. - Google Patents

Abstract

The invention relates to a coupling device between a motor shaft (26) of a surgical instrument (28) and a tool (34). The coupling device (20) comprises a fluid supply element fed from the outside of the coupling device (20) and communicating with a channel (78) formed in the tool (34) and which opens at one point of the length of the tool (34). Such a device allows improved irrigation of the operative field, in particular during rhinoplasty. The invention also relates to a tool (34) for mounting on the motor shaft of a surgical instrument by means of the coupling device.

Description

Description: [0001] The present invention relates to a coupling device between a motor shaft of a surgical instrument and a tool. More specifically, the present invention relates to a coupling device between a motorized surgical instrument and a rhinoplasty tool.

[0002] Rhinoplasty is a branch of cosmetic surgery that aims to redraw the profile of a patient's nose. A special case is the correction by bone ablation of the more or less pronounced hump that is found in some people at the level of the bridge of the nose. To achieve this ablation, the surgeon uses motorized handpieces that print tools such as saw, rasp or plane specific movements back and forth. An example of such a handpiece is shown in FIG. 1 attached to this patent application. Designated as a whole by the general numerical reference 1, the handpiece comprises a body 2 of cylindrical general shape inside which are housed an electric motor and a shaft driven by this motor (not visible in the drawing). A coupling sleeve 4 allows removably mounting a tool 6 such as a saw blade on the motor shaft. The surgeon holds the handpiece 2 in hand by the body 2 thereof. For this purpose, it is possible to provide a fluted surface 8 which will define a non-slip gripping zone.

The success of the operation depends partly on the quality of the handpiece and the tools used. On the other hand, it depends on the irrigation of the working area in physiological saline. This serum makes it possible to maintain at an optimum level the cutting and abrasion qualities of the tools and to eliminate bone debris and blood as and when. For this purpose, the body 2 of the handpiece 1 is provided, on the side of its end bearing the tool 6, a conduit 10 for supplying fluid. In the example shown in FIG. 1, the duct 10 is mounted on a ring 12 which is slidably engaged on the nose 14 of the handpiece 1. This duct 10 is connected to a hose 16 through which the fluid arrives and serves to direct a jet of fluid towards the operative field. Nevertheless, the end 18 through which the fluid jet opens out of the conduit 10 can not be disposed beyond the coupling sleeve 4 as this would prevent easy assembly / disassembly of the tool 6. Thus, when the tool 6 is long as is the case of the saw blade shown in FIG. 1, the exit point of the physiological saline of the duct 10 is remote from the working area of the tool. Irrigation of the work area is therefore imprecise and is not always in sufficient quantity.

The present invention aims to remedy this problem by providing a tool as well as a coupling device of this tool on a motorized handpiece that allow precise and sufficient irrigation of the operating field.

For this purpose, the present invention relates to a coupling device between a motor shaft of a surgical instrument and a tail of a tool, characterized in that the coupling device comprises a fluid supply element. fed from the outside of the coupling device and which communicates with a channel formed in the tail of the tool, this channel opening at a location along the length of the tail of the tool.

[0006] In a complementary manner, the present invention also relates to a tool intended to be mounted on a motor shaft of a surgical instrument, this tool having a tail connected to an active element either directly or via a body , characterized in that a channel formed in the tail of the tool and, where appropriate, in the body of said tool opens at a location of the length of the tool.

With these features, the present invention provides a surgical tool and a device for coupling such a tool on the motor shaft of a surgical instrument that can bring a fluid such as a physiological saline closer to the working area of the tool. Indeed, rather than bringing the fluid to the working area by means of an outer conduit whose fluid discharge end can not extend beyond the coupling point between the tool and the motor shaft of the handpiece, the present invention teaches to route the fluid inside the tool and to emerge closer to the active area of said tool. In this way, it is ensured to irrigate the operating field accurately and in sufficient quantity to ensure optimal operating conditions, which is very important especially for tools of a certain length.

According to a complementary feature of the invention, the coupling device consists of a support piece which ensures the actual connection between the tail of the tool and the motorized shaft of the surgical instrument, a sleeve on which is rigidly coupled a sleeve being arranged concentrically around the support member to define a saline supply chamber. The present invention thus provides a coupling device which consists of only three parts and which is therefore both simple to perform and extremely compact, the latter aspect greatly facilitating the handling of the surgical instrument by the practitioner. In addition, all the parts that compose the coupling device according to the invention has a general symmetry of revolution, which eliminates asperities and other sharp angles that could cause injury to patients.

According to another characteristic of the invention, the coupling device allows a rigid axial locking between the tail of the tool and the motor shaft of the surgical instrument with a spring and ball system blocking. As for the locking in rotation, it is provided by a flat provided on the tail of the tool and on which bears a corresponding flat provided on the coupling device. In this way, the tool is locked both axially and radially during the working phases while being able to be mounted / disassembled very easily thanks to the spring system and ball lock. This last aspect is very important because it considerably facilitates the task of the practitioner who is required to use several tools during an intervention.

Other features and advantages of the present invention will emerge more clearly from the detailed description which follows of an embodiment of the coupling device according to the invention, this example being given for purely illustrative and not limiting purposes only. in conjunction with the accompanying drawing in which: FIG. 1, already mentioned, is a representation of a surgical instrument comprising a field irrigation system according to the prior art; fig. 2 is a longitudinal sectional view of the coupling device according to the invention in the service position; fig. 3 is a perspective view of the support piece; fig. 4 is a view similar to that of FIG. 2, the coupling device according to the invention being shown in the release position of the tail of the tool; fig. 5 from above the tool on which is visible the flat surface which allows the radial locking of the tool, and FIG. 6 is a bottom view of a second type of tool according to the invention, this tool comprising an elongate body locally deformed S which extends between the tail of the tool and its active zone and which is crossed on its entire length by a channel in which flows a fluid and which opens at the active area.

The present invention proceeds from the general inventive idea of providing a coupling device as well as a tool for a motorized surgical instrument that allows particular precise irrigation and sufficient amount of the operating area by means of a fluid such as physiological saline. For this purpose, the coupling device makes it possible both to rigidly couple the tool to the motor shaft of the surgical instrument and to place in communication a channel extending axially in the tail of the tool with a source of external fluid. In this way, the fluid emerges from the tail of the tool at the active area thereof, that is to say closer to the operative field which, masked by tissue, is otherwise difficult to access especially in the case of tools of a certain length. On the other hand, the coupling device comprises a limited number of parts, is compact and devoid of asperities, which makes the handling of the surgical instrument easier. The practitioner is less tired and his gesture is more precise.

The present invention will be described in connection with a motorized surgical instrument more particularly intended for operations in the field of rhinoplasty. It goes without saying, however, that the present invention is not limited to such interventions and that it applies identically to any type of motorized surgical instrument driving a tool whose work area needs to be irrigated to ensure the best possible performance in terms of cutting, abrasion, drilling or otherwise and disposal of waste and blood.

Designated as a whole by the general numerical reference 20, the coupling device according to the present invention is shown in longitudinal section in its working position in FIG. 2. This coupling device 20 comprises in the first place a support piece 22 which, at a rear or proximal end 24, is carried by a motor shaft 26 of a surgical instrument 28 and which, at a front or distal end 30, carries a shank 32 of a tool 34, in this case a saw. As can be seen from Fig. 2, the support member 22 is a generally cylindrical piece which is terminated at its rear end 24 by a circular flange or base 36 and in which are machined first and second bores respectively 38 and 40. The motor shaft 26 of the handpiece 28 is engaged in the first bore 38 of the support member 22. Preferably, the support member 22 is driven and pinned on the drive shaft 26. Nevertheless, according to a variant, the support piece 22 may be made of one piece with the drive shaft 26. In the case where it is mounted on the drive shaft 26, the support member 22 is pierced with two diametrically opposed holes 42a and 42b and the drive shaft 26 also has a bore 44 These two holes 42a and 42b and the bore 44 are aligned for the passage of a pin 46. The support piece 22 is thus rigidly coupled to the motor shaft 26 of the surgical instrument 28 while remaining in position. beable for maintenance and sterilization reasons. The shank 32 of the tool 34 is engaged in the second bore 40 of the support member 22. The tool 34 is axially and radially coupled with the support member 22 in a manner to be described in detail below. The support piece 22 is also pierced with a single hole 48 which forms a duct opening into the second bore 40 as well as at least one, and preferably three through holes 50a, 50b and 50c regularly spaced along the perimeter of this part support 22 and which also open into the second bore 40. Finally, the support piece 22 has at its front end 30 two protrusions 52a and 52b in a circular arc diametrically opposed whose facing surfaces 54a and 54b are planar. The role of these different elements will also be described in detail below.

Second, the coupling device 20 according to the invention comprises a sleeve 56 arranged concentrically around the support member 22. This sleeve 56 has a generally cylindrical outer shape and an internal space also cylindrical locally having a reduction of This reduction in diameter 58 thus divides the internal volume of the sleeve 56 into a first housing 60 whose diameter is adjusted to that of the base 36 and to a second housing 62 whose diameter is adjusted to the outside diameter of the housing. support piece 22. A return spring 64 is disposed inside the first housing 60, resting against a rear end against the base 36 and at a front end against the bottom 66 of said first housing 60. An angled end piece 68 stainless steel is inserted in a first conduit 70 preferably made obliquely to the general axis of longitudinal symmetry XX of the coupling device 20. A flexible hose 72 for supplying a fluid such as physiological fluid is connected to the angled endpiece 68.

The conduit 70 opens into an annular chamber 74 for supplying a fluid defined by the gap left free between the wall of the second housing 62 of the sleeve 56 and the outer surface of the support member 22. The sealing of the annular chamber 74 is provided by means of two seals 76a and 76b placed substantially at the rear end and at the front end of the second housing 62. The annular chamber 74 communicates with the conduit 48 mentioned above which opens into the second bore 40 of the support piece 22. A seal 100 must be mounted on the rear end of the tail 32 of the tool 34 to prevent the physiological fluid from escaping to the outside. Thus, the physiological fluid supplied from the outside via the flexible hose 72 and the angled nozzle 68 will successively flow into the first conduit 70, then the annular chamber 74 and the second conduit 48 before filling the bottom of the Bore 40. According to the invention, a channel 78 is machined in the shank 32 of the tool 34 and opens at a location along the length of the shank 32, preferably at the level of the active zone 80 of the tool 34. , that is to say, in the case where the tool 34 is a saw blade, at the teeth of this saw. Thus, the physiological fluid that has invaded the bottom of the bore 40 will escape by flowing through the channel 78 and emerge at the active zone 80 of the tool 34. Forcing the physiological fluid to borrow a path that leads from the outside of the coupling device 20 to the center of the tail 32 of the tool 34, it is possible to move the point where the physiological liquid emerges closest to the active part of the tool. Irrigation of the surgical field is therefore done accurately and in sufficient quantity to guarantee optimal operating conditions.

We are now interested in the locking / unlocking of the tool on the motor shaft of the surgical instrument. For this purpose, the coupling device 20 according to the invention comprises, thirdly and lastly, a bushing 82 arranged concentrically around the support member 22 and rigidly coupled to the sleeve 56 preferably by driving or other fastening technique. For the mounting of the sleeve 82 on the sleeve 56, the latter has, on the side of its front end 84, an annular flange 86 whose outer diameter is adapted to the inner diameter of the housing 88 defined by the sleeve 82. see the discussion in fig. 2, one of the three through holes 50a formed in the support piece 22 and which opens into the second bore 40 serves as a seat for a locking ball 90. The locking ball 90 is retained in the seat 50a which has for this purpose in its bottom a diameter slightly smaller than the largest diameter of the ball 90.

The locking ball 90 protrudes on either side of the support member 22 on one side in the bore 40 and on the other side in the housing 88 defined by the sleeve 82. More specifically, in operating position of the coupling device 20 as illustrated in FIG. 2, the locking ball 90 protrudes, on the side of the second bore 40 in a V-shaped groove 92 formed in the outer periphery of the shank 32 of the tool 34 and is held in this groove 92 by the sleeve 56 which is forced towards the ball 90 by the elastic return force of the spring 64. It is seen that the sleeve 56 is in abutment against the locking ball 90 via a frustoconical surface 94 that has the annular flange 86 on its inner perimeter. The locking ball 90 thus ensures the axial coupling between the tool 34 and the motor shaft 26 of the surgical instrument 28 via the support piece 22. When the rotation locking of the tool 34 on the drive shaft 26, it is provided by the support piece 22 itself whose projections 52a and 52b come, by their flat surfaces 54a and 54b opposite, resting on corresponding flat surfaces 96a and 96b formed on the tail 32 of the tool. In the working position, the tool 34 is thus rigidly coupled to the drive shaft 26.

We now examine in connection with FIG. 4 the disassembly operation of the tool 34. For this purpose, the user pulls back against the restoring force of the spring 64 on the assembly formed by the sleeve 56 and the sleeve 82 (FIG. see arrow A). Simultaneously, the user pulls forward on the tool 34 (see arrow B). Under the effect of this traction, the locking ball 90 which is no longer held in place in the groove 92 by the frustoconical surface 94, rolls on the outer perimeter of the shank 32 of the tool 34 and rises in the housing 88 defined by the sleeve 82 which is just above the ball 90. At this point, nothing stands in the way of the extraction of the shank 32 of the tool 34. As for the locking ball 90, once the tail 32 of the tool 34 extracted from the bore 40, it falls back into its seat defined by the hole 50a.

At the rear end of the coupling device 20, a seal 98 may be provided between the base 36 and the first housing 60. A seal 102 may also be provided between the bushing 82 and the support piece 22 to prevent the residues of the operation from entering the coupling device 20.

FIG. 5 is a top view of the tool 34 on which is seen in particular the flat surface 96a on which is supported by its corresponding flat surface 54a the projection 52a provided at the front end of the support part 22 for locking in rotation of the tool 34. FIG. 5 also reveals a circular groove 104 in which is housed the seal 100. It also shows the V-shaped groove 92 in which the ball 90 projects for the axial locking of the tool 34.

FIG. 6 is a bottom view of another type of tool according to the invention. Designated as a whole by the general numerical reference 106, this tool differs from that shown in FIGS. 2, 4 and 5 only in that its tail 32 which serves to mount it on the motor shaft of the surgical instrument via the support piece 22 according to the invention is connected to its active part 108, in this case a blade in accordance with the invention, a channel 110 (shown in dashed lines in Fig. 6) extends through the tool 106, this channel 110 being machined in the shank 32 and in the body 112 of the tool 106 and opening at a location along the length of said body of the tool 106, preferably in the vicinity of the active zone 108 thereof. After machining the channel 110 in the shank 32 and the body 112 of the tool 106, one can impart to the tool 106 the desired shape, for example by partially conforming S as shown in the drawing. It will thus be understood that, thanks to the present invention, the physiological fluid can be made to flow as close as possible to the active zone of the tool according to the invention, even when the latter is of substantial length.

Claims (17)

claims 1. A coupling device between a motor shaft (26) of a surgical instrument (28) and a tool (34; 106), characterized in that the coupling device (20) comprises a feed element of a fluid supplied from outside the coupling device (20) and arranged to communicate with a channel (78; 110) in the tool (34; 106) and which opens at a point along the length of the tool (34; 106). 2. coupling device according to claim 1, characterized in that it comprises a support piece (22) which, at a rear end (24), is adapted to be rigidly coupled to the drive shaft (26) of the surgical instrument (28) which, at a front end (30), is adapted to carry the tail (32) of the tool (34; 106). 3. Coupling device according to claim 2, characterized in that the support piece (22) is made in one piece with the motor shaft (26) of the surgical instrument (28). 4. Coupling device according to claim 2, characterized in that the support member (22) is adapted to be driven and pinned on the motor shaft (26) of the surgical instrument (28). Coupling device according to one of Claims 2 to 4, characterized in that, at its front end (30), the support piece (22) has a bore (40) in communication with the delivery element. fluid and in which is engaged the tail (32) of the tool (34; 106). 6. Coupling device according to one of claims 2 to 5, characterized in that the coupling device (20) further comprises a sleeve (56) arranged concentrically around the support piece (22) and which delimits with this support piece (22) an annular chamber (74) for supplying the fluid. Coupling device according to Claim 6, characterized in that the sleeve (56) comprises a first duct (70) through which the fluid arrives from outside the coupling device (20), this first duct (70) ) communicating via the fluid supply chamber (74) with a second conduit (48) formed in the support member (22) and which itself communicates with the channel (78; 110) formed in the shank (32) of the tool (34; 106). 8. Coupling device according to claim 7, characterized in that the fluid supply chamber (74) is sealed at its first and second ends by two seals (76a, 76b) and in that a seal (100) is mounted on the rear end of the shank (32) of the tool (34). 9. Coupling device according to one of claims 6 to 8, characterized in that it also comprises a sleeve (82) arranged concentrically around the support member (22) and rigidly coupled to the sleeve (56), the assembly formed by the sleeve (56) and the sleeve (82) ensuring the axial locking of the tail (32) of the tool (34; 106) on the support piece (22). 10. Coupling device according to claim 9, characterized in that the assembly formed by the sleeve (56) and the sleeve (82) is biased axially in the locking position of the tool (34; 106) on the workpiece. support (22) by a spring (64), a locking ball (90) housed in a seat (50a) formed in the support member (22) being forced by the sleeve (56) into a groove (92) formed on the around the tail (32) of the tool (34; 106). 11. Coupling device according to claim 10, characterized in that, when the assembly formed by the sleeve (56) and the sleeve (82) is brought into the release position of the tail (32) of the tool ( 34; 106) against the restoring force of the spring (64), the locking ball (90) is located at an inner housing (88) delimited by the bushing (82), the diameter of this housing ( 88) being sufficient to allow the locking ball (90) to exit the groove (92) formed around the periphery of the shank (32) of the tool (34; 106) when the shank (32) of the tool (34; 106) is removed from the support piece (22). 12. Coupling device according to one of claims 10 and 11, characterized in that the return spring (64) is supported at a first end against a base (36) provided on the support piece (22) and against an inner shoulder (58) provided in the sleeve (56) at a second end. 13. Coupling device according to one of claims 2 to 12, characterized in that, for its radial immobilization, the tail (32) of the tool (34; 106) has a flat surface (96a, 96b) on which rests on a corresponding flat surface (54a, 54b) provided at the second end of the support piece (22). A tool for mounting on the drive shaft of a surgical instrument by means of a coupling device according to one of the preceding claims, said tool (34; 106) having a shank (32) connected to a active zone (80; 108) either directly or via a body (112), characterized in that a fluid supply channel (78; 110) formed in the tail (32) of the tool (34; 106) and, if appropriate, in the body (112) of said tool (34; 106), opens out at a point along the length of the tool. 15. Tool according to claim 14, characterized in that the supply channel of a fluid (78; 110) opens at the active area (80; 108). 16. Tool according to one of claims 14 and 15, characterized in that a groove (92) formed on the periphery of the tail of the tool is provided to receive a locking ball (90). 17. An assembly comprising a coupling device according to one of claims 1 to 13 and a tool according to one of claims 14 to 16.