Collet and tool assembly

A collet and tool assembly for rotatable tools such as drills and taps in which the collet and tool each include mating: PA1 a) stops for limiting entrance of the tool into the holder; PA1 b) matching detents for producing an audible click when the tool is properly placed in the collet; and PA1 c) matching eccentric sections which provide positive torque transfer between the collet and the tool.

BACKGROUND OF THE INVENTION 
In the orthopedic implant field, the replacement of entire human skeletal 
joints is well established as every day surgical procedures calling for 
the permanent attachment of metallic joint parts to the existing bone 
structure. A usual method of attachment, particularly in the case of total 
hip joint replacement, employs metal screws of various diameters and 
lengths. The placement of such screws requires that a precisely located 
pilot hole is driven into the bone structure at the correct angle and 
depth and diameter as specified by the manufacturer of the implant part 
and subject to the operating surgeon's evaluation of the bone condition as 
observed in both pre-operation x-rays and upon opening the joint. As many 
as three screws may be inserted to hold an acetabular cup in place and of 
the correct diameter and length. This can require the surgeon to rapidly 
select the correct drill bit, hold it at the correct angle with the help 
of a drill guide and drill to the correct depth. The latter requirement is 
aided by the choice of several drill bit lengths and using the correct 
bit, drill until the drill holder bottoms out on the drill guide. 
The surgeon may be forced to make several drill bit changes in a single 
operation. Existing bits require his visual attention as well as the use 
of both hands to make a bit change, if he does so himself. Otherwise, he 
must rely upon other operating room personnel to rapidly exchange bits and 
install the bits properly, particularly to produce the correct diameter 
and depth hole. 
Some drill bits include flexible shafts as a permanent part of the bit, 
increasing their cost significantly and require the discarding of not only 
the bit but the flexible shaft when the normally unresharpened bit becomes 
dull. 
Other types of drill bits have accomplished a degree of modularity in that 
the bit is separate from the flexible drive and uses a form of collet. 
Longitudinal positioning and torque transfer to the bit is achieved via a 
cross bar which is brazed in a transverse hole in the bit shank. This type 
of bit and collet assembly is a step forward but it requires the removal 
of a part of the collet assembly with each bit change. It also allows a 
bit to be placed in the collet without being secured either longitudinally 
or in torque transfer relationship. This might only be discovered as the 
surgeon begins drilling erratically--truly an unsatisfactory situation. 
BRIEF DESCRIPTION OF THE INVENTION 
Faced with the foregoing state of the art, I was convinced that it was 
possible to produce a truly reliable modular collet and tool combination 
which meets the needs of the operating theatre for orthopedic surgery. A 
positive connection between a drive system and interchangeable and 
disposable tools such as bone drill bits and taps can be accomplished. 
Likewise, I was convinced that interchangeable tools can be devised which 
may be changed in a collet type holder with assurance merely by touch and 
audibly that the tool is properly seated and ready for immediate use. I 
knew that such a combination could be achieved in which tools may be 
exchanged in a matter of seconds without the user having to remove his 
eyes from the subject of interest, namely the patient and the operating 
field. 
These are all accomplished in a collet chuck including a body having a tool 
receiving recess defined in part by flexure expandable jaws having an 
internal detent recess and a tool seating reference surface. Additionally, 
the tool receiving recess includes a longitudinally extending eccentric 
recess as well as a positive end surface at the entrance level of the 
longitudinally extending eccentric recess. 
The collet of this invention is used in combination with tools having as 
their attachment end, a) a stop for engaging the tool seating reference 
surface of the collet, b) a detent for engaging the detent recess of the 
collet, and c) an asymmetrical extension which contacts the positive end 
surface of the tool receiving recess and only upon registration with the 
longitudinally extending eccentric recess of the collet allows the detents 
to engage with an audible sound. Thereupon the tool is locked 
longitudinally at a precise position and in positive torque transmitting 
relationship with the collet via the eccentric extension. 
A locking ring on the collet may be tightened about the jaws of the collet 
to further secure the tool in place.

DETAILED DESCRIPTION OF THE INVENTION 
This is an invention, as indicated above, which is directed toward a 
modular system of a collet and tools for use particularly in combination 
with a flexible shaft drive for medical purposes. The use of this system 
is intended principally in the placement of orthopedic implants and 
particularly in the surgical procedure of total hip replacements, for 
example, the placement of the acetabular shell component of a hip joint 
replacement. The collet of this invention and, for that matter, the tools 
employing the mating proximal and attachment feature may be used in 
surgical, dental and other applications where there is a need for the 
precise positioning, locking and driving of a drill or tap along with its 
rapid and reliable exchange of tool under stressful conditions of use. 
A typical flexible drive assembly generally designated 10 is shown in FIG. 
1. It comprises a proximal end adaptor 11, a flexible shaft portion 12, a 
distal end collet assembly 13 with its collet ring 14. The adaptor 11 may 
be of any type designed to mate with a drive source which is indicated 
generally by dash lines 15. The adaptor 11 is FIG. 1 is of the 
Zimmer-Hudson type which is well known in the orthopedic field. The 
adaptor 11 is secured to the flexible shaft 12 by any of a number of 
methods such as welding or brazing but the preferred method of crimping is 
illustrated in FIG. 1 by the crimp indentations 16. The attachment portion 
of adaptor 11 has an end recess corresponding in diameter to receive the 
flexible shaft 12 and is sufficiently thin walled that using crimping 
techniques, the adaptor 11 may be crimped about and permanently secure the 
adaptor 11 to the flexible shaft 12. One type of flexible shaft 12 is made 
up of a plurality of overlying reversely wound layers of wire such as 
stainless steel about a single axially extending stainless steel wire to 
provide a virtually solid but highly flexible length. In a typical 
example, the flexible shaft portion 12 having an outside diameter of 1/4 
inch and a 4 inch length can easily bend through a 45.degree. degree angle 
and effectively drive the collet in both a forward or reverse direction 
without backlash or danger of destruction of the flexible drive. 
At the distal end of the flexible shaft member 12, the collet assembly 13 
is similarly secured to the flexible shaft by such means as crimping as 
represented again by the crimp grooves 20. The attachment by crimping is 
accomplished at the thin walled section 21 which may be seen in FIG. 2, to 
which reference is now made in conjunction with FIGS. 3 and 4. The collet 
assembly 13 defines the recess 22 into which a flexible shaft distal end 
is inserted prior to crimping and in its body portion 23, includes 
external threads 24 for engaging and mating internal threads 41 of locking 
ring 40. Forward of the threads 24, in the distal direction is a necked 
down region 25 constituting the expandable flexure portion of a split 
collet jaw 26. In FIG. 2, two of the four jaw portions 26 may be seen. 
Four jaw sections are preferred produced by two orthogonal transverse 
diametrical slots 30 and 31. Three, four or even, for that matter, six jaw 
portions may be used. 
The jaw portion 26 includes a frusto conical surface 27 which acts both as 
a guide for entrance of a tool and as a stop limiting the longitudinal 
intrusion of the tool into the collet. 
We have found that four jaw portions 26 are effective in carrying out this 
invention. The jaw portions are defined by an internal axial bore 32 which 
defines the thickness of the flexure region 25 and its degree of 
resiliency. An additional bore 33 is eccentric with respect to the collet 
center line CL and the function of which will be made clearer in 
connection with the descriptions of the tools of FIGS. 5 and 8. 
As best seen in FIG. 3, the jaw portions 26 include a plurality of discrete 
surfaces, namely, a frusto conical throat 34, a flat 35 and a detent 
recess 36 defined for simplicity by stops 37 and 38 separated by flat 39. 
Note that the bottom surface 32b of recess 32 is planar and intersects the 
opening of recess 33. Otherwise note from FIG. 4 that the recess 33 is 
tangent to the recess 32 at line T and, therefore, forms a continuation of 
recess 32 at one line only, namely, at the bottom of FIG. 4. 
The locking ring 40 of FIG. 2 has an aperture 42 therethrough to allow the 
jaw portions 26 of the collet assembly 13 to extend through the ring 40 
and includes an internal frusto conical surface 43 which engages a mating 
external surface 26a of the jaw portion 26 of collet 11. The locking ring 
40 is dimensioned so that threads 41 when tightened on threads 24 of the 
collet engage and hold the jaw portions 26 from opening when the locking 
ring 40 is drawn tight on the collet body 23. When in the full lock 
position as illustrated in FIG. 1, the jaws 26 may not open, similar to 
conventional collet operation. 
The operation of this invention is best illustrated in connection with the 
specialized tool attachment illustrated in FIGS. 5 and 6. In FIG. 5 a 
drill generally designated 50 is shown including point 51, flutes 52, 
shank 53 and attachment portion 54. In contradistinction with conventional 
drill bits, the attachment portion 54 includes two sections which extend 
beyond the diameter of the shank portion. They are an annular stop 55 and 
a detent 56. The stop 55 is, in fact, a dual stop having a front surface 
55A which serves as a stop and bearing surface for the drill when used in 
connection with a positioning device such as a tool holder 60 shown in 
FIG. 6. The stop 55 includes a rear stop surface 56 which mates with the 
throat 34 of FIG. 2. A detent portion 58 is configured to match the detent 
recess 36 of FIG. 3. Additionally, at the proximal end of the tool 50 may 
be found an eccentric extension 57 which matches in size and shape the 
recess 33 of the collet 13. This configuration of a tool proximal or 
attachment end 54 includes each of the foregoing surfaces, each 
cooperating to accurately position the tool coaxially with the collet 13 
at a prescribed longitudinal position as defined by the mating stop 
surfaces 58, 59A and 59B on the tool with respective surfaces 37, 39 and 
38 on the collet 13. 
The tool 50 is further locked in rotational engagement with the collet 13 
by means of the eccentric extension 57 engaging the recess 33. With 
extension 57 in recess 33 there can be no slippage of tool 50 in collet 
13. The operating position when employing the collet of this invention 
with a tool of this invention can be assured with rapid interchange of 
tools and with precise longitudinal positioning and positive rotational 
engagement. 
The eccentric extension behind the detent is shown to be an axially offset 
cylinder 57. However, a D-shape extension or multi faceted section also 
are asymmetrical or noncircular and can be employed with a matching collet 
detail. 
The foregoing is accomplished by slightly loosening the ring lock 40, 
inserting the proximal or attachment end of the tool into the jaws 26 
until extension 57 strikes the surface 32B which is tactually felt, 
rotating tool 50 with respect to the collet 11 until the tool definitely 
snaps inwardly with an audible snap of the detents and the tool 50 
bottoming out in recess 32 and finally tightening the locking ring 40. The 
operation can be conducted without the use of one's eyes and one is both 
audibly and tactually assured of proper positioning and reliable drive of 
the tool. 
Although described above in connection with use of a drill bit 50, it may 
be seen that other tools such as tap 80 of FIGS. 8 and 9 which contains 
each of the operative surfaces described above in connection with FIG. 5 
and similarly numbered. 
Although the principal use of this invention is in connection with power 
driven drills or taps, it may be applied as well to hand driven 
instruments such as the T-handled flexible drive of FIG. 10 having a rigid 
shank 101 with a transverse handle 102, a flexible drive section 103 and a 
collet of this invention 104. 
The above described embodiments of the present invention are merely 
descriptive of its principles and are not to be considered limiting. The 
scope of the present invention instead shall be determined from the scope 
of the following claims including their equivalents.