US3731385A

US3731385A - Drilling apparatus

Info

Publication number: US3731385A
Application number: US00134295A
Authority: US
Inventors: J Farber; T Roseman
Original assignee: ELECTRO DENT Inc
Current assignee: ELECTRO DENT Inc
Priority date: 1971-04-15
Filing date: 1971-04-15
Publication date: 1973-05-08
Anticipated expiration: 1990-05-08
Also published as: CA944981A

Abstract

A medical device is disclosed, which employs a form of electric desensitization in connection with the use of pain-producing medical tools. The device is particularly useful in connection with dental drilling operations and includes, in the preferred embodiment, a coil mounted within a dental handpiece and a rotating permanent magnet mounted so that its magnetic flux overlaps the coil windings. Rotation of the magnet includes an electric current in the coil which flows through the drill and into the tooth to desensitize the nervous system of the tooth upon contact. An improved turbine bearing assembly is included, having an elongated substantially tubular hub interconnectable with an elongate collet to form a rotary chuck, preferably adapted to be used in a dental drilling handpiece. The invention also includes apparatus for manipulating this rotatable chuck.

Description

United States Patent 1 Farber et al.

[ 1 May 8, 1973 [54! DRILLING APPARATUS [52] US. Cl ..32/27, 279/52 [51] Int. Cl ..A6lc 1/10 [58] Field of Search ..32/26, 27; 279/51,

l 56] References Cited UNITED STATES PATENTS Primary Examiner-Robert Peshock Attorney-Darby & Darby [57] ABSTRACT A medical device is disclosed, which employs a form of electric desensitization in connection with the use of pain-producing medical tools. The device is particu' larly useful in connection with dental drilling operations and includes, in the preferred embodiment, a coil mounted within a dental handpiece and a rotating permanent magnet mounted so that its magnetic flux overlaps the coil windings. Rotation of the magnet includes an electric current in the coil which flows through the drill and into the tooth to desensitize the nervous system of the tooth upon contact. An improved turbine bearing assembly is included, having an elongated substantially tubular hub interconnectable with an elongate collet to form a rotary chuck, preferably adapted to be used in a dental drilling handpiece. The invention also includes apparatus for manipulating this rotatable chuck.

3 Claims, 8 Drawing Figures 2,263,808 ll/l94l Hutchinson ..32/27 3,545,084 12/1970 Hoffmeister.... .....32/26 3,499,223 3/1970 Liebetal. ..37/27 PATENTED 8% 3,731,385

SHEET 1 0F 2 m 3 mm INVENTORS JEROME FARBER BY THEODORE ROSEMAN ATTORNEYS DRILLING APPARATUS BACKGROUND OF THE INVENTION The invention relates to pain producing dental and medical tools, and more particularly to apparatus and accessories for relieving pain from the use of such tools by a form of electric desensitization which is administered throughthe tool directly at its point of contact with the patient.

Heretofore, electrical analgesia in dental drilling operations, particularly as disclosed in US. Pat. No. 3,083,463 to B. Brooks et al., has been achieved by placing an external unidirectional magnetic field across the affected area of the tooth. The drilling operation is then performed so that the bur rotates in the field. Current is thereby generated in the bur, and this current works directly on the nervous system of the affected tooth. Somewhat results have been obtained by utiliz ing a special bur embedded with an insulated coil of fine wire. One of the leads of the coil is connected to the bur tip, and the other to the bur shank. The additional conductor embedded in the bur shank can generate higher currents in lower strength fields for more effective analgesic action on the dentinal nerves.

Certain attendant disadvantages, however, have rendered the prior devices impracticable, and significantly reduce their effectiveness. One such disadvantage is the observed variation in the level of desensitizing current, depending upon the orientation of the drilling bur with respect to the magnetic flux crossing the affected area of the patient. Dependable current levels have been difficult to maintain owing to the natural field distribution of the magnetic flux density.

Earlier devices have been found to be impractical because of the large size of the permanent magnet and the large size of the coil wound on the drilling bur. In addition, the operation of such devices depended upon the use of special drilling burs embedded with the appropriate turns of wire. This necessitated replacement or doubling of an operators entire stock of plain drilling burs. Furthermore, lack of concentricity between the drilling bur and the coil embedded therein tended to effect uneven rotation of the bur. Such irregularity becomes especially apparent at relatively high turbine drive rotational speeds and resulted in undue vibration and other operational difficulties which significantly shortened the life of such prior apparatus. It has also been necessary to take special precaution to obviate side effects of the powerful magnetic field, for example eyeglasses with metal frames and patients Wristwatches had to be removed. Occasionally, serious psychological aversion to the unusual equipment set up around the patients head has been observed.

Another disadvantage of prior dental drilling apparatus is that upon deactivation of the drive means, usually a high speed turbine, the drilling bur continues to rotate under its momentum. It is necessary therefore, that the operator exercise extreme caution in removing the still rotating bur from the tooth to avoid inadvertent contact with otherwise healthy portions of the tooth or the mouth of the patient.

Servicing of prior drilling apparatus has heretofore been costly and time consuming. Transmittal of the defective device to the manufacturer for repair is often required which results in a substantial loss in operating time and other expenses.

Accordingly, the present invention provides a selfcontained and compact unit which requires none of the complicated preparation and maintenance of the prior apparatus. The invention discloses preferably at least one coil mounted within a handpiece, one lead being electrically connected to the handpiece casing, or circuit common, and the other being electrically connected to a pain-producing tool such as a dental drilling bur. It will be understood however that other forms of conductors, such as a wire grid or the like, may be used in place of the coil, as desired, without departing from the scope of the invention. A magnet, preferably a permanent magnet, is also mounted within the handpiece in the vicinity of the coil. The usual fluid-operated turbine-bearing assembly may be provided, preferably for rotating the magnet relative to the coil, although the coil may be rotated without departing from the scope of the invention. Rotation of the permanent magnet causes its magnetic flux lines to move across the coil thereby inducing a predetermined electric potential at the tool. Upon contact between the tool and the patients body, current flows through the patient to the common, thereby desensitizing the contacted area.

For dental drilling operations, the invention provides a plurality of component units, or modules, which may be easily removed from the apparatus for replacing or other servicing. One such unit contains the electrical system for connecting the preferably fixed conductor, or coil for example, to the rotating drilling bur. Another unit may contain the turbine bearings, collet and magnet. Worn bearings or electrical contacts may therefore be easily serviced on location by simply replacing the deficient unit with a new one.

A further advantage of the present dental handpiece is that it does not require the use of special drilling burs. Accordingly, there is no necessity for costly replacement or doubling of an entire supply of such burs, as was required by the prior apparatus. The present device may be easily assimilated into otherwise standard dental systems.

The invention also provides for braking means to act upon the rotating drilling bur, whereby upon deactivation of the turbine drive, the bur will be rapidly decelerated to its stop mode. This arrangement serves to minimize the danger of inadvertent injury to the patient upon removal of the bur from the affected tooth.

It is one object of the present invention to provide a readily usable and highly effective medical apparatus for producing an electric analgesic effect simultaneously with the use of pain-producing medical tools.

Another object of the present invention is to provide a dental drilling apparatus which produces an electrical analgesic effect simultaneously with its use.

Still another object of the present invention is to provide a self contained dental drilling apparatus for producing electric analgesia.

A further object of the present invention is to provide a dental drilling apparatus for producing electric analgesia which is simple to use and minimizes any adverse psychological reaction in patients.

A still further object of the present invention is to provide a dental drilling apparatus which generates a predetermined subliminal current in the dental drilling bur by the movement of a magnetic field across a coil having a predetermined number of windings.

A yet further object of the present invention is to provide a dental drilling apparatus for producing electrio-analgesia which utilizes the usual type of dental drilling bur.

Another object of the present invention is to provide a dental drilling apparatus having braking means rapidly to decelerate the rotating drilling bur to its stop mode upon deactivation of the turbine.

Still another object of the present invention is to provide a modular dental drilling apparatus which may be readily serviced at its operating location.

Yet another object of the present invention is to provide a simple and inexpensive apparatus for manipulating a rotatable chuck such as may be used in connection with a dental drilling handpiece.

BRIEF DESCRIPTION OF THE DRAWINGS For a better understanding of the present invention, reference may be had to the accompanying drawings, in which:

FIG. 1 is a side elevation, partially cut away, of a preferred dental handpiece embodying the principles of the invention;

FIG. 2 is an enlarged, fragmentary, vertical sectional view of the head of the handpiece shown in FIG. 1;

FIG. 3 is a view taken along the line 33 of FIG. 2;

FIG. 4 is an enlarged, fragmentary, vertical sectional view of the head of an alternate embodiment of the present invention.

FIG. 5 is a view taken along the line 55 of FIG. 4;

FIG. 6 is a fragmentary side elevationalview of a wrench implement to aid in replacement of dental tools in the handpiece;

FIG. 7 is a view taken along the line 77 of FIG. 6; and

FIG. 8 is a view taken along the line 88 of FIG. 6.

BRIEF DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring now to the drawings, and in particular to FIGS. 1 and 2, there is shown, by way of example, a dental handpiece, generally indicated by reference numeral 10, having an elongated handle 11 with knurled gripping portions 12, and a head 13. A pain-producing tool 14, which in the present embodiment is a dental drilling bur, protrudes from the head 13 for operating upon a tooth 16. It should be understood, however, that the invention may be used in connection with different types of medical pain-producing tools, and is not to be limited to dental drilling apparatus.

FIG. 1 is, by way of example, a schematic illustration of the electrical circuit for producing electric desensitization during a dental drilling operation. As will be described below, current is generated within the head 13 during the drilling procedure. Upon contact between the tooth 16 and the drilling bur 14, such cur-' rent will flow into the tooth provided that the tooth is effectively connected to a circuit-common, which is preferably the casing 17 of the handpiece 10. .It has been observed that a current of approximately 2 microamps is sufficient to desensitize the nervous system of the tooth. The effect of such desensitization is limited to the specific tooth involved and only for such a duration of time as that tooth is in contact with the drilling bur 14.

The handpiece 10 may also contain a conventional cooling system, including a tube 15 for directing a water spray against the tooth while the drilling is being carried out. Fiber optic techniques, embodied in a light-conducting tube 20, for illuminating the drilling area may also be contained within the handpiece.

As shown in FIG. 2, the head 13 is preferably composed of a plurality of interconnecting housing portions, each of which may be formed from stainless steel, or other electrically conductive materials suitably rigid to form a proper housing structure. A cap 19 forms an enclosure for the open end of the turbine casing 18 and may be connected thereto by means of cooperating threaded portion 21. The removable cap 19 provides easy access to the internal components of the device to simplify assembly and repair.

The cap 19 is also provided with a central bore 22 having a reduced diameter portion 23 and a larger diameter portion 24. An insert cap 26, preferably hav- -ing a threaded engagement with the larger diameter portion 24 of the bore 22, may be provided to allow easy access to, and replacement of, certain components parts subject to frictional erosion, as will be described in detail below.

Since the head of a dental handpiece is intended for use within a patients mouth, the outer surface area must be smooth and free from edges which might cause inadvertent injury. Accordingly, the insert 26 fits within the bore 22 so that its upper surface is flush with the outer edge of the cap 19. Under such circumstances, it has been found convenient to provide the insert 26 with a pair of

recesses

27 and 27a, which may be used to apply the necessary rotational torque.

Located within the turbine easing 18 is a fluid turbine 28 which is mounted on upper and lower bearings 29 and 29a. A conventional feed tube 30 carries the driving fluid, usually air or water, to the turbine from a remote source. In operation, the fluid is directed over drive blades 31, thereby forcing them to rotate. An exhaust tube (not shown) or other exhaust means, such as vents (not shown) for evacuating from the head fluid which has passed over the blades 31, may also be provided in the handpiece. In the present embodiment, such residual fluid, especially air, has proved to be a useful coolant for components subject to high frictional temperatures during operation.

A preferably elongated rotor shaft, a hub, 32 is connected to the turbine blades 31 so as to be driven thereby, and contains a central bore 33 which extends inward from its lower or external end almost to the top thereof so that the hub is, in effect, substantially tubular. The upper end of the bore is threaded, as indicated by reference numeral 40, so as to connect with a correspondingly threaded collet member 34. The rotor shaft 32 and collet 34 have

external extensions

35 and 36 respectively, each with a preferably hexagonal outer surface. The rotor shaft and collet function together as i a rotary chuck, generally indicated by reference numeral 60, for gripping the drilling bur 14. As indicated in FIG. 2 the bur may be inserted into the chuck to any desired depth of penetration.

The turbine-bearing assembly 28 may be mounted within a preferably hard rubber or neoprene enclosure 37 electrically to insulate the assembly from the casing 18 and otherwise to secure the turbine tightly within the casing 18. The hard rubber enclosure is preferably provided with a longitudinal slot 38 for the purpose of engaging a pair of guide pins 39 and 39a which may extend laterally inwardly from the turbine casing 18. The

pins

39 and 39a serve both to orient the turbine 28 within the casing and to anchor the hard rubber enclosure so as to prevent the cartridge from rotating along with the turbine blades and rotor shaft during the drilling operation.

Electrical conductor means, preferably a coil 41 (FIG. 3) having a predetermined number of windings may be mounted within the casing 18. This coil may be mounted on an armature orcoil form 42. The number of windings may vary. By way of example, however, where 0.005 inch diameter wire is used, it has been found that 21 turns is suitable, although these requirements may be varied depending upon whether more or less voltage is desired.

It is important to note that the present invention is not to be limited by either the configuration or the number of conductive elements operative within the head 13. Conductor configuration, other than a coil, such as a grid or similar arrangement, may also be suitable. In the preferred embodiment however, one coil has been found suitable, although other coils, for example two or more connected in series or in parallel, may be utilized respectively to increase voltage or dependability, as desired, without departing from the scope of the invention. One head 43 of the coil, arbitrarily referred to as the common lead, is electrically connected to the casing 18, while the other lead 44, or hot" lead, is preferably electrically connected to the drilling bur 14 through contact means to be described in detail below.

Magnet means, consisting of a permanent magnet rotor 45 of preferably ceramic material, may be mounted for rotation on the turbine rotor shaft 32 proximal to the coil 41, butseparated therefrom by an air gap 46 (FIG. 4). The rotor 45 is preferably annular, having permanently magnetized areas of alternating polarity spaced around its circumference. During operation of the dental turbine, rotation of the rotor shaft 32 and the rotor 45 will cause each of the magnetized area of the rotor to move successively past the coil windings 41. In accordance with known principles, an electric potential will be induced in the coil as the magnetic flux lines cross the windings. By way of example, suitable analgesic results are obtained when this induced voltage is approximately 0.06 volts, yielding an AC current of substantially 2 microamps. The air gap 46 may be adjustable to aid in determining suitable voltage levels, as desired.

It is to be understood that numerous changes in the details of construction and the combination and arrangement of the generator parts may be resorted to without departing from the scope of the invention. For example, the specific location of the magnet and coil windings need not be the same as specifically described herein. Suitable voltages have been generated when the windings are mounted for rotation on the turbine drive shaft and are encircled, or partially encircled, by a fixed permanent magnet. In addition, other conductive means may be used in place of the coil 41 to cut the line of magnetic flux. The present embodiment is preferably because it is mechanically more efficient to rotate at high speeds a body of uniform density, such as the permanent magnet rotor 45, and it has been found that more dependable voltage may be generated in this manner, and by the use of the coil 41.

The rotor 45 is preferably mounted coaxially with the shaft 32 so that its axis of rotation is substantially perpendicular to the longitudinal axis of the coil. It is also preferably that the coil form 42 and the rotor 45 are substantially laterally aligned. Under such conditions, the coil windings 4t are aligned to inter-sect magnetic flux lines of maximum density originating with the rotor 45.

Electrical contact between the drilling bur l4 and the coil 41 may be accomplished in several ways, such as by using conventional brushes. Contact may also be made through the bearing races of the turbine assembly. Such an arrangement, however, has been found to be somewhat inefficient. Furthermore, fluid turbine drills may rotate at approximately 300,000 to 400,000 revolutions per minute. For such high rotational speeds it has been discovered that suitable electrical connection is afforded by means of continuous contact between a pair of juxtaposed contact buttons 47 and 48. The contact button 47 is preferably formed of hardened silicon carbide, but may be composed of other materials such as stainless steel, and is connected to the innermost end of the rotor shaft 32. The contact surface 49 of button 47 is preferably machine flat; however, a substantially convex contact surface has also been found suitable.

The contact button 48 is connected to one side of a support member or circuit board 51 which is slidably arranged within the reduced diameter portion 23 of the bore 22 in cap 19. The button 48 is also electrically conductive and is preferably composed of a material such as silver graphite. The contact surface 49 of button 47 abuts against the button 48 during operation of the handpiece. it should be noted that a spindle contact (not shown) has also been found to provide an effective connection, and may be employed where desired, in place of either of the contact buttons 47 and 48.

The extremely high rotational speeds achieved by the turbine will cause constant erosion of the silver graphite button 48. To insure that there is continuous contact between the buttons 47 and 48, a spring 52 is positioned on the other side of the circuit board 51, between the board 51 and the insert 26, so that the former is continuously biased toward the button 47. The spring 52 is preferably a conical coil spring so that it collapses to the width of one of its coils. When the contact button 48 is new, the spring 52 is compressed between the circuit board 53 and the insert 26, thereby storing energy. As the button 48 begins to erode from rotational friction, the spring 52 gradually releases its stored energy, the effect of which urges the circuit board 51 and the eroding contact 48 longitudinally along the bore 22. When the button 48 has worn away completely, further movement of the circuit board is prevented by a stop 50 preferably protruding laterally from the side walls of the bore 22. The insert 26 may then be unscrewed from the cap 19 and the circuit board 5! simply replaced by a new circuit board and contact button. Alternatively, the cap 19, having the coil 41 and circuit board 51 connected thereto, may simply be replaced as a modular unit.

At least one contact shoe 53 may be mounted on the inner side wall of the casing 18. A lining or bushing 54 is provided to insulate the shoe 53 from electrical contact with the casing. A resilient contact arm 56 is f xed to the board 51 and is electrically connected to the contact button 48. The arm 56 is biased against the shoe 53 to complete the circuit between the coil windings 41 and the drilling bur 14, as will be described below. As the board 51 moves under impetus from the spring 52, the arm 56 slides along the contact surface of the shoe to maintain the electrical connection between the coil 41 and the button 48. This sliding contact between the arm 56 and the shoe 53 is inherently selfcleaning, and therefore minimizes the possibility of operational failure due to dirty and inefficient electrical connections.

In the event that a source of electricity (not shown) external to the medical handpiece, such as dental handpiece 10, is desirable, the component unit consisting essentially of the circuit board 51 and the contact button 48 may be employed to connect the external source to the pain-producing tool. The lead from the source may be connected to the contact button 48 in any manner known to those skilled in the art. Current from the source will therefore flow into the button 47 and from there through any appropriately insulated conductor to the pain-producing tool. Where a dental handpiece such as that indicated by reference numeral 10 is employed, current may flow from the button 47 into the turbine rotor 32, the collet member 34 and drilling bur 14. When an appropriate return connection from patient to the external source is provided to complete the electrical circuit, contact between the bur and the patient will allow current to flow from the bur and through the affected tooth to desensitize the same and return to the source. It should be noted that the lead from the external source may also be connected in any suitable manner to the contact shoe 53. In this event the resilient contact arm 56 may be utilized as described above.

in the operation of the preferred form of dental handpiece 10 the desensitizing current will flow along the following circuit: from the coil 41 through the hot lead 44 to the contact shoe 53; into the contact arm 56; to the button 48; to the button 47; to the rotor shaft 32, and hence into the drilling bur 14. When the tooth 16 has been properly connected to the circuit common 17, the current will flow into the tooth upon contact with the drill bur, thereby to desensitize the dentinal nerves.

The connection between the tooth and the common to complete the electrical circuit may be accomplished in several ways. For example, a wire lead extending from the handpiece housing to the patient may be provided. A metal clip (not shown) may be used to connect the lead to the patients lip. In the absence of a wire lead, the operator, or dentist, may complete the circuit by touching the patient while holding the dental handpiece. Patient and handpiece may be otherwise tact arm 56 and button 48 from the housing 18, such component unit may be easily replaced by the operator when the button 48 has become inefiective. Such an arrangement serves to minimize time loss and the usual expenses of maintaining operational dental equipment.

The contact shoe 53 is preferably provided with a vertical guide slot 57 to be engaged by the contact arm 56. The slot 57 serves to prevent the circuit board 51 from beginning to rotate under impetus from rotational forces transmitted through the button 48 during operation of the turbine.

Stability may be enchanced by providing a second contact shoe 58 symmetrically arrangedwithin the easing 18 with respect to the shoe 53. A second resilient contact arm 59, similar to the contact arm 56, may be provided on the circuit board 51 for engagement with the shoe 58. Although one contact shoe and contact arm have been found suitable for present purposes, others may be utilized in the present device without departing from the scope of the invention.

It should be noted that the continuous contact between the buttons 47 and 48 generates substantial frictional forces during operation of he turbine. The retarding effect of the friction on the speed of rotation of the turbine rotor 32 is relatively insignificant when the turbine is being activated. Upon deactivation of the turbine however, such frictional forces act as a brake rapidly todecelerate the rotational speed of the rotor 32 until it stops rotating. This arrangement serves to minimize the chances of an injury occurring to the patients tooth or mouth when the handpiece is being 1 removed from the affected area.

connected to a common ground. It should be noted that Such positive braking action may also be provided by types of friction producing members other than the contact button 48 to engage a corresponding portion of the rotating shaft. in the preferred embodiment, it has been found convenient to use the electrically conductive and coaxial contact buttons 47 and 48 for this purpose. All that is required, however, is to provide 21 preferably spring biased braking member (whether or not electrically conductive) to press against some portion of the turbine driven shaft, especially upon deactivation of the turbine.

FIGS. 4 and 5 illustrate an embodiment of the present invention in which miscellaneous pain-producing medical tools, and particularly dental tools such as picks, probes, excavators and other similar tools may be used interchangeably in connection with the handpiece ll0. The arrangement of magnetoelectric components is essentially the same as has been described above in connection with FIGS. 1 through 3. in this embodiment, however, the turbine-bearing assembly 128 is used only for rotating the permanent magnet rotor 145. Accordingly, the coil 141 may be electrically connected through the casing 118 to a known type of non- 'rotating metal chuck which is adapted to accept a plurality of different medical tools. Contact between the coil I41 and the chuck 160 may be made in any convenient manner; however, it has been found preferable to connect one lead 144, arbitrarily designated the return lead, to the cap 119, which in the preferred embodiment serves as a circuit common. A lead 143, arbitrarily designated as the hot lead, may be soldered to a metal ring 161 which is insulated from the cap 1 19 by a nylon or teflon bushing 162.

In the preferred arrangement, current generated in the coil by movement of the magnet rotor 1415 will flow from the coil 141 through the hot lead 143 to the ring 161. Any convenient electrical connection between the ring 161 and the patient, as described above, may be utilized to construct the appropriate electrical circuit. Upon contact between the tool 114 and the patient the circuit is complete, and current will flow through the drilling bur and into the tooth to the circuit common thereby desensitizing the affected dentinal nerve.

It should be noted that it is within the scope of the present invention to utilize the same dental handpiece 10 with either drilling burs or other pain-producing dental and medical tools. For example, if the coil 41 and shoe 53 of the embodiment of FIG. 2 were fixed to the cap 19, then the handpiece of FIG. 4 could be converted to the drilling mode simply by replacing the turbine-bearing assembly 128 with the bearing assembly 28 having a rotatable chuck, and by replacing the cap 119 with the cap 19. Such interchangeability may be easily and inexpensively accomplished in accordance with the present invention.

In the event that the pain-producing medical tool, or drilling bur, is formed of non-electrically conductive material, it is within the scope of this invention to supply current from the coil 41 to the affected area of the patient through electrical conduits other than the tool itself, Accessory probes, formed of electrically conductive material, may be utilized, or other means such as electrically conductive straps or clips may be provided, as desired, to contact the affected area.

Referring now to FIGS. 6,7 and 8, there is illustrated a wrench implement generally indicated by reference numeral 70, and intended particularly for use in manipulating the rotatable chuck 60 to aid in replacement of dental medical tools in the handpiece 10. The wrench 70 preferably consists of a shank or handle portion 71 having a plunger member 72 mounted at one end for longitudinal movement relative to the handle. The plunger may be connected to the handle in any suitable way; however, it has been found convenient to support the plunger within the bore of a hollow enlarged portion 73, so that the plunger is free to slide back and forth, as desired, when the implement is being used. A coil spring 74 serves to bias the plunger outward to the position illustred by the broken lines in FIG. 6.

A pair of laterally extending

members

76 and 77 may be provided at the other end of the shank 71 for gripping the handpiece 10. Preferably, these members consist of integral wall members separated by a fixed predetermined distance substantially equal to the longitudinal dimension of the head 13 of the handpiece. It should be noted, however, that the invention is not to be limited by such wall members, and that other types of gripping means may be provided without departing from the scope of the invention. The

wall members

76 and 77 need not be immobile. Adjustable members capable of gripping several different types and sizes of dental handpieces may also be utilized. 7

A radial slot 78 may be provided in the wall member 77 (FIG. 7). The slot 78 is adapted to fit securely over the hexagonal extension 35 of the rotor shaft 32, when the head of the handpiece 10 is positioned between the

grgpping members

76 and 77, as illustrated in FIG. 6. e purpose of the slot 78 is to hold the rotor shaft against rotation during manipulation of the chuck.

The interior end 79 of the plunger 72 is provided with a central bore 81 having a reduced diameter portion 82 and a recessed portion 83 (FIG. 8) of larger diameter. The configuration of the recessed portion 83 is such as to correspond to the shape of the collet extension 36 so that the latter may be engaged for movement independent of the rotor shaft 32.

In operation, the plunger 72 is pressed inward against the bias of the spring 74 until the recessed portion 83 engages the collet extension 36. The drilling bur 14 extends harmlessly into the remainder of the bore 81. The bur 14 is released by appropriately rotating the plunger 72 which in turn rotates the collet 34. As the collet rotates, it moves axially relative to the rotor shaft 32 by virtue of the motion translating characteristics of threaded portion 46. When the collet moves axially outward, it relaxes its grip on the drilling bur according to known principles of chuck design. The bur may then be removed and another inserted. The replacement bur may be secured in the chuck simply by reversing the direction of rotation of the collet. A knurled portion 84 is provided on the plunger to facilitate manual turning of the plunger and collet.

What is claimed is:

1. Improved dental drilling apparatus having a fluid turbine bearing assembly of the type wherein a rotary chuck is provided wherein the improvement comprises:

an elongated substantially tubular hub member having inner and outer opposite ends and connected to said assembly to be rotated thereby, at least said outer end protruding substantially axially beyond said assembly, said outer end having at least one substantially flat surface area adapted to be gripped to lock the turbine assembly against movement during manipulation of said chuck;

an elongated substantially tubular collet member having inner and outer opposite ends, and adapted to fit concentrically within said hub, said outer end of said collet protruding substantially axially beyond said outer end of said hub, said outer end having at least one substantially flat surface area adapted to be gripped for manipulation to actuate said chuck; and

motion translating means for interconnecting said hub and said collet, whereby said collet may be interlocked against inadvertent axial movement relative to said hub.

2. The device as recited in claim 1 wherein the inner end of each of said members is closed.

3. The device as recited in claim 1, wherein said motion translating means comprises:

an external threaded portion on the inner end of said collet; and v a correspondingly internal threaded portion proximal to the inner end of said hub, whereby said members may be interlocked against inadvertent axial movement.

Claims

1. Improved dental drilling apparatus having a fluid turbine bearing assembly of the type wherein a rotary chuck is provided wherein the improvement comprises: an elongated substantially tubular hub member having inner and outer opposite ends and connected to said assembly to be rotated thereby, at least said outer end protruding substantially axially beyond said assembly, said outer end having at least one substantially flat surface area adapted to be gripped to lock the turbine assembly against movement during manipulation of said chuck; an elongated substantially tubular collet member having inner and outer opposite ends, and adapted to fit concentrically within said hub, said outer end of said collet protruding substantially axially beyond said outer end of said hub, said outer end having at least one substantially flat surface area adapted to be gripped for manipulation to actuate said chuck; and motion translating means for interconnecting said hub and said collet, whereby said collet may be interlocked against inadvertent axial movement relative to said hub.

3. The device as recited in claim 1, wherein said motion translating means comprises: an external threaded portion on the inner end of said collet; and a correspondingly internal threaded portion proximal to the inner end of said hub, whereby said members may be interlocked against inadvertent axial movement.