AU2006235202A1 - Automated chuck exchange using rotating turret - Google Patents

Description

WO 2006/108220 PCT/AU2006/000483 1 AUTOMATED CHUCK EXCHANGE USING ROTATING TURRET FIELD OF THE INVENTION 5 The present invention relates, generally, to a tool having one drive shaft and rotatable bit holders that can be selectively brought to a position of use in front of the tool to enable the drive shaft to be connected to one of the bit holders in this position. More specifically, the present invention relates to a tool having bit holders mounted at arcuately-spaced positions on a turret which 10 is rotatable about an axis inclined to the shaft axis so that when one of the bit holders is brought to the position of use, the bit holder it replaces is moved simultaneously to a storage position set back from the position of use so that it does not impede the usefulness of the tool. The present invention is particularly suited, although not exclusively so, to a tool such as a pistol-grip 15 power drill designed to be used with one hand and having chucks providing the bit holders for the tool bits. Throughout the ensuing description the expressions "bit(s)", "tool bit(s)" and "drill bit(s)" are intended to refer to any suitable drill or tool device which can be mounted in the bit holders of the tool of the present invention and 20 which can be used to perform various actions including, but not limited to, drilling, grinding, countersinking, enlarging, threading and screwing. BACKGROUND OF THE INVENTION Any discussion of documents, devices, acts or knowledge in this 25 specification is included to explain the context of the invention. It should not be taken as an admission that any of the material forms a part of the prior art base or the common general knowledge in the relevant art in Australia or elsewhere on or before the priority date of the disclosure and claims herein. International Patent Application No. PCT/US2000/009080 (WO 30 2001/017728) by Richard D. Cummins, describes a hand drill having a drive shaft and a turret that is manually rotatable about an axis set at 450 to the rotational axis of the drive shaft. The turret has two chucks arranged at 900 to WO 2006/108220 PCT/AU2006/000483 2 one another and arcuately spaced around the axis of rotation of the turret. A user of the drill can load each of the chucks with an appropriately-sized drill bit so that each drill bit can be used in turn to conduct a particular operation requiring the use of two bits. To interchange the drill bits the user must hold 5 the pistol grip of the drill in one hand and, after disengaging the drill shaft from a first chuck currently at a position of use, manually turn the turret through an angle of 180'. This action brings a second chuck, and corresponding drill bit, to the position of use, wherein the user can then selectively re-engage the drive shaft with this second chuck to facilitate use of the drill bit. 10 There are may situations in which a user of a drill does not have both hands free. If both hands are not free, a user cannot interchange the chucks, and hence the drill bits, without taking a risk of some sort. One such situation occurs when a user is drilling an overhead hole while standing above ground level on a ladder. In order to interchange the positions of the drill bits when 15 using the above-described tool of the prior art, the user must descend the ladder and then manually turn the turret after which he or she can re-ascend the ladder to continue using the drill with the new drill bit in place. It is therefore an object of the present invention to provide a hand-held tool, preferably a hand-held drill, including a plurality of turret-mounted bit 20 holders which can each be selectively interchanged to a position of use without requiring the use of both hands of an operator. SUMMARY OF THE INVENTION According to the present invention there is provided a tool including a 25 plurality of bit holders interchangeable with one another at a position of use in front of the tool, the bit holders being mounted at arcuately-spaced positions on a turret rotatable around an axis set at an angle to an axis of rotation of a drive shaft which is reciprocal between first and second axially-spaced locations at which, respectively, the drive shaft is engaged and disengaged from a bit 30 holder at the position of use, wherein the positioning of the drive shaft at the second location establishes a drive connection between the drive shaft and the turret so that subsequent operation of the drive shaft rotates the turret to WO 2006/108220 PCT/AU2006/000483 3 interchange the positions of the bit holders at the position of use, and wherein the drive shaft is adapted to return to its first location and restore the drive connection with a new bit holder at the position of use after the turret has been rotated. 5 Preferably the turret has an axis of rotation set at substantially 450 to the drive shaft axis, and is equipped with two bit holders. This arrangement being particularly useful when the tool has a pistol grip, as it enables a bit holder not at the position of use to occupy a storage position at which it lies in front of the pistol grip. 10 Preferably the tool further includes at least two triggers to control the operation of the tool, a first trigger being selectively operable to establish rotation of the drive shaft, and a second trigger being selectively operable to reciprocate the drive shaft between its first and second axially-spaced locations. Preferably the triggers are arranged on a pistol grip portion of the 15 tool. In a practical preferred embodiment the drive shaft carries a pinion which is located at a non-functioning station when the drive shaft is in its first location, and which moves into meshing engagement with a ring gear disposed on or integral with the turret when the drive shaft is in its second location, 20 wherein subsequent rotation of the drive shaft rotates the turret and thus interchanges the positions of the bit holders at the position of use. In this practical embodiment it is preferred that use of the second trigger activates a solenoid which moves the drive shaft to its second location, and rotation of the turret is achieved by selectively activating the first trigger 25 whilst the drive shaft in its second location. In an alternative practical preferred embodiment the drive shaft carries a pinion which is located at a non-functioning station when the drive shaft is in its first location, and which moves into meshing engagement with a gear disposed within the turret when the drive shaft is in its second location, 30 wherein subsequent rotation of the drive shaft rotates the turret and thus interchanges the positions of the bit holders at the position of use.

WO 2006/108220 PCT/AU2006/000483 4 In this alternative practical embodiment it is preferred that the second trigger is a mechanism which mechanically moves the drive shaft to its second location as force is applied to the trigger, and when the second trigger has moved the drive shaft to its second location a sensor or switch is activated 5 which establishes rotation of the drive shaft and thus rotates the turret. In a preferred embodiment the tool is a battery powered drill and the bit holders are drill chucks. BRIEF DESCRIPTION OF THE DRAWINGS 10 In order that the invention may be more clearly understood and put into practical effect there shall now be described in detail preferred constructions of a hand-held drill in accordance with the invention. The ensuing description is given by way of non-limitative example only and is with reference to the accompanying drawings, wherein: 15 Figs. la & lb are cross-sectional side views of a hand-held electric drill, having a pistol grip, made in accordance with a first preferred embodiment of the present invention; Figs. 2a & 2b are cross-sectional plan views of Figs. la & lb respectively; 20 Fig. 3 is a cross-sectional plan view of the hand-held electric drill of Figs. la to 2b, showing the turret of the drill rotated approximately half-way between the position of use of both the chucks of the drill; Fig. 4 is a partial side view of the drill of Fig. 3; Figs. 5a to 5f are enlarged partial cross-sectional views of preferred 25 internal components of the hand-held electric drill of Figs. la to 4, these components facilitating the rotation of the turret and the engaging and disengaging of the drive shaft with the respective chucks, each drawing showing a different phase of operation of the drill; Fig. 6 is a cross-sectional side view of a hand-held electric drill, having 30 a pistol grip, made in accordance with a second preferred embodiment of the present invention; and WO 2006/108220 PCT/AU2006/000483 5~ Figs. 7a to 7d are cross-sectional side views of the hand-held electric drill of Fig. 6, each showing a different phase of operation of the drill. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 5 In Figs. 1 to 5f there is shown a hand-held tool 10 of any suitable form, for example an electric drill as shown. Although shown in the drawings as being an electric drill it should be understood that hand-held tool 10 may be embodied in many other forms and as such the invention is not limited to the specific example as shown. 10 In Figs. la & lb particularly, it can be seen that hand-held tool 10 is constructed as a drill having a body casing 12 with a pistol grip portion 14 which a user (not shown) of hand-held tool 10 (hereinafter simply referred to as "drill 10") can hold comfortably with one hand. A speed-control slide or switch 16 allows the speed of drill 10 to be altered to suit different materials 15 (not shown) to be drilled. Pistol grip portion 14 has an enlarged base 18 to enable a rechargeable battery (not shown) to be fitted to drill 10 to power the same. Two trigger switches 20,22 respectively include a power ON/OFF switch (20) for drill 10 and a chuck-changing switch (22). Although not shown in the drawings, instead of utilising a rechargeable 20 battery as a the power supply means, drill 10 may be powered by an AC mains supply or may even be a pneumatic or hydro-static drill device. It should therefore be understood that the present invention is not limited to the specific example described. The forward end of body casing 12 carries a rotatable turret 24 on 25 which are mounted two drill chucks 26,28. It should be appreciated that more than two chucks may be provided, if necessary, and as such the invention is not limited to the specific example provided. Chucks 26,28 have respective axes of rotation 30,32 and enable different tool bits 34,36, for example drill bits as shown, to be mounted in respective chucks 26,28 as shown. Body casing 12 30 contains an electric motor 38 powered by the battery of tool 10 by way of ON/OFF switch 20, and a reduction gear box 40 controlled by speed-control switch 16 and which transmits the drive of motor 38 to a drive shaft 42.

WO 2006/108220 PCT/AU2006/000483 6 As is shown in Figs. 1a & lb (and in plan view in Figs. 2a & 2b) drive shaft 42 is axially reciprocal between two, axially-spaced positions by chuck changing switch 22 when chucks 26,28 are to be interchanged with one another at the forward end of drill 10. Chucks 26,28 are mounted on respective socket 5 connectors 44,46 which are rotatably mounted on turret 24 so that their axes 30,32 are set at a suitable angle to one another, for example substantially 90' as shown. Each of socket connectors 44,46 has a central rear socket (not shown) provided with a flared entry which guides a complementary shaped plug formation (not shown) formed on the forward end of drive shaft 42 into the 10 central rear sockets during movement of drive shaft 42 to a first or engaged position (see for example Figs. la & 2a). In this way (referring particularly to the position of chuck 26 in Fig. 1 a) the plug formation of drive shaft 42 can be mated with the central rear socket of socket connector 44 so that the rotational drive from drive shaft 42 is transferred to socket connector 44 and chuck 26 at 15 the forward end of drill 10. Drive shaft 42 is resiliently biased by a spring or any other suitable means (not shown) towards its engaged position (Figs. la & 2a) at which its plug formation engages with the central rear socket of socket connector 44 at the forward end of drill 10. Operation of a solenoid 48 moves drive shaft 42 20 against the spring bias, to a second or disengaged position (see for example Figs. 1b & 2b) which is axially spaced from its engaged position (of Figs. la & 2a) and at which the plug formation at the forward end of drive shaft 42 is withdrawn from the central rear socket of socket connector 44. It should be understood that instead of utilising a spring or similar means (not shown) to 25 return drive shaft 42 to its engaged position, drill 10 may simply utilise a dual action solenoid or similar means (not shown) to perform the same action and as such the invention is not limited to the specific example provided. Turret 24 is so mounted that it can be rotated about an axis 50 after the plug formation of drive shaft 42 has been withdrawn from socket connector 44 30 to its disengaged position (of Figs. lb & 2b). Axis 50 is preferably set at an angle of 450 to the axis of drive shaft 42 as shown in the drawings, but may be set at any suitable angle, and both axes preferably lie in the same plane as the WO 2006/108220 PCT/AU2006/000483 7 longitudinal axis of pistol grip portion 14. Rotation of turret 24 is carried out to interchange the positions of chucks 26,28 by the operation of a mechanism 52 shown in more detail in Figs. Sa to 5f which will now be described. In Fig. 5a it can be seen that mechanism 52 of drill 10 includes a 5 toothed circular rack or ring gear 54 arranged concentrically with respect to rotational axis 50 of turret 24, and which is coupled to or integral with turret 24. Drive shaft 42 carries a bevel gear or pinion 56 which is brought into mesh with ring gear 54 by movement of drive shaft 42 from its engaged position to its disengaged position in the direction of arrow a (see Fig. 5b) by the 10 activation of solenoid 48 in response to the selective operation of chuck changing switch 22. The upper peripheral edge or surface of ring gear 54 carries two chevron-shaped blocks 58 arranged on diametrically opposite sides of axis 50 as shown in Fig. 5a, and which each provide a pair of opposed ramp surfaces. Blocks 58 are each positioned to cooperate with a rocker 60. 15 Rocker 60 includes two parallel arms 62 (see plan views of Figs 2a, 2b & 3) having a strip or bridge 64 joining one pair of ends 66. Bridge 64 includes a smooth underside surface which abuts against the upper peripheral edge of ring gear 54 during operation of mechanism 52. The opposed ramp surfaces of blocks 58 act against bridge 64 of rocker 60 as ring gear 54 is 20 rotated by pinion 56 (see Fig. 5d). The remaining pair of ends 68 of parallel arms 62 terminate in respective detents 70 which engage between the teeth of ring gear 54 when rocker 60 is in its rest position (illustrated in solid lines in Figs. 5a, 5b, 5e & 5f). Rocker 60 is mounted on a pin 72 which is mounted in bushings (not shown) that allow pin 72 to rotate about its axis. The underside 25 of pin 72 carries between parallel arms 62 a segment 74 having its underside toothed as shown, and which is preferably provided with a cup (not shown) arranged on or integral with its upper surface. The cup receives the lower end of a coiled compression spring 76 which is preferably retained within the interior of a straight tube (not shown). As shown in Figs. la to 4, the upper end 30 of rocker 60 is attached to body casing 12, by pin 72, at thrust block 78. Rocker 60 is biased to its rest position by segment 74 and spring 76. The toothed underside surface of segment 74 provides an over-centering device WO 2006/108220 PCT/AU2006/000483 8 which in cooperation with spring 76 maintains rocker 60 in two stationary positions, one being the rest position (Figs. 5a, 5b, 5e & 5f) and the other being a tripped position (Figs. 5c & 5d). Rocker 60 shifts to its tripped position in the direction of arrow b (see Fig. 5c) when pinion 56 engages with and pushes 5 a tripping block 78 affixed to, or integral with, the underside surface of parallel arms 62, as pinion 56 is drawn into mesh with ring gear 54 in the direction of arrow a. Rocker 60 returns to its rest position (see Figs. 5d & 5e) in the direction of arrow b' when the underside surface of bridge 64 is engaged with and urged upwards by chevron-shaped blocks 58, as ring gear 54 is rotated in 10 the direction of arrow c by pinion 56 (which rotates with drive shaft 42 in the direction of arrow d). Use of. drill 10 and the selective automated rotation of turret 24 in response to activation of chuck-changing switch 22 will now be described in more detail with particular reference to Figs. Sa to 5f. 15 When drive shaft 42 is engaged with socket connector 44 (as shown in Figs. la & 2a - which corresponds to the position of the internal components of drill 10 shown in Fig. 5a) overhead drilling (with chuck 26 and corresponding drill bit 34) can be carried out with a single hand of a user, by the selective operation of ON/OFF trigger switch 20. The operation of drill 10 can be 20 carried out, if necessary, while the user is standing on a ladder which is being held with his/her other hand. The operation of ON/OFF switch 20 completes an electrical circuit (not shown) between the battery (not shown) and motor 38 that provides an output drive which is transferred by way of gearbox 40 to drive shaft 42. Drive shaft 42 rotates at a speed determined by the depth of the 25 squeeze applied to ON/OFF switch 20. The positions of chucks 26,28 (and corresponding drill bits 34,36) can be selectively interchanged when necessary by first releasing ON/OFF switch 20. When ON/OFF switch 20 is released, the electric circuit to motor 38 is broken, which stops rotation of drive shaft 42. By then selectively depressing 30 chuck-changing switch 22, a user can interchange the positions of chucks 26,28 as required. Depressing chuck-changing switch 22 energises solenoid 48 which reciprocates drive shaft 42 from its engaged position, in the direction of WO 2006/108220 PCT/AU2006/000483 9 arrow a (Figs. 5b & 5c), to its disengaged position (Figs. 5c to 5e) at which time the plug formation (not shown) at the front end of drive shaft 42 is withdrawn from socket connector 44. Movement of drive shaft 42 to its disengaged position causes pinion 56 to engage and push tripping block 78 of 5 rocker 60 which shifts rocker 60 from its rest position to its tripped position in the direction of arrow b (Fig. 5c). The movement of rocker 60 to its tripped position brings the underside surface of bridge 64 into engagement with the upper peripheral edge of ring gear 54. Simultaneously the rotation of rocker 60 lifts detents 70, at ends 68, of parallel arms 62 out of the slots between the teeth 10 of ring gear 54, while pinion 56 meshes with ring gear 54. The user can then depress the ON/OFF trigger switch 20 with one finger while holding chuck-changing switch 22 depressed with another finger. All of this can be done by the user with a single hand only so that his/her other hand is free to continue to support himself/herself on the ladder. 15 The action of depressing ON/OFF switch 20 a second time is to energise motor 38 again but this time its rotational drive is transmitted through drive shaft 42 and pinion 56 to rotate turret 24 in the clockwise direction of arrow c (Fig. 5d). The position of chucks 26,28 are progressively interchanged (see the approximate mid-way position shown in Figs. 3 & 4) until turret 24 20 has rotated through approximating 180*, in the present embodiment, to bring socket connector 46 of chuck 28 almost opposite the forward end of drive shaft 42 so that its plug formation (not shown) is nearly aligned with the flared entry of socket connector 46. Chevron-shaped blocks 58 are so positioned on ring gear 54 of turret 24 that when this occurs, the underside surface of bridge 25 64 is engaged by the ramp surfaces of block 58 which forces bridge 64 of rocker 60 upwards which shifts rocker 60 back to its rest position in the direction of arrow b' (Fig. 5e). In the event that detents 70, on ends 68, of parallel arms 62 are opposite (not meshed) respective teeth of ring gear 54, the lifting of bridge 64 is accommodated by a small upward movement of segment 30 74 against the resilient bias of spring 76. The rotation of turret 24 is not obstructed and continues until detents 70 are aligned between the teeth of ring WO 2006/108220 PCT/AU2006/000483 10 gear 54. Detents 70 then drop in-between the teeth to prevent further rotation of turret 24. At this time the plug formation (not shown) at the forward end of drive shaft 42 is spaced opposite the flared entry to socket connector 46. Chuck 5 changing switch 22 can then be released to de-energise solenoid 48. Drive shaft 42 can then reciprocate back to its engaged position in the direction of arrow a' (Fig. 5f) under the thrust of the spring bias acting on drive shaft 42. During this movement, the plug formation is guided (by the flared entry if necessary) into connector socket 46. 10 To interchange chucks 26,28 again, the user can release ON/OFF switch 20, and press chuck-changing switch 22 as before. Motor 38 is then de energised and solenoid 48 is activated to move drive shaft 42 back into its disengaged position (in the direction of arrow a). By then operating the two switches 20,22 together, turret 24 can be rotated through 180*, or any other 15 suitable angle depending on the number of chucks and their positioning, and the sequence as already described can be repeated. In Figs. 6 to 7d, there is shown a hand-held tool 100 of any suitable form, for example an electric drill as shown, made in accordance with a second preferred embodiment of the present invention. In Figs. 6 to 7d like reference 20 numerals correspond to like parts shown in Figs. la to 5f. Tool 100 (hereinafter "drill 100") of Figs. 6 to 7d varies to that of drill 10 of Figs. la to 9d with respect to the way in which drive shaft 142 is moved between its engaged (Figs. 6 & 7d) and disengaged (Figs. 7a to 7c) positions, and also with respect to the components of mechanism 152. These major 25 differences will now be discussed. In Fig. 6, like in the case of drill 10 of Figs. 1 a to 5f, it can be seen that drive shaft 142 of drill 100 is resiliently biased by a spring 180 (or other suitable means) to its engaged position at which its plug formation 182 engages with the rear socket 184 of socket connector 144 at the forward end of drill 30 100. Instead of utilising a solenoid to move drive shaft 142 to its disengaged position, drill 100 of Figs. 6 to 7d, utilises a mechanical trigger mechanism which acts as the chuck-changing switch 122 of drill 100. Chuck-changing WO 2006/108220 PCT/AU2006/000483 11 trigger 122 pivots in the direction of arrows x and x' (see Fig. 7a & 7d) with respect to a pin 186. Chuck-changing trigger 122 assumes a rest position (see Figs. 6 & 7d) when drive shaft 142 is in its engaged position and moves to an activated position (see Figs. 7a to 7c) when drive shaft 142 is moved and 5 assumes' its disengaged position. In response to force applied to chuck changing trigger 122, and when chuck-changing trigger 122 is moved to its activated position in the direction of arrow x, drive shaft 142 is moved from its engaged position to its disengaged position in the direction of arrow a. An upper portion of chuck-changing trigger 122 acts against a protrusion 188 10 disposed on, or integral with, drive shaft 142, which enables chuck-changing trigger 122 to draw drive shaft 142 into its disengaged position in the direction of arrow a when force is applied to the same. When chuck-changing trigger 122 is released from its activation position, spring 180 returns chuck-changing trigger 122 to its rest position in the direction or arrow x' (Fig. 7d), whilst at the 15 same time spring 180 returns drive shaft 142 to its engaged position in the direction of arrow a'. Disposed on the rear peripheral edge of chuck-changing trigger 122 is an extension 190 which is arranged in such a manner that when chuck changing trigger 122 is forced to its activated position in the direction of arrow 20 x, a trip switch 192 is activated by extension 190. The activation of trip switch 192 completes an electric circuit (not shown) between the battery (not shown) and motor 138 of drill 100. When power is applied to motor 138, drive shaft 142 rotates in the direction of arrow d (see Fig. 7b) which causes turret 124 to rotate in the direction of arrow c as a result of pinion 156 being engaged with 25 mechanism 152 of drill 100 in the disengaged position of drive shaft 142. Unlike in the case of drill 10 of Figs. la to 5f, mechanism 152 of drill 100 is simply a gear 154 disposed within turret 124 that is engaged and driven by pinion 156 when drive shaft 142 is rotated in the direction of arrow d (Fig. 7b) whilst in its disengaged position. Instead of drill 100 of Figs. 6 to 7d 30 having a mechanism 152 utilising a rocker arrangement (60) which correctly positions chucks (26,28) at their respective positions of use, as in the case of drill 10 of Figs. la to 5f, drill 100 utilises sensors or switches (not shown) WO 2006/108220 PCT/AU2006/000483 12 which detect when turret 124 is correctly aligned with chucks 126,128 so that drive shaft 142 can move back to its engaged position in the direction of arrow a' when chuck-changing trigger 122 is released. Unlike in the case of drill 10 of Figs. la to 5f, chuck-changing trigger 5 122 of drill 100 enables turret 124 to be rotated by the action of a single finger, that is, chuck-changing trigger 122 provides a dual-action arrangement that simultaneously disengages drive shaft 142 and rotates turret 124 in order to interchange chucks 126,128. This same action being achieved by the operation of ON/OFF switch 20 and chuck-changing switch 22 of drill 10 of Figs. 1 a to 10 5f. It should therefore be understood that with either drill 10 or 100 of the present invention, turret 24 or 124 can be selectively and automatically rotated to interchange chucks 26,126,28,128 by using only a single hand. Thus the drill 10,100 of the present invention provides an automated chuck exchange 15 system that provides single handed operation and enables an operator to use a free hand to grasp, for example, a ladder whilst operating the drill. While this invention has been described in connection with specific embodiments thereof, it will be understood that it is capable of further modification(s). The present invention is intended to cover any variations, uses 20 or adaptations of the invention following in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains and as may be applied to the essential features hereinbefore set forth. As the present invention may be embodied in several forms without 25 departing from the spirit of the essential characteristics of the invention, it should be understood that the above described embodiments are not to limit the present invention unless otherwise specified, but rather should be construed broadly within the spirit and scope of the invention as defined in the appended claims. Various modifications and equivalent arrangements are intended to be 30 included within the spirit and scope of the invention and appended claims. Therefore, the specific embodiments are to be understood to be illustrative of the many ways in which the principles of the present invention may be WO 2006/108220 PCT/AU2006/000483 13 practiced. In the following claims, means-plus-function clauses are intended to cover structures as performing the defined function and not only structural equivalents, but also equivalent structures. For example, although a nail and a screw may not be structural equivalents in that a nail employs a cylindrical 5 surface to secure wooden parts together, whereas a screw employs a helical surface to secure wooden parts together, in the environment of fastening wooden parts, a nail and a screw are equivalent structures.

Claims (13)

1. A tool including a plurality of bit holders interchangeable with one another at a position of use in front of the tool, the bit holders being 5 mounted at arcuately-spaced positions on a turret rotatable around an axis set at an angle to an axis of rotation of a drive shaft which is reciprocal between first and second axially-spaced locations at which, respectively, the drive shaft is engaged and disengaged from a bit holder at the position of use, wherein the positioning of the drive shaft at the second location establishes a drive 10 connection between the drive shaft and the turret so that subsequent operation of the drive shaft rotates the turret to interchange the positions of the bit holders at the position of use, and wherein the drive shaft is adapted to return to its first location and restore the drive connection with a new bit holder at the position of use after the turret has been rotated. 15

2. The tool as claimed in claim 1, wherein the turret has an axis of rotation set at substantially 450 to the drive shaft axis, and is equipped with two bit holders. 20

3. The tool as claimed in claim 1 or claim 2, further including at least two triggers to control the operation of the tool, a first trigger being selectively operable to establish rotation of the drive shaft, and a second trigger being selectively operable to reciprocate the drive shaft between its first and second axially-spaced locations. 25

4. The tool as claimed in claim 3, wherein the triggers are arranged on a pistol grip portion of the tool.

5. The tool as claimed in any one of the preceding claims, wherein 30 the drive shaft carries a pinion which is located at a non-functioning station when the drive shaft is in its first location, and which moves into meshing engagement with a ring gear disposed on or integral with the turret when the drive shaft is in its second location, wherein subsequent rotation of the drive WO 2006/108220 PCT/AU2006/000483 15 shaft rotates the turret and thus interchanges the positions of the bit holders at the position of use.

6. The tool as claimed in claim 5, when appended to claim 3, 5 wherein use of the second trigger activates a solenoid which moves the drive shaft to its second location.

7. The tool as claimed in claim 6, wherein rotation of the turret is achieved by selectively activating the first trigger whilst the drive shaft in its 10 second location.

8. The tool as claimed in any one of claims 1 to 4, wherein the drive shaft carries a pinion which is located at a non-functioning station when the drive shaft is in its first location, and which moves into meshing 15 engagement with a gear disposed within the turret when the drive shaft is in its second location, wherein subsequent rotation of the drive shaft rotates the turret and thus interchanges the positions of the bit holders at the position of use.

9. The tool as claimed in claim 8, when appended to claim 3, 20 wherein the second trigger is a mechanism which mechanically moves the drive shaft to its second location as force is applied to the trigger.

10. The tool as claimed in claim 9, wherein when the second trigger has moved the drive shaft to its second location a sensor or switch is activated 25 which establishes rotation of the drive shaft and thus rotates the turret.

11. The tool as claimed in any one of the preceding claims, wherein the tool is a battery powered drill and the bit holders are drill chucks. 30

12. A tool, substantially as hereinbefore described with reference to Figs. 1 a to 5f of the accompanying drawings.

13. A tool, substantially as hereinbefore described with reference to Figs. 6 to 7d of the accompanying drawings.