DRILLING TOOL AND USE IN A SCREW-DRIVING OPERATION

Abstract

A drilling tool configured to operate in two drilling modes, respectively with and without hammer action, said tool comprising a front end equipped with a rotating part for mounting a drill bit by way of an SDS-type push-fitting, characterized in that said rotating part comprises mechanism for the removable attachment to a first longitudinal end of a tubular extension, this tubular extension being configured to extend along and around a drill bit mounted in the rotating part and comprising a second longitudinal end configured to bear at least one screw-driving element, such that the tool can be used for a screw-driving operation even when it is equipped with the drill bit.

Claims

1-16. (canceled)

17. A drilling tool configured to operate in a first drilling mode with hammer action and in a second drilling mode without hammer action, said drilling tool comprising: a handle; and a front end including: a rotating part including a SDS-type push-fitting configured to removably receive a drill bit, the rotating part including an extension connection mechanism engagable with a first longitudinal end of a tubular extension such that the tubular extension extends along and around the drill bit received in the rotating part, such that the tubular extension includes a second longitudinal end configured to engage a screw-driving element, and such that the drilling tool is configured to cause a screw-driving operation when the drill bit is received in the SDS-type push-fitting.

18. The drilling tool of claim 17, wherein the first longitudinal end of the tubular extension has a polygonal shape in cross section, and the extension connection mechanism includes inner walls that correspond to the polygonal shape.

19. The drilling tool of claim 17, wherein the extension connection mechanism is configured to engage the first longitudinal end via a male-female push-fitting.

20. The drilling tool of claim 17, wherein the extension connection mechanism includes a tubular body configured to extend around part of the drill bit and around the first longitudinal end of the tubular extension.

21. The drilling tool of claim 17, wherein the extension connection mechanism includes a biased retention ball movable into a recess defined by the first longitudinal end of the tubular extension.

22. The drilling tool of claim 17, wherein the extension connection mechanism includes an inwardly biased retention ball movable into a recess defined by the first longitudinal end of the tubular extension.

23. The drilling tool of claim 17, wherein the extension connection mechanism includes an inwardly biased retention ball movable into any one of a plurality of recesses defined by the first longitudinal end of the tubular extension.

24. The drilling tool of claim 17, wherein the extension connection mechanism includes an O-ring seal configured to engage the drill bit, and wherein the extension connection mechanism defines an internal annular groove configured to receive the O-ring seal.

25. The drilling tool of claim 17, which includes a mode selector operable to enable user selection of the first drilling mode and the second drilling mode, and a speed selector operable to enable user selection of a first speed for hammer drilling with a high impact force and fast screw driving, and a second lower speed for slow high-torque screw driving and hammer drilling with a lower impact force.

26. The drilling tool of claim 25, which includes a brushless motor operably connected to the rotating part to drive rotation of the rotating part, the brushless motor connected by a microcontroller to the mode selector, the speed selector, and to a trigger supported by the handle.

27. The drilling tool of claim 26, wherein the rotating part and the extension connection mechanism are configured to not transmit hammer action to the tubular extension.

28. A tubular extension for the drilling tool claim 17, the tubular extension having an elongated shape, a first longitudinal end configured to be removable attached to the extension connection mechanism, and a second longitudinal end configured to engage a screw driving element, the tubular extension defining a longitudinal internal bore that is open at the first longitudinal end and that is of a length and a diameter such that the tubular extension can be removably mounted to the drilling tool over the drill bit.

29. The tubular extension of claim 28, wherein the longitudinal internal bore includes at least two cylindrical portions of different diameters, including a first portion of larger diameter than a second diameter, and wherein the first portion is at the first longitudinal end.

30. The tubular extension of claim 28, wherein the second longitudinal end is configured to receive an element affixed by a male or female push-fitting.

31. The tubular extension of claim 28, wherein the second longitudinal end is configured to receive two elements affixed by male and female push-fittings, respectively.

32. The tubular extension of claim 28, wherein the second longitudinal end has a polygonal shape in cross section.

33. An assembly comprising the drilling tool of claim 17 and the tubular extension of claim 28.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0029] The present disclosure will be better understood and further details, features and advantages thereof will become more clearly apparent from reading the following description, given by way of non-limiting example and made with reference to the attached drawings in which:

[0030] FIG. 1 is a schematic perspective view of a drilling tool equipped with a tubular extension according to the present disclosure, the drilling tool being depicted in part;

[0031] FIG. 2 is a schematic perspective and sectioned view of the tool of FIG. 1;

[0032] FIG. 3 is a schematic perspective view of the tool of FIG. 3, the extension having been removed from the front end of the tool;

[0033] FIG. 4 is a schematic view in axial section of part of the front end and of the extension of the tool of FIG. 1;

[0034] FIG. 5 is a schematic and exploded perspective view of the elements of FIG. 4;

[0035] FIG. 6 is a schematic and perspective view of an alternative form of embodiment of a drilling tool equipped with an extension according to the present disclosure, the drilling tool being depicted in part and the extension being removed from the front end of the tool; and

[0036] FIG. 7 very schematically depicts an electronic circuit for the control of the tool.

DETAILED DESCRIPTION

[0037] FIGS. 1 to 5 depict a first embodiment of a drilling tool 10 according to the present disclosure, this tool being depicted in part.

[0038] Conventionally, such a tool 10 is portable and therefore comprises a handle for a user to hold and a front end 12 for mounting a drill bit, only the front end 12 of the tool being visible in the drawings.

[0039] This tool 10 is able to operate in two drilling modes, respectively with and without hammer action. For that, the tool 10 is equipped with a first selector (not depicted) for selecting the mode of operation from these two drilling modes.

[0040] This first selector is situated on a housing of the tool and is accessible to the user. It may come in the form of a rotary knob that the user can move between two positions, for example spaced 180 apart, a first position for selecting the mode of drilling without hammer action, in which an arrow on the knob points for example toward a first drawing provided on the housing and depicting for example a drill bit, and a second position for selecting the mode of drilling with hammer action, in which the arrow on the knob points toward another drawing provided on the housing and depicting for example a hammer.

[0041] The front end 12 of the tool is configured to accept a drill bit via an SDS-type push-fit, which may be SDS+, SDSmax or the like. Naturally, a drill bit is chosen according to its drilling diameter, namely to the diameter of its drilling portion 18b. The diameter of its SDS attachment portion 18a however, is standard.

[0042] In the description which follows, expressions such as axial, radial, longitudinal, etc. refer to the axis of the front end of the tool or to the axis of the drill bit, which in the drawings is indicated by the reference A.

[0043] The front end 12 comprises a fixed part and a rotary part rotating about the axis A. The rotating part comprises an SDS-type mechanism 14 for push-fitting the drill bit, which mechanism will not be described in detail as it forms part of the general knowledge of a person skilled in the art in this field. For an understanding of the present disclosure, it should be noted that this push-fitting mechanism 14 comprise a rotary ring 16 that extends around the SDS-fixing portion 18a of the drill bit 18 and that comprises radial through-slots 20 in which there are mounted rollers 22 intended to engage in longitudinal grooves 24 in this portion 18a of the drill bit. A locking mechanism 26 allows the rollers 22 to be blocked radially in the grooves while at the same time allowing the drill bit a translational travel in the front end of the tool, which travel is notably dependent on the length of the grooves 24. The mechanism 26 is accessible to the user who can unlock the assembly in order to remove the drill bit or replace same.

[0044] According to the present disclosure, the rotating part of the front end of the tool 10 further comprises an extension connection mechanism 28 for removable attachment of an extension referred to in the drawings by the reference 30.

[0045] This extension 30 is tubular and has an elongate overall shape. It is configured to extend along and around the drill bit 18, beyond its drilling tip 18c. The extension 30 comprises two opposite longitudinal ends including: [0046] a first longitudinal end 30a configured to be connected removably to the front end of the tool, and in particular to its rotating part, so that the extension can be driven in rotation, and [0047] a second longitudinal end 30b configured to bear at least one screw-driving element.

[0048] The extension connection mechanism 28 comprises a tubular body 32 intended to be secured in terms of rotation to the rotating part of the front end of the tool. The body 32 is intended to extend around a portion of the ring 16 and may be secured in terms of rotation to this ring directly. For that purpose, it comprises an end portion 32a, situated on the same side as the ring 16, and configured to fit onto the ring 16.

[0049] This end portion 32a is surmounted by an annular seal 34 that collaborates both with the ring 16 and the aforementioned locking mechanism 26 to prevent the passage of dust between these components during operation. The body 32 further comprises or defines an internal annular groove for housing another annular seal 35, such as an O-ring, which extends around the part 18a of the drill bit and engages with this portion 18a when the latter is mounted in the front end of the tool.

[0050] The body 32 further comprises, on the opposite side to its portion 32a, an end portion 32b configured to engage by male/female push-fitting with the first end 30a of the extension. In the embodiment of FIGS. 1 to 5, this portion 32b is female and accommodates the male end 30a of the extension. However, the reverse is conceivable, as visible in the alternative form of embodiment in FIG. 6, in which the first end of the extension is female and accepts a male portion of the front end of the tool.

[0051] The extension 30 is intended to be set in rotation by the rotating part of the front end of the tool and therefore to rotate as one with this rotating part. This inability to rotate independently of one another can be obtained in a simple way by collaboration of shapes, the male-female push-fitting being for example performed by portions with polygonal cross sections, as in the example depicted.

[0052] The inside of the portion 32b of the body thus in cross section has a polygonal and, more precisely, hexagonal, shape that complements the cross-sectional shape of the end 30a of the extension. The end 30a of the extension thus comprises planar exterior faces uniformly distributed on its circumference and connected one to the next by longitudinal edge corners 30b. The end 30a is, for example, of the SW13 type. As can be seen in FIGS. 3 and 5, each edge corner 30b is interrupted by a localized recess 36. The recesses 36 are situated on the one same circumference centered on the longitudinal axis of the extension, which coincides with the axis A of the drill bit and of the front end, and form sectors of an external peripheral annular groove.

[0053] The recesses 36 are intended to collaborate with a ball retention system 38 borne by the body 32 of the extension connection mechanism 28. The ball retention system 38 comprises at least one ball 40 engaged in a radial hole in the portion 32b of the body and held in this hole by way of a split ring 42 that surrounds the portion 32b, passing over the ball. The ball 40 is prevented from escaping radially outward by this ring, and radially inward by the shape or dimensions of the hole, the radially internal opening of which may for example be of a diameter smaller than the diameter of the ball. The ball 40 is urged radially inward by the ring 42 and by default adopts a position in which it partially projects radially into the internal passage of the portion 32a into which the end 30a of the extension is push-fitted. When the extension is mounted in the front end, the ball 40 is therefore engaged in a recess 36 of the extension, allowing the extension to be retained axially in relation to the front end. A manual force to extract the extension can be applied by the user to overcome the resistance of the ball and pull the extension off the tool, in axial translation.

[0054] The extension 30 comprises or defines an internal longitudinal bore 44 to accept a drill bit, when such a drill bit is mounted in the front end of the tool. The dimensions of this bore 44 are therefore notably dependent on those of the drill bit. In the example depicted, the bore 44 comprises two cylindrical portions 44a and 44b. The portion 44a, situated on the front-end side of the tool, has a diameter D1 so that it surrounds, with a small radial clearance, the portion 18b of the drill bit, which is of standard diameter as mentioned in the foregoing. The portion 44b, situated on the opposite side, has a diameter D2, where D2 is equal to or less than D1, so as to surround with clearance the portion 18a of the drill bit.

[0055] The example depicted is particularly well suited to a drill bit of which the diameter of its portion 18a is at most equal to the diameter of its portion 18b (in which case the diameters of the portions 44a and 44b are identical). If the diameter of the portion 18a of the drill bit were greater than the diameter of its portion 18b, the diameter of the portion 44b would be greater and the alternative form of embodiment of FIG. 6 would be adopted because its extension is able to accommodate a drill bit of larger diameter.

[0056] The length of the portion 44a can be predetermined. The length of the portion 44b is also predetermined, so as to maintain an axial clearance between the tip 18c of the drill bit and the end 30b of the extension (FIG. 2). The length of the portion 44b is therefore greater than the longest length of a portion 18a of a drill bit of diameter D2. An additional margin on this clearance may be used in order to give the possibility for translational movement of the drill bit inside the extension, particularly when a screw-driving operation is being performed while the tool is in hammer drill mode. The hammer action is not, however, needed during screw driving and therefore the drilling mode without hammer action will be favored. In operation, the extension and the drill bit are driven in rotation by the rotating part of the front end of the tool.

[0057] The end 30b of the extension 30 is configured to accommodate by male-female push-fitting, various types of end piece and coupling. It comprises a tubular wall 48 of polygonal, and more exactly hexagonal, cross section. This wall 48 comprises an annular row of flat external faces 48a and an annular row of flat internal faces 48b. Thus, a first element can be mounted on the wall 48 and engage through complementing shapes with the faces 48a, and a second element can be mounted in the wall 48 and engage, through complementing shapes, with the faces 48b. The complementing shapes allow these elements to be secured against rotation with respect to the extension.

[0058] An end-stop socket 50 or screw-driving socket 52 may for example be mounted on the wall 48 and comprise a female hexagonal portion (for example SW13) that complements the faces 48a. The end-stop socket 50 is intended to bear against a wall to limit the depth to which a fastener, such as a screw, is screwed into this wall. The screw-driving socket 52 comprises, for example, a hexagon-socket female end portion for driving a hexagon-head screw.

[0059] A screw-driving bit 54 may for example be mounted in the wall. This bit comprises a male (for example SW10) hexagonal portion complementing the faces 48b, and a screw-driving portion of flat-blade or cruciform or some other type. The bit 54 can be used in combination with the socket 50.

[0060] The insertion of the bit 54 into the wall 48 may be limited by a transverse wall 56 that closes the internal bore 44 of the extension, near its end 30b. Such closure is advantageous insofar as it makes it possible to improve the torsional strength of the extension. The axial position of the socket 50 and 52 on the wall 48 can be defined by the socket pressing against an external annular flange 58 situated on the end 30b.

[0061] In the example depicted, the faces 48b of the wall are separated from one another by edge corners each comprising a localized recess 58. The recesses 58 are situated on the one same circumference centered on the longitudinal axis of the extension and form sectors of an external peripheral annular groove.

[0062] The recesses 58 are intended to engage with a ball retention system 60 borne by the socket 52 and similar to the ball retention system 38 described in the foregoing. This system 60 is intended to ensure axial retention of the socket 52 on the wall 48 of the extension.

[0063] The tool 10 is advantageously able to operate at two, drilling/screw-driving speeds which are respectively high speed and low speed. For that, the tool 10 is also equipped with a speed selector 66 (FIG. 7). This selector 66 is situated on the casing of the tool and is accessible to the user. It may take the form of a switch that the user can move translationally between two positions, a first position for selecting the high-torque low drilling/screw-driving speed in which position an arrow on the knob points for example toward a first picture provided on the casing and depicting for example a tortoise, and a second position for selecting the low torque and high speed, in which position the arrow on the knob points toward another drawing provided on the casing and representing for example a hare.

[0064] For that, the tool preferably comprises a brushless motor 62 electronically controlled and, through the speed selector, making it possible to choose a torque and a speed that are suited to the desired function.

[0065] FIG. 7 depicts an electronic control circuit for controlling the tool. This circuit comprises the motor 62 that drives the rotating part of the front end 12 of the tool. The motor 62 is connected by a microcontroller 64 to the selector 66 and to the trigger 68 for operating the tool. The microcontroller 64 is also connected to a mode selector 70 for selecting a mode with or without hammer action. The microcontroller 64 controls the motor 62 according to instructions received from the trigger 68 and from the torque/speed selector 66.

[0066] In one particular exemplary embodiment, the selector 66 is provided with a magnet that is detected by two hall-effect sensors mounted on the electronic control circuit. Detection activates one or other of the modes of use: a normal mode with a maximum rotational speed of 800 revolutions/minute and a maximum torque of 7 N.m for hammer drilling and high speed, and a mode with a speed reduced to 300 revolutions/minute and a maximum torque of 15 N.m for low-speed high-torque screw-driving and for hammer drilling with a lower impact force. Activation of a mode makes it possible to define the maximum rotational speed of the tool. The trigger 68 of the tool because of its progressive action makes it possible to achieve any rotational speed within the range thus defined, without the torque varying. The hall-effect sensors detect at each moment the position of the rotor of the brushless motor. The phases of the stator windings can thus be switched in the appropriate sequence.

[0067] The electronic circuit thus makes it possible to control the rotational speed of the motor very precisely, the angular position (for example the number of turns of screwing) and the tightening torque.

[0068] The speed and angular position are perfectly determined by the hall-effect sensors that detect the position of the magnets of the rotor of the motor. The tightening torque is deduced/calculated from the measurement of the current injected into the various phases of the stator of the motor. This is because current and torque are directly proportional.

[0069] In another alternative form of embodiment that has not been depicted, a screw-driving element could be incorporated directly into the extension. The screw-driving element would then not be added on to the extension as in the aforementioned examples, but formed of one piece with this extension.

[0070] In one specific embodiment of the present disclosure, the extension has a length of the order of 200 mm and is made of metal.