Auxiliary drill handle

Abstract

Auxiliary handle installed on the casing (11) of a drill (1) having a drilling axis (Xo), incorporating an electronic acceleration meter (231), with axes (XoYoZo) defining a reference point; one (Xo) of the axes being the drilling axis; the other axis (Yo) being that of the handle (2); and a reference surface (SR, SR1-SR3, 3, 4) associated with the reference point of the acceleration meter (231) to register the relative position between the surface to be drilled (S) and the drill (1), and calculate the set position of the drilling axis (Xo), and a display (25) to show the set position of the handle (2) calculated from the set position of the drilling axis (Xo) to execute the drilling.

Claims

1. An auxiliary handle designed to be installed on the body (11) of a drill (1) having a drilling axis (Xo); the auxiliary handle (2) characterized in that it incorporates an electronic acceleration meter (231), with axes (XoYoZo) defining an orthogonal reference point, wherein one (Xo) of the axes being the drilling axis, the other axis (Yo) being that of the handle (2), and one associated reference surface (SR,SR1-SR3) is formed by the elementary surfaces (SR1-SR3) from a shell of the auxiliary handle (2) to a reference point of the acceleration meter (231) to register a relative position between a surface to be drilled (S) and the drill (1) and to calculate a set position of the drilling axis (Xo), and wherein reference surface (SR) is composed of co-planar elementary surfaces (SR1), (SR2) integral with the auxiliary handle (2) and distributed in the direction (Yo), and a display (25) to show a set position of the handle (2) calculated from the set position of the drilling axis (Xo) to execute the drilling.

2. The auxiliary handle in accordance with claim 1, characterized in that it incorporates a collar (24) to be installed on a cylindrical neck (12) of the drill (1).

3. The auxiliary handle in accordance with claim 1, characterized in that it has a gripping part (22) terminated by an end piece in relief (21) on an exterior side and by a casing (23) on an interior side.

4. The auxiliary handle in accordance with claim 3, characterized in that the orthogonal reference point (XoYoZo) is positioned in relation to the handle (2) by the positioning of the acceleration meter (231) within the casing (23).

5. The auxiliary handle in accordance with claim 4, characterized in that the axis (Xo) of the orthogonal reference point is also that of the collar (24).

6. The auxiliary handle in accordance with claim 3, characterized in that the exterior extremity (21) and the casing (23), form co-planar elementary surfaces (SR1, SR2) distributed in the direction (Yo).

Description

DRAWINGS

(1) The invention will described hereafter in a more-detailed manner aided by examples of implementation of auxiliary drill handles illustrated in the appended drawings, in which:

(2) FIG. 1 is a plan-view schematic of an auxiliary drill handle mounted on a drill installed facing a medium to be drilled;

(3) FIG. 1A is a very-simplified schematic of the display of the auxiliary handle in FIG. 1;

(4) FIG. 2 is a plan view of the positioning of the auxiliary handle against the surface to be drilled, for the marking of the inclination of the surface;

(5) FIG. 3 is another example of marking of the inclination of the surface to be drilled, using the handle according to the invention;

(6) FIG. 4 is a very-simplified schematic of a reference surface according to the invention;

(7) FIG. 5 is a geometric schematic that explains the principle of orientation of the drill fitted with the auxiliary handle according to the invention;

(8) FIG. 5A is a schematic similar to that of FIG. 5, for an operation of marking/drilling of the surface to be drilled;

(9) FIGS. 6A, 6B are in-perspective views in two different directions of the shell of the auxiliary handle;

(10) FIG. 7 is an exploded view of the shell of the auxiliary handle.

DESCRIPTION OF IMPLEMENTATIONS OF THE INVENTION

(11) FIG. 1 is a very-schematic plan view of a hand-operated machine tool (1), such as a drill or a perforator, hereafter referred to in a simpler manner as a drill or machine. This drill (1) has the function of drilling holes at an orientation established in relation to the surface (S) of a medium (M) in which the drilling(s) is/are executed.

(12) As seen from above, the drill (1) has a body (11) accommodating the motor and the transmission mechanism, of which the output shaft bears a chuck (13) holding a tool such as the drilling bit (14). The body (11) has a cylindrical neck (12) of circular cross-section behind the chuck (13) to accommodate the auxiliary handle (2) and lock around the neck (12) in a chosen orientation.

(13) The body (11) hasin an already-known implementationa handle with a trigger and, where appropriate, an inverter of direction of rotation for the right hand. The other hand holds the auxiliary handle (2).

(14) The geometric axis or drilling axis Xo of the drill (1) is that of the chuck (13) and of the drilling tool (14).

(15) The auxiliary handle (2) is positioned in the plane of the axis Xo and of the handle of the body (11) for storage. This plane is perpendicular to the plane of FIG. 1, and passes through the axis Xo.

(16) For working, the auxiliary handle (2) is generally locked so that its axis (Yo) is perpendicular to the plane of the axis Xo and of the handle of the body. But this orientation is not essential; it can be modified according to the user's working habits.

(17) In all cases, the axis Yo is always perpendicular to the drilling axis Xo through the construction of the handle (2) and its positioning on the machine or on the neck (12) of the machine. The auxiliary handle (2) has a gripping part (22) terminated by an end piece in relief (21) on the exterior side, and by a casing (23) on the interior side; it continues through the split collar (24) engaged on the neck (12) and then locked onto it. The casing (23) houses an electronic tri-axial acceleration meter (231) of which the reference point XoYoZopreferably orthogonalis schematically illustrated in FIG. 1, together with a display (25). The electronic acceleration meter (231) incorporates calculation and storage systems for the data processing of the orientation data and its saving. Various means of control are provided, but not shown in a detailed manner, for activating the acceleration meter (on/off button) and commanding the saving/erasure of a position, or the display mode. The orthogonal reference point XoYoZo is positioned in relation to the handle (2) by the positioning of the acceleration meter (231) within the casing (23) so that: the axis Xo of the reference point is that of the machine (1), which is also that of the collar (24); the axis Yo of the reference point is that of the auxiliary handle (2).

(18) By definition, the direction Zo is the direction perpendicular to the plane (Xo, Yo). Obviously, this orientation is valid regardless of the position of rotation in which the auxiliary handle (2) is locked around the neck (12), namely the machine's drilling axis Xo.

(19) The acceleration meter automatically knows the vertical direction V and, consequently, the horizontal plane and the direction of North within the plane, such that it also knows the matrix of rotation to change from this geographical orientation (absolute orientation) to the instantaneous orientation of the handle via the reference point XoYoZo of the acceleration meter associated with the auxiliary handle.

(20) The auxiliary handle (2) has a flat reference surface (SR) that enables markingvia contactof the surface (S) of the medium (M) to orient/adjust the orientation of the drilling axis Xo in relation to the surface (S). The surface (S) is, by definition, flator it is at least locally flat at the position intended for the drilling(s).

(21) As seen in FIG. 1, the reference surface (SR) is composed of co-planar elementary surfaces (SR1), (SR2) integral with the auxiliary handle (2) and, preferably, distributed in the direction Yo, namely co-planar surfaces containing a parallel to the axis Yo.

(22) The elementary surfaces of (SR1), (SR2) are borne by the extremities of the handle bounding the gripping area (22), namely the exterior extremity (21) and the casing (23). There might also be, in addition to or instead of one of these elementary surfaces, an elementary surface (SR3) on the collar (24). The reference surface (SR) is used to establish the orientation of the surface (S) of the medium (M) with the handle (2), by applying this reference surface (SR) against the surface (S)directly, as shown in FIG. 2, or by means of an accessory (3), (4) as shown in FIGS. 3 and 4. The marking of the orientation of the surface (S) will be described with reference to FIG. 5.

(23) FIG. 1 shows the orthogonal reference point associated with the drill (1) in the horizontal plane (as a hypothesis), which is the plane in FIG. 1, with its demi-axes: OX0, Oxo; OYo, Oyo; Zo.

(24) As seen in FIG. 1A, the auxiliary handle (2) incorporates a display (25)preferably analog, with one or two strips of illuminating points (LEDs) to aid with the orientation of the drill (1) in the right directions in relation to the surface (S) for executing the drilling.

(25) The analog display (25) is composed of an illuminating reticle formed by two perpendicular illuminating lines (LV), (LH) that cross each other at the origin O to display the set position of the handle (2) associated with the set position of the drilling axis Xo. It is supposed that the inclination (generally vertical) of the surface (S) has been marked and saved in the acceleration meter (231), and that it is now necessary to execute drillings oriented correctly within the surface (S). It is supposed that the reference plane thus defined is the plane in FIGS. 1 and 1A. The surface S has been marked and does not necessarily have an orientation perpendicular to the plane in FIGS. 1 and 1A.

(26) When presenting the drill (1) to execute a drilling, as per the orientation in FIG. 1A, if the auxiliary handle is inclined to the bottom right, the branch OYo will be illuminated over a length dependent on the amplitude of the inclination; the branch ends when the inclination is zero, namely when the handle (2) is in the horizontal direction of Yo.

(27) The same applies from the line Xo O X0, of which the OX0 branchis illuminated if X0 is inclined towards the bottom, machine side.

(28) These means of analog display of the set position are only conventional examples; one can, for example, illuminate the other branch of each line or invert the concepts of inclination upwards/downwards. All these analog display systems show the correct position by complete extinction of their illumination, or by only leaving the illumination of the origin O in another colorgreen, for instancewhereas the branches are illuminated in red or orange when they are inclined.

(29) FIG. 2 shows the auxiliary handle (2) alone, applied via its elementary reference surfaces (SR1), (SR2), (SR3) against the surface (S) to mark its orientation. For this, one dismounts the handle (2) by loosening the collar (24). After the marking, the handle (2) is remounted. This operation is very quick because one only has to loosen and then tighten the collar securing nut.

(30) This marking is performed by the acceleration meter, which automatically corrects the handle's set position, namely performs the marking of the orientation of the surface (S) in relation to the acceleration meter's horizontal plane, regardless of the actual orientation of the handle during this marking. The user saves the position of the surface (S) by pressing a button that is not illustrated.

(31) According to one variant (FIG. 3), the reference surface (SR) is an accessory (3) composed of a flat plate (31)a disc, for exampleendowed with a shaft (32) perpendicular to the surface of the plate (31). This shaft (32) is fitted into the chuck (12), like the stem of a drill bit, and is secured there to support the plate, mounted on the machine (1), with its auxiliary handle (2) against the surface (S) to mark the orientation.

(32) This accessory (3) avoids having to dismount the handle (2) to apply it against the surface (S) and then remount it on the drill.

(33) When the reference surface (SR) is applied against the surface (S) to be drilled, the position is registered in the acceleration meter, which will be used as reference position.

(34) FIG. 4 shows another example accessory (4) forming a reference surface (SR). The accessory (4) is a cruciform shape with two branches (41), (42) pivoting between a folded position and a position of deployment in cruciform shape. The extremities define a plane via studs (43). The cruciform shape (4) is endowed with a shaft (44) perpendicular to the plane of the deployed cruciform shape (4). This reference surface is used like the one illustrated in FIG. 3.

(35) The acquisition of the orientation of the flat surface (S) is described with the aid of FIG. 5, which shows the plane (line S) which, for simplification, is perpendicular to the surface of the plane in FIG. 5, in which the vertical direction V and the horizontal direction H have been indicated.

(36) The auxiliary handle (2) with the built-in acceleration meter (231) and the reference surface (SR), or the handle (2) only, are applied by the reference flat surface (SR) against the surface (S) (the items are not illustrated in FIG. 5).

(37) The drilling axis Xo is contained within the plane in the illustration, which results automatically from the simple positioning of the reference surface (SR) against the surface (S) of the wall. However, the same does not apply for the axis Zo. To position it within the plane in FIG. 5, which is also the vertical plane, one pivots the auxiliary handle (2) around the axis Xo until it is horizontal (this direction is perpendicular to the plane in FIG. 5). This is one of the manners of using the acceleration meter to detect the inclination of the surface (S). However, as already explained above, the fact of producing the reference surface (SR)which is perpendicular to the axis Xo of the drill (1)the only undetermined variable is the orientation of the handle (2) at the moment of the registration: one of the solutions consists in placing the handle in the horizontal position; the other, simpler solution is to use the horizontal orientation internally within the acceleration meter, without taking account of the orientation of the handle (2) for the marking. This will give the position of the surface (S) and of the handle in relation to this marked position. Then, to use the drill and its positioning in relation to the surface (S) to be drilled, the acceleration meter will imposevia its display (25)the set position of the axis Xo of the drill (1) through the set position to be attributed to the handle (2) (its axis Yo).

(38) In the example presented, the axis Zo forms an angle () in relation to the vertical (V). This angle is the inclination of the surface (S). It is zero with a vertical surface (S). This marking measurement is performed to execute a drilling perpendicular to the surface (S) in the direction of drilling Xowhich is inclined here in relation to the vertical (V)can also be used to execute a drilling that is non-perpendicular to the surface (S), which can also not be vertical but inclined.

(39) If the drilling angle is other than 90, one simply enters the changed angle into the acceleration meter to take account of it automatically. The registration of the inclination of the surface (S) is still performed as described above. The marking processes described above provide precise orientations of the drilling axis for precise, imposed examples.

(40) But it is also possible to register an appropriate angle specified by the operator. This presents the drill equipped with the drill bit in accordance with the desired orientation against the surface to be drilled. It commands the saving of this part of the acceleration meter, and then uses this orientation for four other drillings of a series of drillings.

(41) After having thus marked the angle of the surface (S) and having saved it in the acceleration meter, it is easy to position the drilling access Xo in accordance with the desired angle (direction perpendicular to the surface (S) or in accordance with a certain inclination, with simple reference to the readings of the display (25) for calculating the orientation errors of the lines (LV), (LH) and display the correct general orientation via the extinction of lines and the possible illumination of the origin of the display reticle.

(42) To explain the principle employed by the acceleration meter and the display without requiring a particular level to obtain the horizontal direction of the auxiliary handle (2), the various angular relationships are described below. Firstly, it is simple to explain how to orient the auxiliary handle (2) horizontally, using the diagram in FIG. 5.

(43) For the needs of the explanation, one can assume that, working from the position to be obtained, namely the position of the machine (1) when oriented correctly, to drill: the drilling axis Xo is perpendicular to the surface (S) to be drilled (this is the general case); the axis Yo of the auxiliary handle (2) is perpendicular to the plane in FIG. 5 and, therefore, the axis Zo is within the plane of this illustration.

(44) This also means, geometrically, that the plane perpendicular to Zo containing the axis Xo cuts through the surface (S) in a line that is horizontal because the said line is perpendicular to the plane in FIG. 5, which is vertical by hypothesis.

(45) If, for whatever reason, the drill (1) moves and if, in a simple example, it conserves the orientation of the axis Zo in relation to the vertical, namely that the line of drilling Xo remains within the perpendicular plane PXo in FIG. 5, but is inclined in relation to the surface (S) then the axis Yo of the auxiliary handle (2) remains within the plane PXo perpendicular to the fixed axis Zo. But it will no longer be perpendicular to the plane in the illustration and, therefore, the axis Yo, namely the auxiliary handle (2) will no longer be horizontal; this is of no importance in itself for the auxiliary handle (2), but it means that the drilling axis Xo is no longer perpendicular to the surface (S). In other words, if the handle (2) is no longer horizontal, the drilling axis Xo will no longer be perpendicular to the surface (S).

(46) Working from the result to be obtained (the orientation of the axis Xo in relation to the surface (S), this analysis shows that the marking registered within the acceleration meter, namely the angle () and the horizontal direction imposed on the axis Yo of the handle (2) are sufficient to correctly orient the drill (1) for drilling.

(47) To sum up, the acceleration meter enables one to adjust the drilling axis Xo in relation to the surface (S) by observing its display (25) while doing drilling work and/or for executing successive drillings with the same orientation in relation to the surface (S).

(48) A similar mutans mutandis explanation also applies to a change of inclination of the axis Zo that moves outside the plane in FIG. 5.

(49) The various explanations provided above apply to any other orientation to be given to the drilling axis Xo, with this being achieved by a simple change of orientation of the angle of the surface (S) to be drilled, and for drilling axis Xo that are not only inclined in a plane (V, H) perpendicular to the surface (S) but also for whatever inclination of the drilling axis Xo.

(50) Thus, FIG. 5A shows how to drill a hole of direction X.sub.1 forming a precise angle () in relation to the perpendicular Xo to the surface (S), after having marked and saved the inclination of the surface (S). One simply enters the value () into the acceleration meter (231) for it to take it into account and specify this direction X.sub.1 in relation to the horizontal plane, with the perpendicularity of Xo in relation to the plane being obtained at the moment of the marking, working from the inclination of the reference point XoYoZo in relation to the vertical direction, with the axis Yo being horizontal.

(51) FIGS. 6A and 6B show an in-perspective view, in two different directions, of an auxiliary handle (200) according to the invention, composed of a shell with two constituent parts (201), (202) cutting across the horizontal plane of symmetry. The handle (200) has one end in relief (221), a gripping part (222), and a casing (223) followed by a split collar (224) that fits around the cylindrical neck (12) of the drill's (1) body (11).

(52) The elementary surfaces (SR1), (SR2) have facets forward of the extremity in relief (221) and the casing (223). The casing (223) incorporates a display (225).

(53) The actuating instrumentation such as the on/off button or the button for registering the surface (S) are not illustrated.

(54) FIG. 7 shows the two semi-shells (201), (202) separated at the plane of joining and the seal (203) engaged in a peripheral groove (204) to ensure the impermeability of the shell's interior. As explained above, the shell accommodates the various functional parts of the handlenotably the acceleration meter, the power supply battery and, where applicable, the remote sensing or orientation LEDs emitting a directional beam through apertures (not referenced) in the casing and in the extremity in relief (223), (221).

LIST OF PRINCIPAL PARTS

(55) 1 Drill 11 Body 12 Cylindrical neck 13 Chuck 14 Drilling tool/bit 2 Auxiliary handle 21 Extremity in relief 22 Gripping part 23 Casings 200 Auxiliary handle 201 Shell component 202 Shell component 203 Seal 204 Peripheral groove 221 Extremity in relief 222 Gripping part 223 Casing 224 Collar 231 Acceleration meter 24 Collar 25 Display 3 Accessory 31 Flat plate 32 Shaft 4 Accessory/cruciform part 41 Branch 42 Branch 43 Shaft LH Horizontal line LV Vertical line M Medium/wall S Surface to be drilled SR Reference surface SR1, SR2, SR3 Elementary reference surfaces