FR2569141A1 - Process and tool for drilling holes with a chamber, in particular in walls made of concrete, plaster or similar material - Google Patents

Abstract

Tool for drilling a hole with a chamber, comprising, at the end of an elongated body C, a pivoting blade L having a cutting edge and a non-cutting cam profile interacting with a ball B placed at the bottom of the hole.

Description

The problem of drilling chamber or shoulder holes in walls of concrete, plaster, or other material, for example for the installation of certain dowels, has so far been solved only by means of tools relatively complex, which do not allow a great variety in the shape and dimensions of the chambers and whose handling is delicate.

The subject of the invention is a method of drilling chamber holes which uses a very simple construction tool having great flexibility and great ease of use.

The tool according to the invention is mainly characterized by at least one blade movable angularly about a transverse axis at the end of an elongated body, said blade having, apart from its cutting edge, a cam profile which cooperates with a profiled part resting at the bottom of the hole to give the blade a variable orientation depending on the axial pressure exerted on the rod.

In a first embodiment, said profiled part is simply constituted by a ball placed at the bottom of the hole and the method according to the invention then consists in drilling a hole with a conventional drill, inserting the ball into it and bringing the blade the tool according to the invention in contact with the ball, while driving, by conventional means, the body of the tool in rapid rotation and by exerting an axial pressure. The ball then fulfills three functions, namely
- it prevents the tool from digging further in the axis of the
hole,
- it acts on the cam part of the blade and causes its
tilting,
- by turning in all directions on itself, it follows the
stresses of the work of the blade which turns around
of the axis of the elongated body and rocks around the above
transverse axis.

In a second embodiment, said profiled part is an element incorporated in the tool, comprising a cam portion retained in a housing formed at the end of the elongated body of the tool and into which the cam profile of the blade for bearing on said cam portion, and an extension which projects beyond the end of said elongated body, along the axis thereof, said extension having at its free end a spherical part intended to bear at the bottom of the hole.

The process according to the invention then consists in drilling a hole with a conventional drill, then in introducing the tool into it until bringing the spherical part to the bottom of the hole and in driving the body of the tool in rotation while exerting a thrust. axial.

Once the shoulder is done, the tool can be removed by a simple axial pull. During this withdrawal, the blade which is radially projecting at the start abuts on the anterior edge of the shoulder and is erased by tilting.

Other features, as well as the advantages of the invention, will become apparent in the light of the description below
In the attached drawing.

Figures 1 to 3 illustrate the following process
the invention, in a first embodiment of
the tool;
Figure 4 shows another embodiment of
the blade of the tool, provided with spherical portions for
mant pivot axis
Figures 5 and 6 show the end of the tool
with blade
Figure 7 is a longitudinal sectional view of
the tool, showing the drainage channels of the louse
drilling rig
FIG. 8 illustrates the second embodiment, and
Figures 9 and 10 are two axial sections of a
other mode of execution of the tool involving
two blades.

Figure 1 illustrates the first phase of the process which consists of drilling a hole with a conventional drill and then introducing a ball B at the bottom of the hole. The tool according to the invention comprises, in this first embodiment, an elongated body C carrying, at its active end, a blade L movable angularly around an axis X'X and comprising, apart from its cutting edge, a cam profile which rests on the ball. The tool is rotated around the longitudinal axis of the body C, and a thrust is exerted parallel to said axis. The ball stops the blade and prevents it from drilling more deeply; on the other hand, it causes its inclination, the greater the greater the thrust. FIG. 3 shows that the inclined blade will thus hollow out a chamber whose shape, of revolution around said longitudinal axis, depends on the thrust exerted and of the cutting edge profile. It is possible to carry out several successive operations in the same hole to increase the depth of the chamber.

The ball can be made of steel and recovered at the end of drilling by means of a flexible magnetic rod.

Of course, various solutions can be envisaged to ensure the mounting of the blade at the end of the all-round body.

One of these solutions consists for example in providing at the end of the elongated body a slot so as to constitute a yoke in which the blade is articulated. In this case, the articulation axis which passes through the two wings of the yoke can be rigidly fixed to them, for example by welding, crimping or by any other known means so as to prevent the two wings from s '' dismiss during use. Such an arrangement therefore contributes to making the tool more reliable.

In addition, to facilitate its introduction into the hole, the tool may comprise means for locking in rotation in one direction of the blade, the latter then preferably being in an axially projecting position relative to the elongated body. In the example described above, these locking means may simply consist of abutment surfaces suitably provided on said blade and on said body.

FIG. 4 illustrates a particularly advantageous embodiment of the blade, which is here provided on its two faces, at its pivoting end, with two portions of sphere
L1L2 which surround said end L3 to form with it a spherical body capable of engaging in a corresponding cavity in the end of the body of the tool and is held there by a crimp C'2, visible in FIG. 6.

It can be seen in FIG. 5 that this cavity C1 has, before crimping of its end C2, a cylindrical part open at said end extended by a hemispherical part. Figure 6 shows that after introduction of the spherical body of the blade in the cavity, the edge of the latter is crimped at its end to retain said body. A slot F open along a generatrix of the cylindrical body C to the end thereof, allows the passage of the blade.

In Figure 4, we see the cutting edge Lt of the blade and the profiled part Lc forming a cam.

In FIG. 7, which shows the body of the tool in longitudinal section, it can be seen that an axial channel Ca communicates the open cavity C1, into which the drilling dust penetrates, with axial discharge channels C2C3. r These channels can be fitted with flexible tubes (not shown) extending them axially, in which the centrifugal force creates a vacuum which sucks the dust from the bottom of the hole. As a variant, it is possible, as shown in FIG. 7, to have a fin turbine T around the body C, at the level of the channels C2C3, to reinforce the suction effect.

 FIG. 8 illustrates the second embodiment mentioned above, in which the ball B is replaced by an element secured to the body C of the tool. This element comprises a portion forming a cam Ec, retained in a housing formed at the end of the body C, and an extension which leaves the housing beyond the end of the body C and forms at its end a ball Eb. It is obvious that this ball will bear on the bottom of the hole, while the cam portion Ec bears on the cam profile of the blade L, to modify the inclination of the latter as a function of the axial thrust exerted on the 'tool. This embodiment eliminates the use of a ball lost at the bottom of the hole and which must be recovered at the end of each operation.

The invention is not limited to the use of a single blade at the end of the elongated body.

It can for example involve two blades L11 L2 articulated at one end forming a yoke of the elongated body C, as shown in FIGS. 9 and 10, these two blades L1,
L2 corresponding with the same profiled part (ball B).

The advantage of this solution is that the two blades
L1, L2 work simultaneously and in opposition so that the result of the transverse forces which they exert on the elongated body C tends to cancel out. This results in a reduction of the friction forces exerted on said body C.

It goes without saying that various other embodiments of the tool described and shown, in particular at the level of the blade and its shape, could be imagined by a person skilled in the art, without departing from the spirit of the invention.

Thus, the elongated body can be at least partially surrounded by a ring or a sleeve which is free to rotate, to eliminate friction and consequently wear of the body in contact with the hole.

Claims (7)

Patent claims  1. Chamber hole drilling tool, characterized by at least one blade (L) angularly movable about a transverse axis (X'X) at the end of an elongated body (C), said blade having, in outside its cutting edge (Lt), a cam profile (Lc) which cooperates with a profiled part <B, E c - Eb) resting at the bottom of the hole to give the blade a variable orientation depending on the axial pressure exerted on the rod.  2. Tool according to claim 1, characterized in that said blade is provided on its faces, at its pivot end (L3), with two sphere portions (L1L2) which frame said end to form with it a spherical body (L1L2L3 ) capable of engaging in a cavity (C1) formed at the end of the body (C) of the tool, while the active part of the blade passes through a slot <F) open along a generatrix of the body of the tool, to the end of it.  3. Tool according to claim 1, characterized in that said profiled part is an element incorporated in the tool, comprising a portion (Ec) forming a cam retained in a housing formed at the end of the elongated body of the tool and in which penetrates the cam profile of the blade to bear on said cam portion, and an extension which projects beyond the end of said elongated body, along the axis thereof, said extension having at its end free a spherical part 5Eb) intended to bear on the bottom of the hole.  4. Tool according to claim 1, characterized in that it comprises two blades <L1, L2) movable angularly about a transverse axis <x'X) at the end of the elongated body (C), these two blades cooperating with the same profiled part (B).  5. Tool according to one of the preceding claims, characterized in that said body is at least partially surrounded by a free rotating ring.  6. A method of drilling a chamber hole using the tool according to claim 1, characterized in that it consists in drilling a hole with a conventional drill, in introducing a ball which constitutes said profiled part, and in bringing the tool blade in contact with the ball, while driving, by conventional means, the body of the tool in rapid rotation and by exerting an axial pressure.  7. A method of drilling a chamber hole using the tool according to claim 3, characterized in that it consists in drilling a hole with a conventional drill, then inserting the tool into it until bringing the spherical part to the bottom of the hole and to drive the tool body in rotation while exerting an axial thrust.