FR2476737A1 - Auger for boring stony ground - has spaced teeth on pointed base to commence bore before helical part is operating - Google Patents

Abstract

The tool is for boring stony ground and uses augers having a point at the end of an axial shaft (4), followed by a helicoidal blade to remove material. The perforating head (1) has several teeth (2) on the outside of a conical blade (13a,13b). The teeth are arranged differently radially and axially on the head. They are more widely spaced diametrically opposite to each other but have the same angular inclination to the axial shaft (4). The shaft has concentric breaking teeth (5) at its end to commence the bore.

Description

The present invention relates to tools for perforating stony materials, and more particularly large diameter wicks provided with a perforating head located at the tip of an axial rod and followed by a helical fin for transporting the disaggregated material, used to drill soils with more or less rocks, or composed entirely of rocks.

 Currently, the bits used for extraction purposes have one or more series of teeth of high hardness suitably distributed with marks to achieve the greatest drilling efficiency.

In some cases, the teeth mentioned are in the same frontal plane, distributed with an arrangement in similar or distinct radial positions. In other cases, the teeth mentioned are arranged in correlative steps, with similar radial positions for each of them, and with a positional correspondence between these steps.

The present improvements are intended to increase the drilling yields obtained so far, to reduce the fatigue of the tools as well as the wear and tear undergone by the active elements of these tools, and are basically characterized in that the perforation head comprises several teeth of perforation successively contained on the trajectory of a conical helix of increasing pitch from the point of attack to the transport zone, said teeth adopting a progressive arrangement radially and axially differentiated in the head mentioned, for which those -these are distributed correlatively diametrically opposite two by two, and all with an increasing radial distance and increasing levels from the point, the median plane of the mentioned perforation teeth also having an angular value of inclination determined with respect to a plane perpendicular to the stem.

Other objects and characteristics of the invention will appear on reading the detailed description which follows, and with reference to the appended drawings given by way of non-limiting example and in which
FIG. 1 schematically represents the position of the teeth of a tool according to the invention, seen in a projection in the front plane, with the indication of the concentric grooves traversed by each tooth.

FIG. 2 corresponds to the planar development of the arrangement of the teeth of the tool relative to the planar development of a hole made in a rock, represented in FIG. 1.

 Figure 3 is a schematic representation of the tilt and deflection of a tooth relative to a three-dimensional coordinate system.

 FIG. 4 is a practical representation of the inclination and the deviation of a tooth relative to the size planes in a hole.

 Figure 5 shows in perspective a wick made with an arrangement according to the invention, in side view.

Figure 6 is a schematic view of the wick of Figure 3 from the point of attack.

 The perforation tool according to the invention consists of a perforation head 1, the essential characteristic of which is that it has several perforation teeth 2a, 2b, 2c, 2d, 2e, 2f, ..., arranged progressively at separate levels 3a, 3b, 3c, 3d, 3e, 3f ...., respectively, from the point of attack and in a helical trajectory, these perforation teeth are also diametrically opposite two by two, for the adjacent levels , and with an increasing distance r1, r2, r3, r4, r5 and r6, relative to the axis of the tool as shown in FIGS. 1 and 2. This arrangement of the teeth gives them a differentiated positioning in the axial and radial directions, on the axial rod 4.

 Other teeth 5 having a breaking action are located concentrically at the end of the mentioned rod 4, their function being to open the necessary passage in advance of the perforation teeth 2a, 2b, 2c, 2d which work in radial staggering. Between the breaking teeth 5 are interposed other auxiliary teeth 6 having a disintegration action.

The perforation teeth 2a, 2b, 2c, 2d. ., must be arranged so that their cutting action in the rock occurs obliquely such that they jointly attack the inner faces 7 and upper 8 of the successive steps which form in the hole of the rock being perforation, thus achieving the largest cutting capacity with the least effort, or the lowest energy consumption and the lowest tool wear
To have the effects mentioned above, the perforation teeth have several angular values determined by reference to the axial rod 4 of the tool, according to FIGS. 3 and 4. On the one hand, one of said values is calculated on the basis of the result of two vectors, such as the axial pressure in kg on said tool rod, and the torque of said drill bit also applied to the axis, in meters / kg, which provide the angle of inclination between the median plane of the tooth and the plane perpendicular to the rod 4, and represented by the angle g. The importance of this angular value is paramount since it determines the performance of the bit with minimal wear.

On the other hand, we consider the angular value defined between the leading edge of the tooth and the mentioned plane perpendicular to the tool shank, this angular value will be called in the following "deviation" to distinguish it from the previously defined inclination, this deviation is determined in relation to the hardness in the Mohs scale of the geological formations which are the subject of a perforation and is represented in FIGS. 2 to 4 by the angle B. This angle ss makes it possible to attack the edge formed by the inner surfaces 7 and upper 8, or the riser and the stride of the rung which in the hole of the rock is attacked by the corresponding tooth, so as to obtain a more disintegration easy of the rock mass, since they attack the sharp angle of the mentioned echelon of the cylindrical hollow, which makes that the perforation action is really an enlargement to widen this cylindrical hole. The internal vacuum thus existing avoids counterpressures and po ssibility of compaction of the rocky material, as usually occurs due to the pressure to which the rocky material is subjected by teeth which are not arranged in the proper shape; these drawbacks are also avoided thanks to the angular values K and given, which are modified as a function of the speed of rotation of the rod 4 of the tool, which in turn depends on the hardness of the rocks.

 In view of the foregoing considerations, each perforation tool normally responds to a range of rock types of similar hardness, which means that there must be various tools suitable for different hardness ranges.

 What has been said about the perforation teeth 2, about their angles of inclination <and deflection ss also applies to the rupture teeth 5 and disintegration 6 located at the end of latige 4.

As for the width of the perforation teeth 2, it is intended to be slightly greater than that of its working groove in the rock, or that of the upper plane 8, so that there is an overlap between the actions of the various teeth to have exhaustive work.

It should also be observed that the distance from the center of the perforation to successive staggerings, or that of its inner face 7, increases progressively from the lower rung having the lowest radial value.

 FIGS. 1 and 2 show the basic distribution of the perforation 2, rupture 5 and disintegration teeth 6, mentioned, while FIGS. 5 and 6 show a concrete embodiment referring to a wick 9. This wick 9 is consists of an axial rod 4 carrying a helical transport fin 10, and a perforation head 1 provided with a few pairs of perforation teeth 2a, 2b, 2c, 2d, 2e and 2f, successively staggered in radial progression, mounted on supports Il fixed on radial reinforcements 12 of two opposite helices 13a and 13b which form part of the perforation head and which make it possible to extract the material resulting from the perforation. The supports Il for the respective teeth are fitted in notches successive from the edge of the propellers 13a and 13b.

 The wick 9 proper has breaking teeth 5 at the anterior guide tip of the rod 4, concentric, regularly distributed and with an inclination of the same angular value, as well as disintegration teeth 6.

 The axial rod 4 has, at its rear end, according to the conventional method, a securing head 14 with a transverse bolt 15 applied by an orifice 16 provided with a safety key 17.

 The various perforation 2, rupture 5 and disintegration teeth 6 of the wick 9 are obtained in a material of great hardness, such as tungsten carbide, as is currently done.

 The bits 9 in question are of large diameter, having a value of between 200 and 1000 mm, the size of which has so far been adopted only for work carried out in soft soils, or composed of earth or small disaggregated stones. The use of the drill bits 9 of the present invention is suitable for the execution of holes for planting posts or for constructing pilings, and also for other works which require cementing of a certain depth in more or less less rocky.

Claims (6)

1) Tool for perforating stony materials, in particular in wicks provided with a perforation head located at the tip of an axial rod and followed by a helical transport fin disposed along said rod for extraction of disaggregated material, characterized in that the perforation head (1) comprises several perforation teeth (2a-2f) successively contained on the trajectory of a conical helix (13a-13b) of increasing pitch from the tip of attack up to the transport zone, said teeth (2) having a progressive arrangement differentiated radially and axially on the mentioned head, teeth (2) being moreover distributed correlatively diametrically opposite two by two, and all with an increasing radial distance and in increasing levels from the tip of the rod, the median plane of the mentioned perforation teeth also having an angular value (g) of inclination determined relative to a perpendicular plane e to the axial rod (4). 2) Tool according to claim 1, characterized in that the lead wires of the perforation teeth (2) further have a deviation (B) of a certain angular value, relative to a plane perpendicular to the rod axial (4), so that the action of said teeth (2) is exerted in the form of an enlargement from the edge formed by the internal (7) and upper (8) planes of the respective rung of the hole of rock during perforation 3) Tool according to one of claims 1 and 2, characterized in that the front of the axial rod (4) has breaking teeth (5) concentric, regularly distributed, preSerence 3 in number, between which s intercalate other auxiliary teeth (6) having a disintegrating action, and all of which have said inclinations and said angular deviations. 4) Tool according to claim 1, characterized in that the various perforation teeth (2) are capable of making staggerings in the rock, which consist of annular grooves in which the respective tooth (2) plows the rock in its advance , said grooves being of a width slightly smaller than the width of said teeth, so that the work is carried out with a certain overlap between the successive steps. 5) Tool according to claim 1, characterized in that the perforation head (1) of the tool contains two helical threads (13a, 13b), diametrically opposite and in a spiral, capable of extracting the material resulting from the perforation. 6) Tool according to claim 1, characterized in that the height of the successive staggerings of the perforation head (1) of the tool has an increasing progression from the lower rung of smaller radial span.