NO20181642A1 - Slotted drill with interchangeable tooth ring - Google Patents

Description

SLOTTING DRILL WITH REPLACEABLE TOOTH RING

The invention relates to a slot drill designed for drilling in the ground, where the slot drill comprises a replaceable toothed ring. The invention also relates to an assembly comprising a slot drill and a drive unit, where the slot drill is connected to the drive unit.

Background for the invention

When creating larger holes or slots, it is known to use slotted drills, also referred to as hole drills, core drills or barrel drills. The slotted drill is provided in a first end section with several teeth and in a second end section connected to a drive unit. The teeth typically comprise a relatively hard material, for example diamond or tungsten carbide.

The teeth can be attached by welding, so-called brazing where a silver-containing binder is used, use of a hardenable fastening agent, screw connections or by wedging the teeth. The teeth can be round or flat and they can have a directional or directional neutral direction of movement. A tooth with a directionally neutral direction of movement typically has a symmetrical design.

Slotted drills designed for use in the ground are typically equipped with detachable teeth. Because the teeth are attached and dismantled individually, changing teeth is a time-consuming and expensive work operation. It is also known that the slot drill often has to be dismantled from the drive unit when changing teeth. If the change of teeth includes soldering and hardenable fasteners, time must be added for hardening before the slotted drill can be put into operation again.

When slot drilling in mountains and rough terrain, it is common to use a helicopter to transport the slot drill and associated equipment and crew. When the lifting operation is completed, the helicopter is usually on standby on the ground nearby, waiting to move the equipment and crew to the next drilling operation. It is therefore important that the drilling operations and associated maintenance can be carried out as efficiently as possible. Changing teeth outside of planned maintenance intervals can mean that the drilling operation stops, and both crew and

P28213NO01 description and requirements

other equipment may become inoperative. Reasons for such interruptions can be excessive wear or damage to the teeth. To reduce downtime when changing teeth, the industry is looking for alternative and simpler solutions.

Slotted drills designed for drilling in concrete, for example a brick wall, are known, where the slotted drill comprises a sleeve and a detachable toothed ring. The toothed ring is provided with a plurality of T-shaped recesses which open out of the first end portion of the toothed ring, and the sleeve is provided in its first end portion with corresponding radially arranged locking pins. The toothed ring can be locked axially to the sleeve by pushing the toothed ring onto the sleeve so that the locking pins reach the bottom of the T-shaped recesses, and then turning clockwise or counter-clockwise. The solution has several disadvantages:

- The toothed ring can loosen and fall off the sleeve if the direction of rotation of the slotted drill changes direction at the same time as the slotted drill is pulled out of the sleeve, or if the toothed ring has shifted on the sleeve.

- The first end part of the toothed ring is divided, and can thereby be easily exposed to breakage and structural weakening, especially if the material being drilled into includes loose particles, for example gravel and stone.

- The locking pins are unprotected and thus exposed to wear and damage, especially if the material being drilled into includes loose particles, for example gravel and stone.

General description of the invention

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology, or at least to provide a useful alternative to known technology.

The purpose is achieved by the features indicated in the description below and in the subsequent patent claims.

The invention is defined by the independent patent claims. The independent claims define advantageous embodiments of the invention.

In a first aspect, the invention relates to a slot drill adapted for drilling in the ground, where the slot drill comprises a sleeve with a first end part and a toothed ring which is rigidly, releasably attached to the first end part. One of the sleeve and toothed ring has a groove with two converging side surfaces and the other of the sleeve and toothed ring has a protrusion with two complementary side surfaces and the groove and the protrusion are arranged to engage with each other.

The effect of the groove and recess having two converging and complementary side surfaces is that a conical coupling part is formed where the toothed ring is wedged firmly to the sleeve so that a greater torque can be transmitted between the sleeve and to the toothed ring than a coupling part with a flat contact surface. The angle can typically be 10<0> in relation to a center axis for the slotted drill. The angle can be less than 10<0>. The angle can be greater than 10<0>. By using a small angle between the sleeve and the toothed ring, a greater torque can be transmitted than by using a large angle.

The groove and the protrusion can advantageously be designed with a flat bottom and a flat end, respectively, so that only the converging side surfaces are in contact with each other, thereby creating the largest possible friction surface between the toothed ring and the sleeve.

At least one side surface can be provided with a friction-promoting surface. The friction-enhanced surface can be a friction coating. The friction-enhancing surface can be created by processing the inclined surface, for example a mechanical processing where an uneven surface is created in the form of grooves or grooves.

The effect of the rotationally rigid attachment according to the invention is that it is possible to transfer a rotational movement in alternating directions from the sleeve to the toothed ring without a mutual movement occurring between the sleeve and the toothed ring. As a result, it is possible to change the direction of rotation of the slotted drill without causing unnecessary wear, and to change the direction of rotation at the same time as the slotted drill is pulled out of the slot in the ground without the risk of the toothed ring loosening from the sleeve. A counter-rotating motion may be necessary to loosen a jammed bit, or if it is necessary to withdraw the slot bit to clean the slot of drill dust and particles. This makes the slotted drill particularly suitable for drilling in the ground, for example in a mountain and/or a rock.

Furthermore, the invention makes it possible to combine a rotationally rigid attachment of the tooth ring with a simultaneous change of all the teeth. This means that changing teeth can be done faster and more cost-effectively than today. By changing the direction of rotation, it is also possible to get more even wear on the teeth, if directional neutral teeth are used. The toothed ring and sleeve may comprise a radial and/or axial contact surface.

The toothed ring can be releasably attached to the sleeve via a coupling adapted to be able to absorb an axial force that is greater than an axial lifting force necessary to lift the slot drill out of the ground. The coupling is placed between the first end portion of the sleeve and the toothed ring. By the fact that the coupling is stronger than the lifting force, as the invention describes, the risk that the toothed ring may fall off or be pulled from the sleeve is reduced or removed in the event of a wedged toothed ring being loosened, or in the event of the extraction of a slotted drill where part of the base has loosened and rests against the tooth ring and/or the teeth. This problem is particularly large when drilling in porous rock, where a part of the rock can loosen and wedge the slot drill.

The coupling may comprise fasteners taken from a group comprising screws, collets and wedges. A coupling comprising said fasteners can provide a simple and quick assembly and disassembly of the toothed ring using only simple hand tools. A screw connection makes it possible to fasten the toothed ring with a desired torque against the sleeve, and the screw connection can absorb both axial and radial forces. The screw can advantageously comprise an internal engagement part for a tool to protect the engagement part against wear and damage. Such screws are known as, for example, hex and torx. A collet is designed to absorb radial forces, and has the advantage that it can be attached and detached quickly and easily using an impact tool.

When drilling into the ground, a screw, sleeve or wedge described herein will be exposed to shear forces, as a torque is generated between the toothed ring and the sleeve. These shear forces can be reduced if the toothed ring is arranged to the first end part via a conical coupling part according to the invention.

Long-term tests carried out by the applicant show that the conical coupling part provides a significant reduction in vibrations and in particular so-called locking, which are vibrations that can occur when using long drills. The conical coupling part means that the axial drilling force can be increased, so that the progress in the drilling can also be increased. The reason for this beneficial effect is believed to be the wedge effect achieved by the conical coupling part and that the conical coupling part between the sleeve and the toothed ring provides a stiffer coupling than with alternative solutions.

The fastening means can be arranged in the end part of the sleeve. The sleeve may have a thickness which enables the arrangement of an axial thread portion for a screw which is suitable for screwing the toothed ring to the sleeve. The toothed ring can advantageously have a thickness that is equal to or greater than said screw's diameter, in order thereby to provide the screw with radial protection during drilling. The toothed ring may comprise a recess or recess designed to protect the screw during drilling. The recess can be open or closed. An open recess enables the use of an axial fastening tool, for example a straight screwdriver or screw drill. A closed recess requires the use of a radial fastening tool, for example a spanner or an angled Allen key.

The locking element may comprise a coupling body. The coupling body can be designed to accommodate both an axial and a radial force. The coupling body can be a body with an outer shape that is complementary to a recess in the sleeve and the toothed ring and thereby locks the sleeve and the toothed ring to each other. The coupling body can be locked to the sleeve and the toothed ring by means of a press fit, a set screw or another suitable locking device.

The sleeve's first end portion and the toothed ring may comprise a complementary toothing arranged to prevent a relative rotation between the sleeve and the toothed ring. A toothing as described can transfer a torque from the sleeve to the toothed ring when drilling, thereby reducing the forces applied to the fasteners. This is particularly advantageous if the toothed ring is attached to the sleeve with axially arranged screws, where a serration can reduce or eliminate the shearing forces on the screws.

The tooth ring can comprise several detachable teeth. The effect of removable teeth is that broken teeth can be replaced, while the other teeth can be kept. If a tooth is destroyed, a first tooth ring that includes the broken tooth can be replaced with a new second tooth ring. Second, the first toothed ring can be repaired while the second toothed ring is in use.

In another aspect, the invention relates to an assembly comprising a slotting drill according to the invention, and a drive unit, where the slotting drill is connected to the drive unit. The drive unit is arranged to rotate the slot drill in at least one direction. The drive unit may be a drilling rig, a drill or other device adapted to rotate the slot drill.

Execution example

In what follows, examples of preferred embodiments are described which are illustrated in the accompanying drawings. For the record, it is noted that figures 1 and 14-19 describe the first aspect of the invention. Figures 4-7 and 12-13 show solutions which can be combined with the first aspect of the invention. Figures 2-3 and 8-11 show solutions on which the invention is built, but which cannot be combined with the first aspect of the invention:

Fig.1 shows a slot drill according to the invention with a first connection of a toothed ring;

Fig.2 shows on a larger scale the connection in figure 1;

Fig.3. shows a section of Figure 2;

Fig.4 shows a slot drill with a second coupling of the toothed ring;

Fig.5 shows on a larger scale a section of the toothed ring in figure 4;

Fig.6 shows on a larger scale the second connection;

Fig.7 shows a section of figure 6;

Fig.8 shows a third connection of the toothed ring;

Fig.9 shows a section of figure 8;

Fig.10 shows a fourth connection of the toothed ring;

Fig. 11 shows a section of figure 10;

Fig.12 shows a fifth connection of the toothed ring;

Fig.13 shows a section of figure 12.

Fig.14 shows a sixth connection of the toothed ring;

Fig. 15 shows a first section of figure 14;

Fig. 16 shows a second section of figure 14;

Fig.17 shows an alternative embodiment of the sixth connection shown in figure 16.

Fig. 18 shows on a smaller scale a toothed ring as shown in figure 14; and

Fig.19 shows a section of figure 18 on a larger scale.

Figure 1 shows a slot drill 1 according to the invention, where the slot drill 1 is in an operative position in a ground 99. The slot drill 1 comprises a sleeve 2 and a toothed ring 3. The toothed ring 3 is rotatably and releasably attached to the sleeve 2 via a first coupling 4a . The slot drill comprises a plurality of connectors 4a. The slot drill 1 is arranged to a drilling rig 5 comprising a drive unit 51 and a lifting device 52 arranged to raise and lower the slot drill 1. The couplings 4 are arranged to absorb a force F1 which is greater than the lifting device 52's maximum lifting force F2.

Figures 2 and 3 respectively show from the side and in a cross-section A-A the coupling 4a. The sleeve 2 is provided with an end surface 21 and an internal threaded portion 23. The toothed ring 3 is provided with a corresponding end surface 31 and a continuous recess 33. A tooth 35 is attached to the toothed ring 3. A screw 12 is threaded through the toothed ring 3's recess 33 and screwed fixed in the threaded portion 23. The head diameter 12d of the screw 12 is smaller than the thickness 3d of the toothed ring, and the height of the screw 12h is smaller than the height of the tooth body 40h. In turn, the screw head is protected in a tangential direction when drilling.

Figure 4 shows a slot drill 2 with a second coupling 4b. The sleeve 2 and the toothed ring 3 are provided with a corresponding toothing 29, 39. The toothed ring 3 is releasably attached to the sleeve 2 via the coupling 4b. The coupling 4b comprises an axially arranged screw 12, shown in Figures 6 and 7.

Figure 5 shows on a larger scale a cross section of the toothed ring in Figure 4. The toothed ring 3 is provided with six axial recesses 34 and six corresponding radial recesses 33. The axial recesses 34 are arranged to receive and enclose the screw 12, shown in Figure 4. The the radial recesses are designed to protect the screw 12. The recess 33 provides a movement angle A1 for a fastening tool. A wider recess 33 can provide a wider movement angle A2. See Figures 6 and 7 for more details.

Figures 6 and 7 show on a larger scale the second coupling 4b shown in Figures 4 and 5, respectively from the side and in a section C-C. The recess 34 has a size and shape that makes it possible to thread the screw 12 through the recess 33 and then screw the screw 12 to the sleeve 22 with a tool. The tooth 35 is attached to the sleeve 3.

Figures 8 and 9 show a third connection 4c, respectively from the side and a section D-D. The toothed ring 3 is threaded onto the outside of the sleeve 2 and secured with a radially arranged countersunk screw 13. The end surface 31 of the toothed ring 3 is designed to rest against the end surface 21 of the sleeve 2. The tooth 35 is attached to the sleeve 3.

Figures 10 and 11 show a fourth connection 4d, respectively from the side and a section E-E. The fourth coupling 4d is in principle similar to the third coupling 4c, with the difference that the countersunk screw 13 is replaced by a clamping sleeve 14. Figures 9 and 10 further show a detachable tooth 36, attached to the toothed ring with two screws 37.

Figures 12 and 13 show a fifth coupling 4e, respectively from the side and a section F-F. The fifth coupling 4e comprises a coupling body 16 which is locked to the sleeve 2 and the toothed ring 3 by means of two set screws 15. In order to prevent a relative movement between the sleeve 2 and the toothed ring 3, a slot drill 1 provided with coupling bodies 16 should comprise at least three coupling bodies 16 arranged evenly distributed along the 1 circumference of the slotted drill. The tooth 35 is attached to the sleeve 3.

Figures 14 - 16 show a sixth link 4f, respectively from the side and a section G-G and a section H-H. The sleeve 2 and the toothed ring 3 are provided with a conical coupling part 60, where the toothed ring 3 has a protrusion 63 with two converging side surfaces 64 and the sleeve 2 has a groove 61 with two complementary side surfaces 62, and where the protrusion 63 and the groove 61 are arranged to move in engagement with each other

The conical coupling part 60 is designed so that an axial clearance 61 is created between the top of the protrusion 63 and the bottom of the groove 61. This ensures the greatest possible contact between the inclined surfaces 62, 64.

When the screw 12 (figure 15) is attracted, the surface pressure and thus the friction between the first and the second inclined surface 62, 63 will increase.

Figure 17 shows an alternative embodiment of the conical coupling part shown in Figures 14-16, the protrusion 64 being arranged for the sleeve 2 and the groove 61 being arranged for the toothed ring 3.

Figure 18 shows the tooth ring in figures 14-16 in perspective.

Figure 19 shows a section of Figure 18.

It should be noted that all of the above embodiments illustrate the invention, but do not limit it, and those skilled in the art will be able to devise many alternative embodiments without departing from the scope of the appended claims. In the requirements, reference numbers in parentheses should not be seen as limiting.

The use of the verb "to comprise" and its various forms does not exclude the presence of elements or steps not mentioned in the claims. The indefinite articles "an", "ei" or "et" before an element do not exclude the presence of several such elements.

The fact that certain features are listed in different mutually dependent claims does not indicate that a combination of these features cannot be advantageously used.

Claims (9)

Patent claims 1. Slotted drill (1) designed for drilling in the ground (99), where the slotted drill (1) comprises: - a sleeve (2) with a first end part (22); and - a toothed ring (3) which is rotationally rigid, releasably attached to the first end part (22), characterized by the fact that one of the sleeve (2) and the toothed ring (3) has a groove (61) with two converging side surfaces (62) and the other of the sleeve (2) and the toothed ring (3) has a protrusion (63) with two complementary side surfaces (64) and the groove (61) and the protrusion (63) are arranged to engage with each other. 2. Slotted drill (1) according to claim 1, where the protrusion (63) is arranged for the toothed ring (3). 3. Slotting drill (1) according to claims 1-2, where the toothed ring (3) is releasably attached to the sleeve (2) via a coupling (4) designed to absorb an axial force (F1) that is greater than an axial lifting force (F2) required to lift the slot drill (1) out of the base (99), where the coupling (4) is located between the first end part (22) of the sleeve (2) and the toothed ring (3). 4. Slotting drill (1) according to any of the preceding claims, where the coupling (4) comprises fasteners taken from a group comprising screws, collets and wedges. 5. Slotted drill according to any of the foregoing, where the fastening means is arranged in a recess in the end surface of the sleeve (21). 6. Slotting drill (1) according to one of claims 3-5, where the coupling (4) comprises a coupling body (16). 7. Slotting drill (1) according to any of the preceding claims, where the first end part (22) of the sleeve (2) and the toothed ring (3) comprise a complementary toothing (29, 39) arranged to prevent a relative rotation between the sleeve (2) and the toothed ring (3). 8. Slotting drill (1) according to any of the preceding claims, where the toothed ring (3) comprises several detachable teeth (36). 9. Assembly comprising a slot drill (1) according to claim 1, and a drive unit (51), where the slot drill (1) is connected to the drive unit (51). P28213NO01 description and requirements