GB2405606A - Self-centering drill bit with pilot tip - Google Patents

Abstract

An elongate drill bit (20) with a longitudinal axis (X-X), the drill bit comprising a shank (28), a working end (24), and a fluted section (26) located between the shank and the working end, wherein the shank, the working end and the fluted section are all formed integrally in the drill bit, wherein the working end comprises an outer cutting portion (34) and a central pilot tip (36) extending axially ahead of the outer cutting portion, wherein the pilot tip is formed with at least one pair of minor cutting edges (40, 42; 44, 46) arranged on opposite sides of the axis, and the outer cutting portion is formed with a pair of major cutting edges (70, 72) arranged on opposite sides of the axis, wherein the outer cutting portion has a major diameter (D) defined by the pair of major cutting edges and the pilot tip has a minor diameter (d) defined by the at least one pair of minor cutting edges, wherein the fluted section has a pair of helical lands (32) each with a respective inner surface (92) extending axially rearward from one of the major cutting edges and from one of the minor cutting edges, wherein the helical lands define a web (94) and each helical land defines a respective helical flute (30), wherein the helical lands have a pitch (S) and the web has a web thickness (K) at the pilot tip, characterised in that the ratio of pitch to major diameter (S:D) falls within a range of 380% to 410% and the ratio of minor diameter to web thickness at the pilot tip (d:K) falls within a range of 220% to 380%.

Description

IMPROVED SELF-CENTERING DRILL BIT

WITH PILOT TIP

The present invention relates to a drill bit for cutting accurately formed round holes of uniform diameter through wood, metal and plastics.

One of the most commonly used drill bits for drilling through metal is a twist drill formed with a chisel edge at the working end of the drill. The chisel edge is formed perpendicular to the axis of the drill and usually extends across a small portion of the drill bit diameter and equally on opposite sides of the drill bit axis. A cutting edge extends from each opposite end of the chisel edge and tapers axially rearward to the outer periphery of the drill bit diameter. In use, the chisel edge is the first portion of the drill bit to engage a workpiece. The chisel edge engages the workplace and literally works and extrudes the material in the immediate vicinity rather than forming chips, swarf, sawdust and the like for extraction. The worked material permits the drill bit to begin to move into the material of the workplace whereby the cutting edges begin to cut the material to form removable chips which are discharged via helical flutes running axially rearward from the chisel edge and the cutting edges.

While a drill bit with a chisel edge is satisfactory for some drilling operations, it does not provide holes with accurately located centres or round holes. For example, it tends to "skip" away from the desired location of the hole as the rotating chisel edge engages the workpiece. Further, any out-of-round characteristic of the drill bit or the tool holder connected to the shank of the drill bit is transmitted to the working end while drilling the hole. In addition, a drill bit with a chisel edge typically has a relatively large core, or web, which is slightly less than the length of the chisel edge.

Drill bits with a large web require significant thrust in order to urge the drill bit into the workpiece. A larger web also limits the effective space for chip removal through the helical flutes, the radial depth of which is determined by the web thickness.

Patent publication No. EP0315643 discloses a drill bit having a pilot tip extending axially ahead of an outer cutting portion. The pilot tip has a smaller diameter than the outer cutting portion. In use, the pilot tip cuts a pilot hole which P-UK-AC 1 045 a *e . C . . ee. e. e e . . . self-centres the drill bit. Next, the outer cutting portion cuts a main hole in the workpiece which corresponds to the diameter of the drill bit.

A drill bit sold by the Applicant under the registered trade mark EXTREME 2 (hereinafter referred to as the EXTREME 2 drill bit) also has a pilot tip extending axially ahead of an outer cutting portion. The pilot tip has a split point cutting edge arrangement for cutting the self-centering pilot hole and the outer cutting portion has a pair of major cutting edges arranged on opposite sides of the axis for cutting the primary hole. The split point has two inner minor cutting edges arranged on opposite sides of the axis and spaced apart and connected at the extreme tip of the split point by a slight chisel edge. The split point also has an outer minor cutting edge extending from the end of each inner minor cutting edge and tapering axially rearward to the outer periphery of the pilot tip. In use, the two inner minor cutting edges engage a workpiece to initiate the drilling operation slightly in advance of the engagement of the workpiece by the outer minor cutting edges. The chisel edge does not work or extrude the material in its immediate vicinity, like in the case of the common twist drill mentioned above, because the chisel edge is insignificantly small. The chips created by the inner and the outer minor cutting edges are separate from each other and are therefore smaller in size.

Once the pilot tip has begun drilling the self-centering pilot hole, the major cutting edges of the outer cutting portion engage the workpiece and create chips which are also separate from those created by the cutting edges of the pilot tip. This arrangement produces smaller chips during the drilling operation which reduces resistance to the passage of the drill bit through the workpiece as the drilling process progresses. The drill bit has debris channels in the form a pair of helical flutes for transporting the chips away from the cutting edges and out of the hole being drilled in the workpiece. Smaller chips are naturally easier to convey along the flutes and are less likely to clog up the flutes. A clogged flute creates the problem of significantly increased resistance to the passage of the drill bit through the workpiece. Deeper flutes transport such chips and other debris more easily and are less prone to clogging. However, deeper flutes also result in a thinner web that reduces the strength of the dill bit. A compromise is met by a web tapering radially outwardly and axially rearward from the pilot tip of the working end towards the drill bit shank. This P-UK-AC] 045 . ë e . . en- .. e . @ provides deeper flutes in the region of the working end where efficient debris removal is most important, whilst providing a thicker web towards the shank where robustness and strength is important. The EXTREME 2 drill bit has a tapering web with a thickness increasing from the tip portion to the shank portion at a uniform taper rate.

It is an object of the present invention to maintain the robustness and self centering capabilities of the EXTREME 2 drill bit whilst improving its drilling speed.

This is achieved by elongate drill bit with a longitudinal axis, the drill bit comprising a shank, a working end and a fluted section located between the shank and the working end, wherein the shank, the working end and the fluted section all formed integrally in the drill bit, wherein the working end comprises an outer cutting portion and a central pilot tip extending axially ahead of the outer cutting portion, wherein the pilot tip is formed with at least one pair of minor cutting edges arranged on opposite sides of the axis, and the outer cutting portion is formed with a pair of major cutting edges arranged on opposite sides of the axis, wherein the outer cutting portion has a major diameter D defined by the pair of major cutting edges and the pilot tip has a minor diameter d defined by the at least one pair of minor cutting edges, wherein the fluted section has a pair of helical lands each with a respective inner surface extending axially rearward from one of the major cutting edges and from one of the minor cutting edges, wherein the helical lands define a tapering web and each helical land defines a respective helical flute, wherein the helical lands have a pitch S and the web has a web thickness K at the pilot tip, characterized in that the ratio of pitch to major diameter S:D falls within a range of 380% to 410% and the ratio of minor diameter to web thickness d:K at the at the pilot tip falls within a range of 220% to 380%.

The drill bit of the present invention has a greater minor diameter and smaller web thickness at the pilot tip than an EXTREME 2 drill bit with an equivalent major diameter. The increased minor diameter compensates for the reduced web thickness thereby maintaining the strength of the pilot tip.

Further, the helical lands of drill bit of the present invention have a smaller pitch than an EXTREME 2 drill bit with an equivalent major diameter. This results in a corresponding increase in the helix angle of the helical lands' inner surfaces which P-UK-AC1045 . . se ccece C C - reduces the cutting angle of both the major and minor cutting edges. Therefore, in use, the drill bit of the present invention can drill a hole in a workplace more rapidly since these cutting edges are sharper. In some tests, the drill bit according to the present invention can cut a hole in certain workplaces twice as fast as the EXTREME 2 drill bit. However, faster drill bit are more likely form burrs at the exit mouth of a hole drilled in the workplace because they often push a final chip out of the way rather than allowing the cutting edges the time to cleanly cut the final chip before it becomes a burr.

Burrs are undesirable because they are sharp and unsightly remains of the drilling operation attached to the exit mouth of the hole. However, the deep flutes formed by the reduced web thickness at the pilot tip counteracts this risk of forming burrs by providing extra space in front of the major cutting edges so that a bigger final chip is formed as the drilling operation is completed. There is always a risk that the final chip cut will remain partially attached to the workplace around the exit mouth of the hole as the drill bit advances. However, a bigger final chip will have greater strength and remain in place as the outer cutting portion advances so that they can be cleanly cut away by the major cutting edges without forming burrs. Further, the thickness of each land is reduced by the reduction of the web thickness at the pilot tip. This results in a sharpening of an edge defining the boundary between each flute and the respective trailing land in the region of the pilot tip. This sharpened edge helps cut away and any final chips missed by the major cutting edges to avoid them becoming burrs.

The present invention is based on the existing EXTREME 2 drill bit with changes made to the pitch of the helical lands, to the thickness of the web taper in the region of the pilot tip and to the minor diameter of the pilot tip. The effect of such changes, taken each in isolation, may be common knowledge in the field of drill bit technology. However, combined effect of these changes on the drill bit according to the present invention, as defined by claim 1, has the surprising result of significantly improving its drilling speed without the reducing its strength or increasing the likelihood of creating burrs at the exit mouth of the hole drilled in a workpiece.

P-UK-AC1 045 ë.

C C

ë C - . C An embodiment of the present invention shall now be described with reference to the accompanying drawings of which: Figure 1 is a side elevational view of a drill bit according to the present invention; Figure 2 is a perspective view of a working end of the drill bit of Figure 1 from one side; Figure 3 is a perspective view of the working end of the drill bit of Figure 1 from another side; Figure 4 is a plan view of the drill bit of Figure 1; Figure 5 is a side elevational schematic view of the working end of the drill bit of Figure 1; Figure 6 is a side elevational schematic view of the working end of the drill bit of Figure 5 rotated through 90 ; Figure 7 is a section along the line Z-Z through a pilot tip of the working end of the drill bit of Figure 6; and Figure 8 is a schematic side view of a web taper rate of the drill bit of Figure 1.

Referring to Figure 1, there is shown a drill bit 20 for cutting a variety of material such as metal, wood, plastics, plastics, piping and tubing. The drill bit 20 has a longitudinal axis X-X and is composed of high-speed steel. The drill bit 20 comprises a shank end 22, a working end 24 and a fluted section 26 interposed between the shank end and the working end. The shank end 22 includes a substantially cylindrical shank 28 that extends from one end of the drill bit 20 to the fluted section 26. The shank 28 is for connection to a tool holder (not shown) of a power tool. Optionally, the shank 28 may have a plurality of axially parallel flat chamfers arranged equi-angularly around its circumference for improved connection with a tool holder of a power tool. The fluted section 26 is formed with a pair of helical flutes 30 defined by a pair of helical lands 32 formed at a prescribed helix angle a measured with respect to the axis X-X. The helical flutes 30 and the helical lands 32 extend axially rearward from the working end 24 to the shank 28 and each have a pitch S. The pitch S is controlled by the helix angle a. The helix angle a falls within a range of 37 to 40 .

P-UK-AC1045 . . ce :. :. . Referring to figures 2 to 5, the working end 24 includes an outer cutting portion 34 with a major diameter D and a pilot tip 36 with a minor diameter d that is smaller than the major diameter D. The pilot tip 36 is formed integrally with and extends a short distance L1 axially ahead of the outer cutting portion 34. The pilot tip 36 has at its extreme end 38 a split point cutting edge arrangement formed with a pair of inner minor cutting edges 40, 42 separated by a slight chisel edge 38 extending therebetween. The chisel edge 38 is perpendicular to the axis X-X. The split point is also formed with a pair of outer minor cutting edges 44, 46 each tapering radially outwardly from a respective inner minor cutting edge 40, 42 to the periphery of the minor diameter d of the pilot tip 36. The split point is also formed with a pair of minor relief faces 48, 50 each formed behind a respective pair of leading inner and outer minor cutting edges 40, 44; 42, 46 (in the direction of rotation R) to provide! relief behind these cutting edges. Each inner minor cutting edge 40, 42 forms a boundary between a leading rake face 52, 54 and a respective trailing minor relief face 48, 50 (in the direction of rotation R).

The pilot tip 36 is also formed with a pair of rounded outer surface 56, 58 each extending axially rearward on opposite sides of the pilot tip 36. The outer surface 56 is formed with a forward edge 60 and a trailing edge 62 (in the direction of rotation R). The outer surface 58 is formed with a forward edge 64 and a trailing edge 66 (in the direction of rotation R).

When viewed from above, as shown in figure 4, the outer surfaces 56, 58 are generally rounded but are also curved radially inwardly as the outer surfaces extend from a respective forward edge 60, 64 to a respective trailing edge 62, 66. This is clearly shown in figure 7, where the outer surfaces 56, 58 curve radially inwardly of a true circle represented by dashed line 68 thereby creating a radial relief RR.

Accordingly, the outer surfaces 56, 58 each provide relief behind a respective forward edge 60, 64.

When viewed from the side, as shown in figure 5, the outer surfaces 58, 60 are generally straight but are also slightly tapered radially inwardly as the outer surfaces extend axially rearward. The rearward taper T of each outer surface 56, 58 P-UK-AC1045 te # e e C C is approximately 1 to 3 measured from a plane parallel to the axis X-X. Accordingly, the outer surfaces 56, 58 also provide relief behind the pilot tip 36.

Returning to Figures 2 to 5, the outer cutting portion 34 is formed with a pair of major cutting edges 70, 72 each with a respective trailing major relief face 74, 76 (in the direction of rotation R). Each major cutting edge 72 runs radially inwardly in a straight line from the periphery of the major diameter D towards the pilot tip 36. In the region adjacent the pilot tip 36 the major cutting edge 70 begins to curve towards the working end 24 to form a radius at a forward edge 78 of a fillet 80 where the major cutting edge 70 merges with the forward edge 60 of the outer surface 56.

Likewise, the major cutting edge 72 extends from the periphery of the major diameter D towards the pilot tip 32 and eventually curves in an identical manner into a radius at a forward edge 82 of a fillet 84 where the major cutting edge 72 merges with the forward edge 64 of the outer surface 58.

Each fillet 80, 84 begins at a respective forward edge 78, 82 with a relatively large radius and extends rearward in a curved path from the respective forward edge 78, 82, wherein the radius becomes progressively smaller until each fillet terminates in an approximately right-angle shaped corner 86, 88, respectively. In addition, each fillet 80, 84 extends radially inward from the respective forward edge 78, 82 to a respective trailing corner 86, 88 in the same manner as the rounded outer surfaces 56, 58. Accordingly, the fillets 80, 84 create relief behind the forward edges 78, 82.

As discussed above, relief is provided behind the edges mentioned above.

For example, the major relief face 74, the fillet 80, and the outer surface 56 which trail the major cutting edge 70, the fillet forward edge 78 and the pilot tip forward edge 60, respectively, to create relief behind these edges in the manner described above so that, when the drill bit 20 is used to drill a hole in a workpiece, these trailing surfaces did not engage and rub against the walls of the hole. Similarly, the major relief face 76, the fillet 84, and the outer surface 58 which trail the major cutting edge 72, the fillet forward edge 82 and the pilot tip forward edge 64, respectively, also create relief behind these edges so that, when the drill bit 20 is used to drill a hole in a workpiece, these trailing surfaces did not engage and rub against the walls of the hole.

P-UK-AC1045 d d d d a d ' C a .ec. aa a a - As is shown in figure 2, each helical land 32 has a helical margin 90 on a leading edge 91 (in the direction of rotation R) of its circumferential outer face. The margin 90 protrudes radially slightly beyond the circumferential outer face of a respective land 26 and is narrower than the circumferential outer face. The helix defined by each margin 90 has the major diameter D. The margins 90 engage the walls of the hole to provide support to the drill bit 20 as it drills into a workpiece.

Friction between the walls of the hole and the drill bit 20 is thereby reduced because the margins 90 are have a smaller surface area than the circumferential outer faces of the lands 26.

Referring to figure 6, a major relief angle RA of each major relief face 74, 76 is measured from a plane perpendicular to the axis X-X. The major relief angle RA falls within a range of 8 to 12 for those drill bits with a major diameter D of less than 8mm. The major relief angle RA falls within a range of 7 to 12 for those drill bits with a major diameter D of greater than 8mm.

Each helical land 32 has an inner surface 92 that defines the shape of a respective flute 34. Each land inner surface 92 extends axially rearward from a respective outer minor cutting edge 44, 46 and a respective major cutting edge 70, 72. Each outer minor cutting edge 44, 46 forms a boundary between a respective land inner surface 92 and a respective minor relief face 48, 50. Likewise, each major cutting edge 70, 72 forms a boundary between a respective land inner surface 92 and a respective major relief face 74, 76. The land inner surfaces 92 act as a rake face to both the outer minor cutting edges 44, 46 and the major cutting edges 70, 72.

Accordingly, the land inner surfaces 92 each effectively have a rake face angle CA, as measured from a plane parallel to the axis X-X, that is equal to the helix angle a.

The cutting angle of the major cutting edges 70, 74 equals 90 - (CA + RA) . The cutting angle of the outer minor cutting edges 44, 46 equals 90 (CA + the relief angle of the minor relief face 48, 50).

Referring to figures 7 and 8, the drill bit 20 has a core, or web, 94 extending from the working end 24 to where the fluted section 26 joins the shank 28. The web 94 is defined by the helical lands 32. The web 94 is shown in dashed lines and tapers P-UK-AC1 045 . e . c c.

c c rue cee ce radially outwardly as it extends axially rearward from the working end 24. The web 94 has a thickness K at the pilot tip 36 and a thickness J near where the fluted section I 26 joins the shank 28. The web 94 has a uniform web thickness taper rate along a length L2 between the pilot tip 36 and the point on the web 94 at which web thickness J is measured. The web thickness K is selected to provide suitably deep flutes 34 to convey, in use, debris and chips from the pilot tip 36 and out of the hole.

The smaller the web thickness K the greater depth of the flutes 34 at the pilot tip 36.

The web thickness J and the web length L2 are selected to provide a suitably strong drill bit 20.

Returning to figure 5, the split point cutting edge arrangement of the pilot tip 36 is formed with a point angle PP defined by inner minor cutting edges 40, 42. The pilot point angle PP falls within the range of 130 to 140 . The outer portion 36 is formed with an outer point angle OP defined by the major cutting edges 70, 72 which t falls within the range of 160 to 182 . The length L1 of the pilot tip 36 falls within the range of 30% to 45% of the major diameter D. The dimensions of the drill bit 20 change over the range major diameters D. Certain dimensions, in particular those already mentioned above, vary only a small I amount over the range of the major diameters D or remain constant, albeit within a I certain tolerance band. Other dimensions, in particular, the pitch S of the helical lands 32, the minor diameter d, the web thickness K, the web thickness J and the web length L2 change significantly over the range of major diameters D and these dimensions of the drill bit 20 are summarised in Table 1 below. Changes to such dimensions have a consequential effect on other features of the drill bit 20 such as the ratio between minor diameter d and the web thickness K (wherein d is expressed as a percentage of K), the ratio between the pitch S and the major diameter D (wherein S is expressed as a percentage of D), and the web taper rate, all of which; are also included in Table 1.

The EXTREME 2 drill bit has the same basic shape as the drill bit 20 and has many dimensions in common, in particular those mentioned in the passages above.

However, certain of its important dimensions of the EXTREME 2 drill bit not only; change over the range of major diameters D but also change with respect to the P-UK-AC1045 e..e as e e q a e e e c e _ q e ee,e.

e ee e a r' e e e. e corresponding dimensions of the drill bit 20. These dimensions are all summarised in Table 2 below and serve to compare features of the EXTREME 2 drill bit with those of the drill bit 20 so as to explain the latter's improved performance.

P-UK-AC1 045 . . . .. te. . A. ''- Table 1: Drill bit 20.

D D S Ratio d K Ratio L2 L2 J |Web Taper | (Inch) (mm) (mm) S:D (mm) (mm) d:K (mm) (% of D) (mm) (mm/mm) 1/8 317512.5 394% 1.9 0.81 234.6% 24 756% 2.4 0.066 9/64 3.57214 392% 2.15 0.84 256.0% 26 728% 2.6 0.068 5/32 3.96915.5 391 % 2.38 0.86 276.7% 33 831 % 3.05 0.066 11/64 4.36617 389% 2.59 088 294.3% 35 802% 3.2 0.066 3/16 4.76319 399% 2.78 0.91 305.5% 39 819% 3.6 0.069 13/64 5.159 20.5 397% 2.95 0.93 317.2% 42 814% 3.75 0067 7/32 5.556 22 396% 3.11 0.95 327.4% 43 774% 3.9 0.069 15/64 5.953 23.5 395% 326 0.98 332.7% 46 773% 4.1 0.068 1/4 6.353 25 394% 3.4 1 340.0% 48 756% 4.25 0068 17/64 6.747 26.5 393% 3.53 1.02 346.1 % 50 741 % 4.6 0.072 9/32 7.14428 392% 3.65 1.05 347.6% 53 742% 4.7 0.069 19/64 7.54130 398% 3.77 1.07 352.3% 55 729% 4.9 0.070 5/16 7.93831 391 % 3.88 1 09 356.0% 59 743% 5.1 0.068 21/64 8.33433 396% 3.99 1.12 356 3% 62 744% 5.3 0.067 11/32 8.73134.5 395% 4.09 1.14 358.8% 64 733% 5.5 0.068 23/64 9.12836 394% 4.19 1.17 358.1 % 67 734% 5.6 0.066 3/8 9.525 37.5 394% 4.28 1.19 359.7% 69 724% 5.8 0.067 25/64 9.922 39 393% 4.37 1.21 361.2% 69 695% 6.55 0.077 13/32 10.319 40.5 392% 4.45 1.24 358.9% 72 698% 6.8 0.077 27/64 10.716 42 392% 4.53 1.26 359.5% 74 691 % 6.9 0.076 7/16 11.113 44 396% 4.61 1.28 360.2% 78 702% 7.1 0.075 29/64 11.509 45.5 395% 4.69 1.31 358.0% 80 695% 7.3 0.075 15/32 11.906 47 395% 4.76 1.33 357.9% 83 697% 7.6 0.076 31 /64 12.303 48.5 394% 4.83 1.35 357.8% 87 707% 7.7 0.073 1 /2 12.7 50 394% 4.9 1.38 355.1 % 89 701 % 7.3 0.067 ë . ë a:. .e.; Table 2: EXTREME 2 drill bit.

D D S |Ratio |d K Ratio L2 L2 J Web Taper (Inch) (mm) (mm) S:D (mm) (mm) d:K (mm) (% of D) (mm) (mm/mm) 1/8 3.175 18 567% 1.7 0.95 178.9% 24 756% 2 4 0.060 9/64 3.572 20 560% 1.831 183.0% 26 728% 2.6 0.062 5/32 3.969 22 554% 2.031.1 184.5% 33 831 % 3.05 0.059 11 /64 4.366 24 550% 2.211.15 192.2% 35 802% 3.2 0.059 3/16 4.763 26 546% 2.391.3 183.8% 39 819% 3.6 0.059 13/64 5.159 28 543% 2.541.3 195.4% 42 814% 3.75 0.058 7/32 5.556 29 522% 2.741.4 195.7% 43 774% 3.9 0.058 15/64 5.953 31 521 % 2.951.45 203.4% 46 773% 4.1 0.058 1 /4 6.353 33 519% 3.12 1.5 208.0% 48 756% 4.25 0.057 17/64 6.747 35 519% 3.2 1.6 200.0% 50 741 % 4.6 0.060 9/32 7.144 37 518% 3.3 1.65 200.0% 53 742% 4.7 0.058 19/64 7.541 38 504% 3.38 1.7 198.8% 55 729% 4.9 0.058 5/16 7 938 40 504% 3.43 1.75 196.0% 59 743% 5.1 0.057 21 /64 8.334 42 504% 3.43 1.8 190.6% 62 744% 5.3 0.056 11/32 8.731 44 504% 3.45 1.85 186.5% 64 733% 5.5 0.057 23/64 9.128 46 504% 3.58 1.85 193.5% 67 734% 5.6 0.056 3/8 9.525 48 504% 3.66 1.9 192.6% 69 724% 5.8 0.057 25/64 9.922 50 504% 3.78 1.95 193.8% 69 695% 6.55 0.067 13/32 10.319 50 485% 3.94 2 197.0% 72 698% 6.8 0.067 27/64 10.716 52 485% 4.09 2 204.5% 74 691 % 6.9 0.066 7/16 11.113 54 486% 4.24 2.05 206.8% 78 702% 7.1 0.065 29/64 11.509 56 487% 4.39 2.1 209.0% 80 695% 7.3 0.065 15/32 11 906 58 487% 5.52 2.2 250.9% 83 697% 7.6 0.065 31 /64 12.303 60 488% 4.67 2.2 212.3% 87 707% 7.7 0.06 1/2 12.7 61 480% 4.83 2.3 210.0% 89 701 % 7.3 0.056 . . A. ë:..e be. 't' . As is common in the technical field of drill bits, all of the dimensions shown in Tables 1 and 2 are subject to a tolerance of plus or minus 7% for drill bits with the smallest major diameter D ranging down to plus or minus 2% for drill bits with the greatest major diameter D. The inventor believes that, when considering these tolerances, the benefits of the present invention gained by a ratio of pitch to major diameter (S:D) falling within a range of 389% to 398% (as shown in Table 1) extend to a range of 380% to 410% and, the benefits gained by a ratio of minor diameter to web thickness at the at the pilot tip (d:K) falling within a range of 234.6% to 361.2% (as shown in Table 1) extend to a range of 220% to 380%.

A comparison between the data of Tables 1 and 2 shows that the web length L2 and the web thickness J of the drill bit 20 and the EXTREME 2 drill bit are equal across the range of major diameters D. Also, the webs of the drill bit 20 and the EXTREME 2 drill bit taper at constant rates. However, the web taper rate of the drill bit 20 falls within a range of 0. 066mm/mm (i.e. web thickness reduces by 0.066mm per mm of web length) to 0.077mm/mm, whereas the web taper rate of the EXTREME 2 drill bit falls within a range of 0.056 mm/mm to 0.062 mm/mm. This results in the drill bit 20 having a smaller web thickness K at the pilot tip 36 than the web thickness K of an EXTREME 2 drill bit with an equivalent major diameter D. This has the following two effects.

Firstly, the helical flutes 30 in the region of the pilot point 36 are deeper. This is significant because, during the drilling operation, the pilot tip 36 penetrates the opposite side of a workplace before the outer cutting portion 34. The part of the workplace behind the pilot tip 36 and in front of the outer cutting portion 34 is the final chip cut by the major cutting edges 70, 72 when the drilling operation is complete.

There is always a risk that the final chip cut will remain partially attached to the workplace around the mouth of the exit hole as the drill bit advances through the workpiece. This is called a burr, and burrs are undesirable if they remain attached to the workplace around the mouth of the exit hole because they are sharp and unsightly. Small chips have little strength and present little resistance to the advancing outer cutting portion 34 which, instead of cleanly cutting with its major cutting edges, simply bends the small chips out of its path so that they remain attached to the workplace and form the undesirable burrs. Whereas, bigger chips P-UK-AC1045 at, ; ! , t naturally have greater strength and remain in place as the outer cutting portion 34 advances so that they can be cleanly cut away by the major cutting edges 70, 72 without forming burrs. Therefore, the deep flute 30 of the drill bit 20 provides greater space to allow the formation of bigger final chips which are cut from the workplace to form a clean exit hole without burrs. Secondly, a reduced thickness of the circumferential outer face of each

land 32 is a direct result of the reduction of the web thickness K. This also results in a sharpening of the leading edge 91 which defines the boundary between each flute 30 and the margin 90 of a respective trailing land 32 (in the direction of rotation R) in the region of the pilot tip 36. The sharpened leading edges 91 help to cut away any final chips missed by the major cutting edges 70, 72 to avoid such chips becoming burrs at the mouth of the exit hole of the workpiece.

Further, the minor diameter d of the drill bit 20 is greater than the minor diameter d of an EXTREME 2 drill bit with an equivalent major diameter D. This maintains the strength of the pilot tip 36 by compensating for the reduced web thickness K mentioned above. It also reduces the length of the major cutting edges 70, 72 which results a smaller final chip and the attendant risk of forming burrs.

However, the deeper flutes 30 formed by the reduced web thickness K counteracts this risk of forming burrs.

Furthermore, the pitch S of the drill bit 20 is smaller than the pitch S of an EXTREME 2 drill bit with an equivalent major diameter D. The pitch S of the drill bit 20 falls within a range of 380% to 410% of the major diameter D (allowing for normal tolerances), whereas the pitch S of the EXTREME 2 drill bit falls within a range of 470% to 580% (allowing for normal tolerances) of the major diameter D. Naturally, this results in more helical revolutions of the helical lands 32 and flutes 30 of the drill bit 20 per unit length of the fluted section 26 and a corresponding increase in the helix angle a. This reduces the cutting angle of both the outer minor cutting edges 44, 46 and the major cutting edges 70, 72 since the angles of inclination of the trailing minor relief faces 48, 50 and the major relief faces 74, 76, respectively, remain unchanged. In use, the drill bit 20 can drill a hole in a workplace more rapidly since the outer minor and the major cutting edges 44, 46; 70, 72 are more sharp. However, P-UK-AC] 045 :: :e .

e:. .. c: t. :: ! a faster drill bit is more likely to push a final chip out of the way rather than allowing the major cutting edges 7O, 72 the time to cleanly cut it from the workplace before it becomes a burr. Again, the deeper flutes 30 formed by the reduced web thickness K counteracts this risk of forming burrs.

P-UK-AC1 045

Claims (1)

1. ;.. ce. :. A. r:] . .

   1. An elongate drill bit (20) with a longitudinal axis X-X, the drill bit comprising: a shank (28); a working end (24); and a fluted section (26) located between the shank and the working end, wherein the shank, the working end and the fluted section all formed integrally in the drill bit, wherein the working end comprises an outer cutting portion (34) and a central pilot tip (36) extending axially ahead of the outer cutting portion, wherein the pilot tip is formed with at least one pair of minor cutting edges (40, 42; 44, 46) arranged on opposite sides of the axis X-X, and the outer cutting portion is formed with a pair of major cutting edges (70, 72) arranged on opposite sides of the axis, wherein the outer cutting portion has a major diameter (D) defined by the pair of major cutting edges and the pilot tip has a minor diameter (d) defined by the at least one pair of minor cutting edges, wherein the fluted section has a pair of helical lands (32) each with a respective inner surface (92) extending axially rearward from one of the major cutting edges and from one of the minor cutting edges, wherein the helical lands define a tapering web (94) and each helical land defines a respective helical flute (30), wherein the helical lands have a pitch (S) and the web has a web thickness (K) at the pilot tip, characterized in that the ratio of pitch to major diameter (S:D) falls within a range of 380% to 410% and the ratio of minor diameter to web thickness at the at the pilot tip (d:K) falls within a range of 220% to 380%.

   P UK-AC1045