WO1999038661A1

WO1999038661A1 - Improved tooth form for a saw blade

Info

Publication number: WO1999038661A1
Application number: PCT/US1999/002113
Authority: WO
Inventors: William B. Korb; John Miilton-Benoit; Stephen Hampton; James Holsten
Original assignee: American Saw & Mfg. Company
Priority date: 1998-01-29
Filing date: 1999-01-29
Publication date: 1999-08-05
Also published as: CA2320904C; JP4139876B2; EP1105265B1; US6167792B1; JP2002501841A; AU2488999A; EP1105265A1; EP1105265A4; CA2320904A1

Abstract

In a saw blade (10) having a cutting edge defined by a plurality of teeth (12) disposed along the blade, each tooth includes a tip (14), a rake face (16), and a curvilinear base surface (20). The tip of each tooth and the tip of the next consecutively disposed tooth cooperate to define a pitch distance (P) therebetween, with the curvilinear base surface and the tip of each tooth cooperating to define a maximum gullet depth (H). In addition, the rake face and the curvilinear base surface of each tooth define an effective gullet radius (Reff) greater than about 25 % of the pitch distance, and also greater than about 55 % of the maximum gullet depth.

Description

Improved Tooth Form For A Saw Blade

Cross Reference To Related Applications

This patent application is a continuation-in-part of U.S. patent application Ser. No. 08/967,279 entitled "SYNCHRONIZED VARIABLE TOOTH ARRANGEMENTS FOR SAWS," filed on November 7, 1997, which is a continuation of Ser. No. 08/577,930, also entitled "SYNCHRONIZED VARIABLE TOOTH ARRANGEMENTS FOR SAWS," filed on December 22, 1995, which in turn is a continuation-in-part of Ser. No. 08/408,847 filed on March 23, 1995.

Field Of The Invention The present invention relates generally to saw blades, and deals more particularly with an improved tooth form for providing enhanced discharge of chips from the gullet area of each tooth and improved tooth strength.

Background Of The Invention The terms used herein to describe the profile of a saw blade tooth are to be construed in accordance with the definitions found in International Standard Number ISO 4875/1-1978. In addition, the phrase "effective gullet radius" as used herein should be construed to mean the horizontal distance from the leftmost point of the gullet area, when the saw blade is viewed with the teeth pointing upward, to the point where the gullet depth reaches its maximum value.

In many instances, particularly in production settings, it is desirable to cut materials such as wood, plastic, and metal at the highest feed rates achievable. However, the rate at which a particular material can be presented to the saw blade is governed in large part by the stresses induced in the teeth of the blade, as well as by the rate at which particles or chips generated by the cutting action of the blade are discharged from the gullet area between consecutively spaced teeth.

In prior art tooth forms, the effective gullet radius is relatively small, typically less than approximately 25% of the tooth pitch. In addition, the gullet depth or gullet depth is typically between about 40% and about 50% of the tooth pitch with the length of the rake - 2-

face accounting for approximately half of the height. As a result of this relatively small effective gullet radius and the relatively long rake face, shear stresses are concentrated at the base of each tooth on the saw blade which often are of sufficient magnitude to tear or shear a tooth from the saw blade during a cutting operation. Another problem associated with known tooth forms having a profile similar to that described above is that during a cutting operation, the long rake face combined with a small gullet radius inhibits the flow of chips out of the gullet area by acting as a barrier. This creates the potential for the chips generated during a cutting operation to become lodged in the gullet area, which in turn diminishes the cutting efficiency of the saw blade. To minimize this problem, the feed rate of the material through the saw, or the cutting speed of the blade, must be reduced, resulting in a concomitant reduction in production.

Based on the foregoing, it is the general object of the present invention to provide a saw blade employing a tooth profile that overcomes the above-described drawbacks of prior art saw blade teeth. It is a more specific object of the present invention to provide a saw tooth profile having enhanced chip discharge characteristics.

Summary Of The Invention

The present invention is directed to a saw blade having a cutting edge defined by a plurality of teeth disposed along the blade. Each of the teeth includes a tip, a rake face, a relief surface, and a curvilinear base surface, with the tip of one tooth and the tip of the next consecutive tooth defining a pitch distance therebetween. The tip of each tooth and the curvilinear base surface disposed between consecutively spaced teeth cooperate to define a maximum gullet depth. In addition, the rake face of each tooth and the curvilinear base surface cooperate to define the effective gullet radius.

To provide enhanced chip discharge capabilities over prior art saw blades, the saw tooth profile of the present invention includes an effective gullet radius that is greater than approximately 25% of the pitch distance, and 55% of the maximum gullet depth. This larger radius extends upwardly toward the tip of the tooth leaving only a small vertical rake face, thereby minimizing any barriers that would inhibit the flow of chips from between the teeth of the blade. To further improve the chip discharge characteristics, the tooth profile can also be formed such that the relationship between the pitch distance and the height of the tooth is optimized. Preferably, the gullet depth of the saw blade of the present invention is greater than approximately 40% of the pitch distance. - 3-

In addition to the foregoing, each saw tooth may include a primary relief surface defined by a first relief angle extending from the tip of the tooth in a direction opposite to the cutting direction of the saw blade, and a secondary relief surface extending from the first relief surface and defined by a second relief angle different from, and larger than, the first relief angle. Preferably, the first relief angle is approximately 35° and the second relief angle is between about 45° and about 55°, with both the first and second relief angles being measured from a plane approximately perpendicular to the cutting direction of the blade. The presence of the secondary relief surface, coupled with the fact that the second relief angle is larger than the first relief angle, increases the gullet area between consecutive teeth over that which would be achieved if only the first relief angle were present. This increased gullet area reduces the likelihood of chips lodging between consecutively disposed teeth by providing a larger gullet area for chips to collect. The increased gullet area also allows the rate of chip ingress to, and egress from, the gullet area to equilibrate during a cutting operation. In addition to providing enhanced chip discharge capabilities over that of known saw blades, it is also desirable to maximize the stress-bearing capabilities of the saw teeth. Accordingly, the teeth of the saw blade of the present invention employ a relatively short rake face, preferably less than 25% of the gullet depth, and a large radius tangent to the rake face which is defined by the curvilinear base surface. The combination of the short rake face and large radius increases the stress-bearing characteristics of the saw teeth by providing greater tooth width at the base of each tooth where stresses are greatest, without increasing the gullet depth. This reduces the likelihood of the teeth shearing or tearing during a cutting operation.

Brief Description Of The Drawings

FIG. 1 is an enlarged partial side elevational view of the saw blade of the present invention;

FIG. 2 is an enlarged partial side elevational view of an alternate embodiment of the saw blade of FIG. 1; FIG. 3 is an enlarged partial side elevational view of an alternate embodiment of the saw blade of FIG. 1; and

FIG. 4 is an enlarged partial side elevational view of an alternate embodiment of the saw blade of FIG. 1.

Detailed Description Of The Preferred Embodiments .4.

Detailed Description Of The Preferred Embodiments

FIG. 1 illustrates a saw blade embodying the invention. The saw blade, generally designated by the reference numeral 10, includes a cutting edge defined by a plurality of saw teeth 12, each tooth having a tip 14, a rake face 16, and a relief surface 18 extending from the tip in a direction opposite to the saw blade's cutting direction designated in FIG. 1 by arrow A. The teeth 12 are spaced along the cutting edge with the tip of one tooth and the tip of the next consecutively disposed tooth cooperating to define a pitch distance P. A curvilinear base surface 20 extends between the rake face 16 of one tooth 12 and the relief surface 18 of the next consecutive tooth. As shown in FIG. 1 , the base surface 20 is tangent to the rake face 16. The rake face 16, the curvilinear base surface 20, and the relief surface 18 cooperate to define a gullet area 22. In addition, an effective gullet radius R_gff is defined by the rake face 16 and the curvilinear base surface 20. R_eff is equal to the horizontal distance from the leftmost point of the gullet area 22, when the saw blade 10 is viewed in the orientation shown in FIG. 1 , to the point where the gullet depth or gullet depth H reaches its maximum value.

Still referring to FIG. 1 , the relief surface 18 includes a primary relief surface 24 extending from the tip 14 of the tooth 12 and a secondary relief surface 26 extending from the primary relief surface tangent to a radius R_! defined by the curvilinear base surface 20. The primary and secondary relief surfaces, 24 and 26, respectively, are further defined by first and second relief angles, θ_x and θ₂, respectively, measured from a plane extending parallel to the cutting direction A of the saw blade 10. Preferably, the second relief angle θ₂ is larger that the first relief angle θ_i , thereby increasing the size of the gullet area 22 over that which would be possible if only the first relief surface were present.

In the embodiment of the present invention illustrated in FIG. 1, the effective gullet radius R_gff is greater than approximately 25%, and preferably equal to about 30% of the pitch distance P. In addition, the effective gullet radius R_eff is greater than approximately 55% of the gullet depth H, and is preferably between about 65% and 85% of the gullet depth, and most preferably equal to about 81% of the gullet depth. Moreover, the length of the rake face 16 between the tip 14 of the tooth 12 and the point where the rake face is tangent to a radius R₂ defined by the curvilinear base surface 20, is preferably less than 25% of the gullet depth. This relatively short rake face length allows the radius R₂ to be maximized, thereby minimizing stress at the base of the tooth.

Still referring to FIG. 1 , during a cutting operation, chips generated by the saw blade 10 flow into the gullet areas 22 between consecutively disposed teeth 12. As the cutting operation continues, the chips must be discharged from the gullet areas 22 so that newly generated chips can be accommodated. The large effective gullet radius R_gff, the relatively short rake face 16, the primary and secondary relief surfaces, 24 and 26, respectively, and the curvilinear base surface 20 all cooperate to define a gullet area 22 that provides for the smooth ingress and egress of chips to and from the gullet area. A second embodiment of the saw blade of the present invention, shown in

FIG. 2, is generally designated by the reference numeral 110. The saw blade 110 is similar in many respects to the saw blade 10 described above, and therefore like reference numerals preceded by the number 1 are used to indicate like elements. The saw blade 110 differs from the saw blade 10 in that the effective gullet radius R_eff is approximately 36% of the pitch distance P and approximately 77% of the gullet depth H. In addition, the gullet depth is approximately 46% of the pitch distance P.

Still referring to FIG. 2, the relief surface 118 includes a primary relief surface 124 extending from the tip 114 of the tooth 112, and a secondary relief surface 126 extending from the primary relief surface tangent to the radius R₁₀₁ defined by the curvilinear base surface 120. The primary and secondary relief surfaces, 124 and 126, are further defined by first and second relief angles, ?ιoι and θ\oι, respectively, measured from a plane extending parallel to the cutting direction of the saw blade 110. Preferably, the second relief angle θ\ ₀₂ is larger than the first relief angle #ιoι. In the illustrated embodiment #ιoι is approximately 35°, and θw∑ is approximately 45°. A third embodiment of the saw blade of the present invention is shown in FIG.

3 and is generally designated by the reference number 210. The saw blade 210 is similar in many respects to the saw blade 10 described above, and therefore like reference numerals preceded by the number 2 are used to indicate like elements. The saw blade 210 differs from the saw blade 10 in that the effective gullet radius R_eff is approximately 41% of the pitch distance P and approximately 79% of the gullet depth H. In addition, the gullet depth is approximately 46% of the pitch distance.

The relief surface 218 includes a primary relief surface 224 extending from the tip 214 of the tooth 212, and a secondary relief surface 226 extending from the primary relief surface tangent to the radius R₂₀₁ defined by the curvilinear base surface 220. The primary and secondary relief surfaces, 224 and 226, are further defined by first and second relief angles, ftoi and Θ102, respectively, measured from a plane extending parallel to the cutting direction of the saw blade 210. Preferably, the second relief angle 6202 is larger than the first relief angle #201. In the illustrated embodiment #201 is approximately 35°, and Θ202 is approximately 55°. - 6-

A fourth embodiment of the saw blade of the present invention is shown in FIG. 4 and is generally designated by the reference numeral 310. The saw blade 310 is similar in many respects to the saw blade 10 described above, and therefore like reference numerals preceded by the number 3 are used to indicate like elements. The saw blade 310 differs from the saw blade 10 in that the rake face 316 defines a positive rake angle ftake measured from a plane extending approximately perpendicular to the cutting direction A of the saw blade 310. While the angle ftake is positive in the illustrated embodiment, the present invention is not limited in this regard as θ_ιake can also be zero or negative without departing from the broader aspects of the invention. The embodiment illustrated in FIG. 4 also differs from the other embodiments described above in that the curvilinear base surface 320 is defined by a combination of radii, R₃₀₁ and R₃₀₂, with rectilinear portion Z₃₀₁ interposed therebetween. In addition, the relief surface 318 includes a primary relief surface 324 defined by relief angle ftoi, and a secondary relief surface 326 defined by radius R₃₀₃. In the illustrated embodiment, the radius R₃₀₃ is tangent to the primary relief surface 324 and the radius R₃₀₁ defined by the curvilinear base surface 320. In addition, the radius R₃₀₃ is convex relative to the radius R₃₀₁ defined by the curvilinear base surface 320. However, the invention is not limited in this regard as the radius R₃₀₃ can be either convex or concave and does not have to be tangent to the primary relief surface 324 or the curvilinear base surface 320. In addition, while the curvilinear base surface 320 has been shown and described as being defined by a combination of radii, R₃₀₁ and R₃₀₂, with rectilinear portion ₃₀₁ interposed therebetween, the present invention is not limited in this regard. The curvilinear base surface 320 can be defined by any combination of radii and rectilinear sections without departing from the broader aspects of the present invention. Moreover, the relief surface 318, while shown and described in the illustrated embodiment as including a rectilinear primary relief surface 324 and a radial secondary relief surface 326, is not limited in this regard as any combination of radial and rectilinear surfaces can be employed without departing from the broader aspects of the present invention.

Referring to FIGS. 2-4, during a cutting operation, chips are generated by the saw blades, 110, 210, or 310, which flow into the respective gullet areas. As the cutting operation continues, the chips must be discharged from the gullet areas so that newly generated chips can be accommodated. The larger effective gullet radii R_eff, the relatively short rake faces, the larger angles or radii of the secondary relief surfaces 126, 226, and 326, as well as the curvilinear base surfaces 120, 220, or 320 of each of these blades, all cooperate to define gullet areas larger than those of known saw blades. The larger gullet areas provide the saw blades with the capability to handle larger volumes of chips, thereby enabling the - 7-

blades to operate at higher speeds. In addition, the large radii which define the curvilinear base surfaces provide the teeth of these blades with enhanced stress-bearing capabilities by minimizing any stress concentrations at the base of the teeth. This in turn reduces the likelihood of the teeth shearing or tearing from the blades, thereby enabling them to cut materials at higher speeds which would normally impose large amounts of stress on the teeth. While preferred embodiments have been shown and described, various modifications and substitutions may be made without departing from the spirit and scope of the present invention. Accordingly, it is to be understood that the present invention has been described by way of example, and not by limitation.

Claims

- 8-What is claimed is:

1. A saw blade having a cutting edge defined by a plurality of teeth disposed along the blade, each of said teeth having a tip, a rake face, a relief surface and a curvilinear base surface, the tip of each tooth and the tip of the next consecutively disposed tooth defining a pitch distance, the curvilinear base surface and the tip of each tooth cooperating to define a maximum gullet depth, and the rake face and the curvilinear base surface of each tooth cooperating to define an effective gullet radius greater than about 25% of the pitch distance and greater than about 55% of the maximum gullet depth.

2. The saw blade of claim 1 wherein the rake face and the curvilinear base surface of each tooth cooperate to define an effective gullet radius greater than about 30% of pitch distance.

3. The saw blade of claim 1 wherein the rake face of each tooth defines a positive rake angle.

4. The saw blade of claim 1 wherein the rake face of each tooth defines a negative rake angle.

5. The saw blade of claim 1 wherein the relief surface of each tooth includes a primary relief surface defined by a first relief angle and a secondary relief surface defined by a second relief angle, the first and second relief angles being measured relative to a plane substantially parallel to the cutting direction of the saw blade.

6. The saw blade of claim 5 wherein the first relief angle is approximately

35┬░.

7. The saw blade of claim 5 wherein the second relief angle is approximately 45┬░.

8. A saw blade having a cutting edge defined by a plurality of teeth disposed along the blade, each of said teeth having a tip, a rake face, a relief surface and a curvilinear base surface, each tooth and the next consecutively disposed tooth defining a pitch distance extending between the tips thereof, the curvilinear base surface and the tip of each tooth cooperating to define a gullet depth greater than about 40% of the pitch distance, and the rake face and the curvilinear base surface of each tooth cooperating to define an effective gullet radius greater than about 25% of the pitch distance.

9. The saw blade of claim 8 wherein the effective gullet radius is greater than about 30% of the pitch distance.

10. The saw blade of claim 8 wherein the rake face defines a positive rake angle as measured relative to a plane approximately perpendicular to the cutting direction of the saw blade.

11. The saw blade of claim 8 wherein the rake face defines a negative rake angle as measured relative to a plane approximately perpendicular to the cutting direction of the saw blade.

12. The saw blade of claim 8 wherein the relief surface of each tooth includes a primary relief surface defined by a first relief angle extending from the tip of the tooth, and a secondary relief surface defining a second relief angle extending from the primary relief surface, the first and second relief angles being measured relative to a plane substantially parallel to the cutting direction of the saw blade.

13. The saw blade of claim 12 wherein the first relief angle is approximately 35┬░.

14. The saw blade of claim 12 wherein the second relief angle is between approximately 45┬░ and approximately 55┬░.

15. The saw blade of claim 8 wherein:

16. the relief surface of each tooth is defined by a primary relief surface extending from the tip of the tooth, and a secondary relief surface extending from the primary relief surface; and wherein a respective one of the primary and secondary relief surfaces is defined by a relief angle measured from a plane approximately parallel with the direction of cut of the saw blade, and the other of the primary and secondary relief surfaces is defined by a radius. - 10-

17. The saw blade of claim 8 wherein the curvilinear base surface is defined by a first radius tangent to the rake face and at least a second radius tangent at one end to the first radius and at another end to the relief surface.

18. The saw blade of claim 8 wherein: the curvilinear base section of each tooth is defined by at least one radius; and the rake face is between about 10% and about 25% of the gullet depth.

19. The saw blade of claim 1 wherein the curvilinear base surface is defined by a combination of radial and rectilinear sections.