Patent Application
20140150620
The present invention relates to saw blades, and more particularly, to saw blade teeth having tips including different materials, respectively.
A typical toothed saw blade includes a blade portion having a cutting edge defined by a plurality of teeth axially or circumferentially spaced relative to each other along one side of the blade. A “one-sided” blade has a non-working edge formed on an opposite side of the blade relative to the cutting edge, while a “double-sided” blade will have two opposing cutting edges. In addition to the configuration of the saw blade itself, e.g., tooth profile, the blade materials are selected based on an intended application and/or desired durability. Generally, though, the use of stronger and/or more durable materials involves increased cost and/or increased manufacturing complexity. Further these “upgraded” materials may present trade-offs for their increased strength/durability.
One blade configuration, for example, that has gained wide acceptance as having increased performance and durability with an acceptable cost differential is a composite or bi-metal (or tri-metal in the case of double-sided blades) blade. A typical bi-metal saw blade includes a spring or carbon steel blade body having a cutting edge or teeth formed of high speed or tool steel. The use of high speed or tool steel only at the cutting edge limits cost. The use of carbon or spring steel for the blade body helps maintain flexibility and toughness of the blade.
Though bi-metal blades can provide substantial performance improvements over carbons steel blades, some applications require even greater cutting ability and/or durability. For such applications, such as abusive applications, specialty blades are used. As compared to bi-metal blades, specialty blades, on the other hand, may have a cutting edge or include teeth made of different material. For example, specialty blades may include diamond or carbide tipped teeth rather than the high speed steel used on typical bi-metal saw blades. Such higher strength, higher hardness, higher durability materials can provide increased cutting speed and blade life over even bi-metal blades in certain applications or when cutting certain materials.
Though a specialty blade can be very beneficial when used for an intended application, both for its cutting efficiency and for its blade life, there can be trade-offs. A specialty blade can be more susceptible to premature failure than a typical saw blade when misapplied. For example, when cutting through an abrasive material, which tends to dull the blade relatively quickly, a carbide-tipped specialty blade is very advantageous because the carbide tipped teeth remain sharp for longer. However, the carbide material at the tip of these blades possesses a higher hardness than a typical bi-metal blade, and consequently is more brittle. Thus, inadvertent misapplication or misuse by a user, such as, for example, cutting through a hard material, such as a nail or screw, or where an impact occurs, is more likely to cause the teeth to break or even catastrophic failure of the blade than with a typical bi-metal blade. Vibration of the saw blade when cutting, as is not atypical, for example, with reciprocating saw blades, can similarly cause the carbide-tipped teeth to break.
Another issue with specialty-type blades is cost. They are much more expensive to produce than even bi-metal blades. The above-described potential breakage problem is exacerbated by this cost of manufacture, and thus the retail cost, of a specialty blade relative to a typical blade. Consequently, breakage due to just a small error in the blade's application, or premature failure or wear of the blade, is of significant financial consequence to the user.
Prior art attempts to solve the problem include the use of lower grade material, e.g., lower grade carbide, to reduce costs. While less expensive, these blades are also less durable. Other attempts have involved highly sophisticated manufacturing processes in an attempt to reduce blade manufacturing costs. Nonetheless, costs remain higher to manufacture such specialty blades in comparison to a typical bi-metal blade.
It is an object of the present invention to overcome one or more of the above-described drawbacks and/or disadvantages of the known saw blades.
In one aspect, a saw blade comprises a blade body, a plurality of cutting teeth defining a cutting edge along an edge of the blade body, each tooth along the cutting edge defining a cutting tip, wherein at least one tooth tip along the cutting edge includes a first material and at least one other tooth tip along the cutting edge includes a second material different than the first material.
In some embodiments, the saw blade is a reciprocating saw blade for use in a reciprocating saw machine. As should be understood by those of ordinary skill in the art, a reciprocating saw machine is a hand-held power saw that includes a chuck for releasably engaging a tang extending from the end of the saw blade and driving the saw blade in a reciprocating motion through a work piece. The reciprocating motion can be an orbital cutting action, a straight or linear cutting action, or an angled cutting action. The length or stroke of the reciprocating motion is typically about 1½ inches or less. Reciprocating saws typically are driven by electric motors (e.g., cord or cordless saws) or are pneumatically driven. A typical reciprocating saw blade includes a blade portion having a cutting edge defined by a plurality of teeth axially spaced relative to each other along one side of the blade, and a non-working edge formed on an opposite side of the blade relative to the cutting edge. A tang for releasably connecting the blade to the chuck of a reciprocating saw extends from an inner end of the blade.
In some other embodiments, the saw blade is a band saw blade. In yet other embodiments, the saw blade is a hole saw blade. In further embodiments, the saw blade is a hack saw blade.
In some embodiments, the first material includes high speed or tool steel. In some embodiments, the second material includes a carbide material. In some embodiments, the second or different material includes diamond. In some embodiments, the at least one of the materials includes a coating. In some such embodiments, the coating is one of a physical vapor deposition coating, a ceramic coating a metal nitride coating, and a carbide-containing coating.
In some embodiments, the plurality of cutting teeth are arranged in a repeating pattern along the cutting edge, said pattern comprising a tooth having a tip including the first material, followed by a tooth having a tip including the second material.
In some embodiments, the plurality of cutting teeth are arranged in a repeating pattern along the cutting edge, said pattern comprising a tooth having a tip including the first material, followed by a pair of teeth having tips including the second material.
In some embodiments, the plurality of cutting teeth are arranged in a repeating pattern along the cutting edge, said pattern comprising a pair of teeth having tips including the first material, followed by a pair of teeth having tips including the second material.
In accordance with another aspect, a saw blade comprises a blade body, a plurality of cutting teeth defining a cutting edge along an end of the blade body, each tooth along the cutting edge having a first means for cutting, wherein at least one of the first means for cutting includes a first material and at least one other of the first means for cutting includes a second material different than the first material.
In some embodiments, the first means for cutting defines a cutting tip of a respective cutting tooth.
In accordance with another aspect, a method of manufacturing a saw blade comprises the steps of:
(i) forming a saw blade body; and
(ii) forming, along an axial edge of the saw blade body, a plurality of cutting teeth having respective tooth cutting tips defining a cutting edge of the saw blade, wherein at least one tooth tip along the cutting edge includes the first material and at least one other tooth tip along the cutting edge includes a second material different than the first material.
In some embodiments, the step of forming the saw blade body includes attaching a wire comprising the first material along an axial edge of a backing strip; and the step of forming the plurality of cutting teeth comprises forming the teeth along the edge of the saw blade body including the first material.
In some embodiments, the step of forming the plurality of teeth comprises forming the at least one tooth tip including the first material from the saw blade body, forming, at a location of the at least one other tooth tip, a surface on the saw blade body adapted to receive a tooth tip including the second material, and attaching a tooth tip including the second material to said surface to form the at least one other tooth tip.
In some embodiments, the forming step comprises die cutting the blade body to form the plurality of cutting teeth. In some embodiments, the forming step comprises machining the blade body to form the plurality of cutting teeth.
Objects and advantages of the present invention, and/or of the currently preferred embodiments thereof, will become more readily apparent in view of the following detailed description of the currently preferred embodiments and accompanying drawings.
In
As shown in
Though the teeth 16 in the embodiments of
By way of example only, the teeth 16 may also have secondary and/or tertiary clearance surfaces defining secondary and/or tertiary clearance angles, such as, but not limited to, that disclosed in U.S. patent application Ser. No. 12/776,145, filed May 7, 2010, entitled “Recip Blade with Robust Tooth Form,” which is hereby expressly incorporated by reference in its entirety as part of the present disclosure.
As another example, the different teeth 16 along the cutting edge 14 may define variable heights, such as, but not limited to, that disclosed in U.S. Pat. No. 8,210,081, issued Jul. 3, 2012, entitled “Reciprocating Saw Blade Having Variable Height Teeth and Related Method,” which, in turn, claims priority from similarly titled U.S. Provisional Patent Application Ser. No. 60/934,262, filed Jun. 12, 2007, each of which is hereby expressly incorporated by reference in its entirety as part of the present disclosure. The height H of a tooth 16 in the shown embodiments is measured as the distance between a tip 20 of a respective tooth and a selected reference plane of the blade body 12 located below the tips 20, such as, for example, the back edge 13. Typically, heights are measured with respect to a back edge of the saw blade 10; however, as may be recognized by those of ordinary skill in the pertinent art based on the teachings herein, the heights can be measured with respect to any of numerous different reference points that are currently known or used, or later become known or used for this purpose.
As yet another example, the teeth 16 may define a plurality of repetitive patterns of teeth, i.e., tooth patterns that have variable heights, clearance angles, rake angles and/or set, according to the intended application as should be understood by those of ordinary skill in the art, for example, as disclosed in, but not limited to, U.S. patent application Ser. No. 12/827,658, filed Jun. 30, 2010, entitled “Saw Blade Tooth Form For Abusive Cutting Applications,” which is hereby expressly incorporated by reference in its entirety as part of the present disclosure.
Different tips 20 along the cutting edge 14 of the blade 10 include different materials. As shown in
The teeth 16 may also be arranged in different patterns along the cutting edge 14, according to the material of their respective tips 20. For example, as shown in
Further, though in
The current invention provides significant advantages over known saw blades. From a cost perspective, the inventors have found that a reduced number of specialty or higher-grade material tips may be utilized in a blade while still efficiently cutting the intended material. As the cost of a specialty tip material, such as, for example, carbide or diamond, is much more expensive than the cost of a typical steel tip or steel-tipped blade, even when a bi-metal construction is used, reducing the number of tips including specialty blade material will, at a minimum, reduce the manufacturing cost of blades of the invention. Accordingly, the retail cost of such blades will also be reduced.
The current inventors have also found that in addition to reducing the manufacturing costs of blades of the invention, as a result of the reduced number of tips including specialty blade material, for example, the resultant blades are also more versatile. For example, as discussed above, a blade having only high speed steel tooth tips will wear relatively quickly when cutting through an abrasive work piece in comparison to a carbide tipped blade. On the other hand, the blade having only carbide tipped teeth may perform relatively poorly, and may chip fracture, when cutting a hard material, such as a nail or screw, or subject to impact or vibration. However, the current inventors have found that a saw blade 10 having different tips 20′, 20″, including different materials, respectively, performs substantially well, i.e., cuts efficiently, is durable, and/or meets expected blade life, in a variety of applications, and a wider variety of applications than traditional for specialty blades. For example, a blade having an arrangement of both high speed steel tipped teeth and carbide tipped teeth will perform substantially well when cutting through either of the abrasive and/or a hard material work surfaces mentioned, at substantially reduced costs as compared to a blade having only carbide teeth. The high speed steel teeth will cut through the harder material and reduce impact and breakage of the carbide teeth, and the carbide teeth will efficiently cut the abrasive material, reducing the workload and subsequent wear to the high speed tips.
The blades 10 of the invention are manufactured by forming a cutting edge 14 defined by a plurality of cutting teeth 16 along an axial edge of a blade body 12, where different tips 20 of the teeth 16 along the cutting edge 14 include different materials. In many embodiments, the blades are formed using known techniques or a combination of known techniques for making previously-known blades of the selected materials, as should be understood by those of ordinary skill in the art. For example, in embodiments having a combination of high speed steel and carbide tips, the high speed steel tips can be formed using known techniques, and the carbide tips can be formed by using known techniques for doing so.
In one such embodiment, a bi-metal or composite blade strip is first formed by welding a wire of a first material along an axial edge of a backing strip of a second material and heat treating the blade strip in a known manner. In some such embodiments the second material of the backing strip is a metal, such as steel. In some such embodiments, the steel is, for example, spring steel or carbon steel. In some embodiments, the first material of the wire is a metal, such as, for example a high speed or tool steel. However, as may be recognized by those of ordinary skill in the pertinent art based on the teachings herein, any of numerous different materials for the wire and the backing strip, currently known, or that later become known, may be used according to the intended application of the blades. As also may be recognized by those of ordinary skill in the pertinent art based on the teachings herein, a unitary structure blade strip made of a single material, such as, for example, a metal (e.g. spring steel or carbon steel), or a composite material may be utilized to manufacture the blades 10. Alternatively, a tri-metal blade strip may be utilized to manufacture the blades 10 having cutting edges along opposing sides of the blade body.
Individual blade bodies 12 are then die cut or otherwise formed from the unitary or bi-metal blade strip. The plurality of cutting teeth 16 are then machined, such as, for example, milled, cut, punched, ground, or otherwise formed along the edge of the blade bodies 12 having the first material. In some embodiments, the blade bodies 12 are die cut to form the teeth 16. In other embodiments, the blade bodies 12 are mounted in a fixture, and the blade bodies 12 are machined to form the teeth 16, as disclosed in U.S. Provisional Patent Application Ser. No. 61/666,724, filed Jun. 29, 2012, entitled “Double Sided Hand Hack Saw Blade and Method of Manufacture,” which is hereby expressly incorporated by reference in its entirety as part of the present disclosure.
The teeth 16 are formed, i.e., shaped, according to the desired tooth tip material as well as the tooth pattern along the cutting edge 14. For example, where a blade is desired that has select tooth tips including specialty material(s), such as, for example, carbide or diamond, the select teeth intended to have the specialty material at the tip can be initially formed without a tip, but instead are formed with a pocket at the top of the tooth, i.e., a surface at the top of the tooth for receiving a tooth tip, in accordance with the standard methods known by those of ordinary skill in the pertinent art. Thereafter, tips having the specialty material are joined, e.g., welded, onto those select teeth with pockets in accordance with the standard methods known by those of ordinary skill in the pertinent art.
By way example only, if the desired saw blade has a spring steel backing with alternating teeth tips 20′ and 20″, such as shown in
Alternatively, all of the tooth forms can be provided with a pocket for attachment of a tip. For example, if a carbon or spring steel blade body 12 is used, a pocket can be created for each tooth 16, and tooth tips 20 of desired materials or combinations of materials, e.g., HSS, carbide, cermet, diamond, etc., can be attached to form the tip of tooth. In such embodiments, the preliminary step of forming the bi-metal strip, e.g. welding a wire or strip to the carbon or spring steel backing is thereby eliminated. Such embodiments also eliminate the need for more complex tooling and machining operations in which only certain of the teeth are machined to form pockets.
On the other hand, the blade can be made without forming any pockets. Rather, a tooth form with a tip can be made in the initial teeth-forming operation (e.g., milling, punching, grinding, etc.), and then other materials attached to selected teeth. As should also be recognized by those of ordinary skill in the pertinent art, the tooth tip material(s) may equally be welded, or otherwise deposited, such as, for example, via coating, onto teeth 16 formed with tips, i.e., not formed with preformed pockets.
As discussed above, and as those of ordinary skill in the art should appreciate, different teeth intended to receive specialty material(s) (i.e., different than the base material of the blade body) may each receive the same grade specialty material, or different grades of the specialty material. For example, and without limitation, some of the selected teeth 16 may receive type/grade A carbide tips while other of the selected teeth may receive type/grade B carbide tips. As should also be recognized by those of ordinary skill in the pertinent art, select teeth may receive other tooth tip material(s), such as, for example, high speed steel or a cermet composite material.
As may be recognized by those of ordinary skill in the pertinent art based on the teachings herein, numerous changes and modifications may be made to the above-described and other embodiments without departing from the scope of the invention as defined in the appended claims. For example, the tooth forms and patterns may differ from the tooth forms and patterns described herein. Certain tooth forms may be removed, and other different tooth forms may be added, and/or the teeth of the repeating pattern may all define the same tooth form, such as a straight-backed tooth form that defines a single clearance surface, or a tooth form that defines three or more clearance surfaces. Similarly, the teeth may define different pitches, different set patterns, and different combinations of set patterns and tooth heights. For example, the teeth need not define any height differentials and/or the teeth may define varying degrees of set magnitude (including heavy and light sets, and other degrees of set). As another example, the teeth having tips including a first material can be set in the same direction and to the same set magnitude as the teeth having tips including a different second material. Alternatively, the teeth having tips including a first material may be set to a different magnitude and/or direction than the teeth having tips including a different second material. As yet another example, high teeth may include a relatively heavy set magnitude and low teeth may define a relatively light set magnitude as compared to the high teeth. Similarly, the rake face of the teeth may be substantially vertical (i.e., 0° rake) or define a rake angle (e.g., a positive or negative rake angle). As another example, the teeth may be arranged at a variable pitch or a constant pitch. As yet another example, any other clearance angles, tooth heights, gullet radii and rake face depths that are known, or that later become known, and different than those described herein equally may be employed. As yet another example, teeth having tips including a first material may be unset and the teeth having tips including a different second material may be set. As yet another example, the back edge of the saw blade may also define a cutting edge, defining a plurality of teeth configured as described above. Accordingly, this detailed description of currently preferred embodiments is to be taken in an illustrative, as opposed to a limiting sense.
