FOR MANUFACTURING SUCH A BLADE

The present invention relates to a toothed blade manufacturing apparatus and a method of manufacturing a length of toothed blade. In particular, the present invention relates to the manufacture of saw blades produced from a strip material (e.g. bi-metallic, carbon and carbide strip material), e.g. band-saw blades, hack saw blades, reciprocating saw blades, wood bandsaws, food bandsaws, and metal-cutting bandsaws.

Toothed blades used for band-saws, hack saws, reciprocating saws, holesaws, wood bandsaws, food bandsaws, metal-cutting bandsaws or the like generally comprise a length of strip material having a plurality of teeth cut into one edge. These types of saw require a generally straight length of toothed cutting material as opposed to circular saws which require a circular shaped saw blade with circumferential teeth.

It is a known manufacturing method to produce a band-saw blade by machining (e.g. milling/grinding) a number of teeth into the edge of a length of strip material. The machining process is slow and limits the speed at which saw blades can be produced from the resulting toothed length of strip material. In order to increase the rate of production of saw blades the strip material may be machined in batches. This is done by aligning a number (e.g. 40) of lengths of material side by side and machining the teeth on each length in the batch simultaneously. While this method may improve the rate of saw blade production it has a number of drawbacks . The strips must be a consistent and uniform size and shape, and must have the same overall coil length, so that they can be aligned together in a batch for machining. Additional steps must therefore be taken in the production of the strips to ensure that they are consistent and correctly aligned. This makes the production of the strips and saw blades more time consuming and leads to increased waste material when cutting the strips to matched lengths.

In a first aspect, the present invention provides a method of producing toothed blades from a strip material, the method comprising: laser cutting the strip material to form a plurality of teeth in an edge of the strip material; and mechanically machining the strip material to remove at least part of a heat-affected portion of the edge resulting from the laser cutting.

The present invention provides a combination of laser cutting and mechanical machining steps to produce toothed blades from a strip material. The time required to mill teeth into the strip material can be reduced by the use of laser cutting, while any heat-affected region resulting from the laser cutting can be removed using a subsequent quick or light machining process. Once cut in this way, the resulting toothed strip material can be cut into a number of individual saw blades. The present invention may therefore allow the efficient production of a number of different tooth- geometry saw blades from a single continuous length of strip material. This allows the production rate and/or yield of saw blades to be increased compared to prior art methods. Optionally, the laser cutting is controlled to restrict the extent of the heat-affected portion. This allows the amount of material that must be removed by the mechanical machining step to be reduced. This means that the mechanical machining step can be performed quickly enough to the integrated into a continuous production method with the laser cutting step.

Optionally, the laser cutting is controlled by setting one or more parameters of a laser beam used to cut the strip material, and preferably wherein the one or more parameters comprise the laser beam power. The extent of the heat-affected portion may be controlled by appropriately setting the parameters of the laser beam. Controlling the power of the laser beam may provide a convenient method of accurately controlling the heat-affected portion by reducing the amount of heat conducted away from the cutting point.

Optionally, the laser cutting is controlled by setting the rate of relative movement between the metal strip material and the laser beam used to cut the strip material. By altering the time or focus that the laser beam is incident on a particular area of the strip material the extent of heat conduction away from the cutting point may be accurately and conveniently controlled to limit the extent of the resulting heat- affected portion. Optionally, the laser cutting comprises near-net shaping of the metal strip material. This allows the approximate required shape of the teeth to be created by the laser cutting process, with only a quick, light, mechanical machining step required to produce the final toothed strip material.

Optionally, the laser cutting comprises cutting the strip material to produce a heat- affected portion extending less than 0.3 mm into a body of the strip material. This allows the heat-affected portion to be quickly removed by the mechanical machining by reducing the need to remove a large amount of material.

Optionally, the method further comprises heat treating the strip material before the laser cutting step. This may avoid damage to the teeth during the heat treating process. This differs from prior art methods where laser cutting is not used. In such prior art methods heat treating must be done after the teeth are cut when the bi-metal strip material is not too hard for mechanical machining. The heat treating may comprise heating the strip material to a temperature suitable to harden the material (or both harden and temper the strip material e.g. in the case of processing a bi-metallic strip material). The temperature to which it is heated may be chosen according to the type of material (e.g. type of metal or metal alloys) from which the strip material is formed. The combination of heat treatment followed by cutting the strip material to form teeth advantageously allows the heat treatment to be performed while minimising adverse effects on the shape of the teeth. This combination and processing order is not usually possible using prior art mechanical cutting techniques. Optionally, the method further comprises setting the tooth rake of at least one of the plurality of teeth, wherein setting the tooth rake comprises angling the at least one tooth relative to the body of the strip material. When the tooth profiles have been laser cut into the strip material, they are in line with the body of the strip. The teeth may be set (angled out from the body) to facilitate cutting and prevent binding of the blade body during cutting. Optionally, the plurality of teeth are set to vary in angle along the length of the strip material. Optionally, the tooth rake is set after the mechanical machining step.

Optionally, the strip material comprises a bi-metal strip . Optionally, the bi-metal strip comprises a first metal or alloy and a second metal or alloy, and wherein the first metal or alloy is harder that the second metal or alloy, and wherein the laser cut edge of the bi-metal strip material is formed from the first metal or alloy. The teeth may be cut into the harder part of the bi-metal material to provide a hard wearing cutting edge, while the softer part of the bi-metal strip material provides improved durability by reducing the risk of cracking. Optionally, the strip material comprises a single metal or alloy, and wherein the laser cut edge of the strip is formed in the single metal or alloy.

Optionally, the method further comprises providing relative conveying movement between the strip material and a laser cutting apparatus in which the laser cutting occurs, and between the strip material and a mechanical machining apparatus in which the mechanical machining occurs. Optionally, providing the relative conveying movement comprises conveying the strip material through both the laser cutting apparatus and the mechanical machining apparatus. A continuous length of strip material may be conveyed through the apparatus used to perform the method, rather than requiring the manufacturing to be done in batches.

Optionally, the method further comprises feeding the metallic strip material from a spool, or coil, to the laser cutting apparatus. This allows the strip material to be cut in a single length, rather than machining separate lengths in batches.

Optionally, the relative conveying movement rate is between 0.5 m/min and 5 m/min. This rate allows adequate time for the laser cutting and the mechanical machining to be carried out as the material strip passes through the laser cutting and mechanical machining apparatus. This allows continuous, single length production to be achieved compared to prior art batch productions techniques.

Optionally, the method further comprises dividing the strip material into multiple toothed blade lengths following the mechanical machining step. Optionally, the strip material comprises a length from which multiple toothed blades can be produced. This means that multiple toothed-blades can be manufactured from a single length of toothed strip material compared to prior art batch production techniques where individual blades are machined separately. In another aspect, the present invention provides a toothed blade production line arranged to produce toothed blades from strip material, the production line comprising: a laser cutting apparatus arranged to cut a plurality of teeth into an edge of the strip material; and a mechanical machining apparatus arranged to remove at least part of a heat-affected portion of the edge resulting from the laser cutting.

Optionally, the laser cutting apparatus is arranged to control the extent of the heat affected portion. This will reduce the amount of time required to perform the mechanical machining step by reducing the amount of material that must be removed.

Optionally, the laser cutting apparatus is controlled to restrict the heat affected portion by controlling one or both of the power or focus (e.g. spot size) of a laser beam used to cut the strip material, or the rate of relative movement between the strip material and the laser beam, or both. This provides a convenient and accurate means to reduce the heat conduction away from the cutting point to reduce the extent of the heat affected-portion of the strip material.

Optionally, the laser cutting apparatus is arranged to produce a heat affected portion extending less than 0.3 mm into a body of the strip material. This may reduce the time taken to perform the mechanical machining step such that both the laser cutting and mechanical machining can be performed on a single, continuous length of strip material.

Optionally, the laser cutting apparatus comprises a pulsed fiber laser. This allows the strip material to be cut quickly without a large heat-affected portion being created.

Optionally, the toothed blade production further comprises a heat treatment apparatus arranged to heat treat the strip material before it is cut by the laser cutting apparatus. This may avoid damage to the teeth during the heat treating process.

Optionally, the strip material comprises a bi-metal strip material comprising a first metal or alloy and a second metal or alloy, and wherein the first metal or alloy is harder than the second metal or alloy, and wherein the edge of the metallic strip material is formed from the first metal or alloy, and preferably wherein the first metal is formed from a high-speed-steel grade material. The teeth may be cut into the harder part of the strip material to provide a hard wearing cutting edge, while the softer part of the bi-metal strip material provides improved durability by reducing the risk of cracking. Optionally, the toothed blade production line further comprises a tooth setting apparatus arranged to set the tooth rake of at least one of the plurality of teeth. Optionally, the tooth setting apparatus is arranged to set the rake of the teeth following the mechanical machining. The tooth setting apparatus may be arranged to set the angle of individual teeth away from the body of the toothed blade.

Optionally, the toothed blade production line further comprises a conveying mechanism arranged to provide relative conveying movement between the strip material and the laser cutting apparatus and between the strip material and the mechanical machining apparatus. Optionally, the conveying mechanism is arranged to convey the strip material through both the laser cutting apparatus and the mechanical machining apparatus. This may allow a continuous length of strip material to be moved through the apparatus, rather than requiring the manufacturing to be done in batches. Optionally, the toothed blade production line further comprises a feeder mechanism for feeding the strip material from a spool, or coil, to the laser cutting apparatus. This allows the strip material to be cut in a single length, rather than machining separate lengths in batches. Optionally, the toothed blade production line further comprises a dividing apparatus arranged to divide the strip material into multiple toothed blade lengths after removal of at least part of the heat affected portion. Optionally, the strip material comprises a length from which multiple toothed blades can be produced. This allows a single length of strip material to be divided into individual toothed-geometry blades once the teeth have been cut and any heat-affected portion removed. This will provide more efficient production compared to prior art batch production techniques.

Embodiments of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which: Figure 1 is a representation of a method of producing toothed blades from strip material according to an embodiment; and

Figures 2A, 2B and 2C show close-up views of a section of bi-metal strip material at different stages during the method shown in Figure 1 ;

Figures 2D, 2E and 2F show close up views of a non-composite strip material at different stages during the method shown in Figure 1 ; Figure 3 shows a representation of a method of producing toothed blades from strip material according to another embodiment;

Figure 4 shows a schematic representation of a toothed blade production line according to an embodiment; and

Figure 5 shows a schematic representation of a toothed blade production line according to another embodiment.

A method 100 of producing toothed blades from a strip material is shown schematically in Figure 1. The method 100 is suitable for producing toothed blades such as saw blades, including for example band-saw blades; hack saw blades; reciprocating saw blades; and holesaw blades. The method is however not limited to producing saw blades, but may also be used to manufacture other articles such as knives or other tools.

The toothed blades may be produced from a variety of materials. In some embodiment, the strip material comprises a metallic strip such as a steel strip. In some embodiments the strip material is formed from a bi-metal, carbon metal alloy or metal carbide strip material. A section of a bi-metal strip material 200 is shown schematically in Figures 2A, 2B and 2C at various stages of the method 100. Figures 2D, 2E and 2F represent non-composite strip 250 produced in the same manner. As can be seen in Figure 2A, the bi-metal strip material 200 begins as a generally elongate strip formed from a first metal (or metal alloy) 202 and a second metal (or metal alloy) 204 joined together by welding or the like as is known in the art. The first and second metals 202, 204 may have differing properties to provide a saw blade having a suitable combination of cutting speed and durability.

In some embodiments, the first metal (or alloy) 202 may be harder than the second metal (or alloy) 204, and may for example, be formed of high speed steel. In such an embodiment, the teeth of the toothed blade may be formed from the first metal 202 so as to provide a hard material for cutting. As the second metal 204 is comparatively softer it may reduce the brittleness of the overall toothed blade. This may therefore provide an advantageous balance between fast cutting (using the relatively hard first metal 202) and durability (as the second relatively soft metal 204 is not as susceptible to cracking).

In other embodiments, the toothed blades may be produced from a metal strip made from a material other than a bi-metal. The toothed blades may, for example, be made from a metal strip material comprising a single metal, or any other number of metal, metals or alloys or other materials. Figures 2D, 2E and 2F show an embodiment in which a non-composite strip 250 is processed. In this embodiment, the strip material comprises a single material, such as a single metal 202. Teeth are cut into the edge of the metal 202 to again form a heat-affected portion 206.

The method 100 comprises laser cutting 102 the strip material to form a plurality of teeth in an edge of the strip material. The teeth may be cut using a laser cutting apparatus arranged to direct laser radiation onto the surface of the strip to cut the material via localised heating as is known in the art. The laser cutting apparatus may comprise a single cutting laser that is directed to the strip from a single direction (e .g. to cut from one surface of the strip material). In other embodiments, the laser cutting apparatus may comprise a first and a second laser arranged such that they oppose each other to cut from each surface of the strip material. This may reduce the burr produced by the laser cutting. In the described embodiment, a single edge of the strip material 200, 250 may be cut to form teeth. In other embodiments, any number of edges or parts of the strip material 200, 250 may be cut by the laser cutting processes 102 to form the teeth.

During the laser cutting step a heat-affected portion 206 (or heat-affected zone) of the strip material 200, 250 is produced as a result of the heat required to cut the material. The heat-affected portion 206 is created by conduction of heat in the material away from and around the cutting point. Where the metal (or other material) forming the strip is heated a phase change can occur within the structure leading to undesirable properties. The heat affected-portion 206 may be formed adjacent or along the cut edge of the strip material 200, 250 as shown in Figures 2B and 2E.

The method 100 further comprises mechanically machining 104 the strip material 200, 250 to remove at least part of the heat-affected portion 206. In some embodiments, all of the heat-affected portion 206 may be removed by the mechanical machining. In other embodiments, only part of the heat-affected portion 206 is removed. In some embodiments, the mechanical machining step may remove both the heat-affected portion 206 and a part of the strip material not affected by the laser cutting step 102.

The mechanical machining 104 may comprise any suitable method of machining the strip material 200, 250 to remove the required material. The mechanical machining 104 may comprise milling, grinding, drilling or any other suitable machining method. By mechanical machining we mean removing material using a cutting or grinding tool or the like as opposed to removal of material via laser cutting or the like. By providing a combination of both laser cutting and mechanical machining the method 100 allows the efficient production of a continuous length of toothed strip material. Prior art methods which rely solely on mechanical machining must use batch production because the machining of the teeth is slow. The method 100 uses a combination of laser cutting to rapidly cut teeth into the bi-metal strip material, followed by a rapid mechanical machining step to remove any heat affected-portion resulting from the laser cutting. The inventors have found that this combination of cutting processes may allow a more efficient, continuous length production process with a fast rate of production. This makes production of toothed blades quicker, more efficient and reduces waste compared to prior art batch milling methods.

The laser cutting 102 may comprise near-net shaping of the strip material 200, 250. By near-net shaping we mean that the laser cutting step 102 cuts the teeth close (but not completely) to the final desired shape. The mechanical machining step 104 then provides a rapid finishing step to give the final desired shape of the cutting teeth. In some embodiments, the geometry of the plurality of teeth may vary along the length of the strip material. This may be achieved by altering the shape cut by the laser cutting, the shape cut by the mechanical machining, or both. This allows a single length of strip material to be produced having various tooth geometries along its length. Such a strip material can later be cut into separate lengths of toothed blade, each with differing tooth geometries. This is advantageous over prior art batch production methods where a batch of toothed blades are machined with the same geometry. The laser cutting step 102 may be controlled in order to restrict the extent of the heat- affected portion 206. This may allow the heat-affected portion 206 to be reduced in size such that it can be quickly removed during the following mechanical machining step 104, while still allowing the strip material to be quickly cut by the laser. In some embodiments, the laser cutting 102 may be controlled by setting one or more parameters of the laser beam(s) used to cut the strip material 200, 250. The one or more parameters may comprise the laser beam power. This may provide a simple and accurate control of the extent of the heat-affected portion 206. By reducing the laser beam power, the heat-affected portion 206 may be reduced as less heat is generated in the bi-metal strip material 200 during cutting.

In other embodiments, other parameters of the laser beam(s) may be set to control the heat-affected portion 206. This may include, for example, the laser intensity, spot size, focus at the cutting point or type of laser used (i.e. the wavelength of laser radiation used).

In yet other embodiments, the laser cutting 102 may be controlled by setting the rate of relative movement between the strip material 200, 250 and the laser beam(s) used to cut the strip material. By increasing the rate of relative movement the amount of time the laser is incident on a particular part of the strip material 200, 250 is reduced. This reduces the heat generated in the material and thus reduces the extent of the heat affected portion 206.

The laser cutting 102 may be controlled to optimise its speed while still producing a heat-affected portion 206 that can be quickly removed by the mechanical machining step 104. In some embodiments, the laser cutting 102 may comprise cutting the strip material 200, 250 to produce a heat-affected portion 206 extending less than 0.3 mm into a body of the strip material 200, 250 (e.g. the heat-affected portion may extend less than 0.3 mm away from the cut edge of the strip material 200, 250). This has been found to allow rapid machining of the strip material 200 to remove the heat-affected portion 206 and provide an improved rate of production of toothed blades.

In other embodiments, the heat-affected portion 206 may extend any other amount from the cut edge of the bi-metal strip material, and may, for example extend 0.05 mm, 0. 1 mm, 0. 15 mm, 0.2 mm, 0.25 mm, 0.3 mm, 0.35 mm, 0.4 mm, 0.5 mm, 0.6 mm, 0.7 mm, 0.8 mm, 0.9 mm, 1 mm or any range in between any of those valves.

Another embodiment of a method of producing toothed blades from a strip material 200, 250 is shown in Figure 3. Any of the features discussed in relation to the first embodiment 100 may also be included in the second embodiment 300 shown in Figure 3, and vice versa. The method 300 also includes the mechanical machining step 102 and the laser cutting step 104. The method 300 further comprises heat treating 302 the bi-metal strip material 200, 250 before the laser cutting step 102, and tooth-setting 303 as will be explained later.

The heat treating step 302 may comprise heating the strip material to a temperature suitable to harden the metal as is known in the art. The temperature to which it is heated is chosen according to the type of metal (or metal alloys) from which the strip material 200, 250 is formed. By heat treating the strip material 200, 250 before teeth are cut into its edge damage or distortion to the shape of those teeth may be avoided. This is in contrast to prior art methods in which heat treating takes place after teeth are machined into the edge of the strip material 200, 250. In the prior art this is done to allow the material to be machined while it is still relatively soft. The use of laser cutting allows the hardened strip material 200, 250 to be cut (as laser cutting can be used to cut harder material in comparison to other methods) after heat treatment has taken place. In other embodiments, the heat treatment step 302 may not be included in the method 300, or may be performed at a later stage (e.g. after laser cutting and/or after mechanical machining). In some embodiments, the method 100, 300 may further comprise setting 303 the tooth rake of at least one of the plurality of teeth, wherein setting the tooth rake comprises angling at least one of the teeth relative to the body of the strip material 200, 250. The angle of the plurality of teeth may be set such that they vary along the length of the strip material 200, 250. In other embodiments, the angle may be set to be the same along the length of the strip material 200, 250. By setting the angle or rake of the teeth more efficient cutting may be achieved as is known in the art. The tooth setting step 203 may be included after the mechanical machining step 104 as shown in Figure 3. In other embodiments, the tooth setting step may be included at any other suitable point in the method.

In some embodiments, the method 100, 300 may further comprise dividing 308 the strip material 200, 250 into multiple toothed blade lengths following the mechanical machining step 104 (and the teeth setting step 303 if included) as shown in Figure 3. This may be done by cutting the strip material. In other embodiments, the strip material 200 may be wound around an output spool after the mechanical machining 104 to be used in a single length or divided into individual toothed blades in a separate process In some embodiments, the method of producing toothed blades 100, 300 further comprises providing relative conveying movement between the strip material 200, 250 and the laser cutting apparatus in which the laser cutting 104 occurs, and between the strip material 200, 250 and a mechanical machining apparatus in which the mechanical machining 104 occurs. The strip material 200, 250 may, in some embodiments, be conveyed through both the laser cutting apparatus and the mechanical machining apparatus. The relative conveying movement may be provided by a conveying mechanism arranged to move the strip along a processing path through a production line adapted to perform the method 100, 300. The conveying mechanism may comprise a guide means comprising one or more rollers or the like which may be driven to convey the strip material 200, 250. In some embodiments, the conveying movement may comprise feeding of the strip material 200 from a spool (or coil), to the laser cutting apparatus arranged to perform the laser cutting step 102. Following the laser cutting apparatus the strip may be conveyed to the mechanical machining apparatus so that the heat-affected portion of the strip can be removed. In some embodiments, the strip material 200, 250 may be conveyed in a continuous length (e.g. from the input spool) through both the laser cutting apparatus and the mechanical machining apparatus.

The strip material 200, 250 may comprise a length from which multiple toothed blades can be produced. This allows continuous production of a length of toothed strip suitable to provide a number of separate toothed blade lengths, with each length being suitable to form an individual saw blade. In some embodiments, the separate toothed blades may have differing tooth geometries where the tooth geometry is varied along the length of the strip material.

In some embodiments, the relative conveying movement rate may be between 0.5 m/min and 5 m/min. This provides fast production of strip material 200, 250 having a cut toothed edge. This conveying movement rate may be achieved by using a combination of fast laser cutting and rapid mechanical machining.

A toothed blade production line 400 arranged to produce toothed blades from strip material 200, 250 is shown schematically in Figure 4. The production line 400 comprises a laser cutting apparatus 402 arranged to cut a plurality of teeth into an edge of the strip material 200, 250 as described above . The laser cutting apparatus 402 may comprise a laser cutting station having at least one laser arranged to cut teeth into an edge of the strip material 200. In some embodiments, the laser cutting apparatus may comprise one or more lasers directed towards one face or surface of the strip material 200, 250. In other embodiments, the laser cutting apparatus may comprise at least two opposing (e.g. co-axially aligned) lasers arranged to cut the strip material 200, 250 from each of its opposing faces. This may allow any burr created during the cutting process to be minimised. The laser cutting apparatus may be arranged to vary the geometry of the teeth along the length of the strip material as described above.

The laser cutting apparatus 402 may be arranged to provide relative movement between the one or more lasers and the strip material 200, 250 such that the required tooth pattern may be cut. This may be done by moving the laser beam(s) (e.g. by moving a laser cutting head) relative to the strip material 200, 250, which may be kept stationary. In other embodiments, the relative movement may be provided by moving the strip material 200, 250 relative to a stationary laser beam(s) (or laser cutting head). In yet other embodiments, both the strip material 200, 250 and the laser beam(s) may be moved. The strip material 200, 250 may be moved relative to the laser beam(s) (or laser cutting head) in a direction along the length of the strip material. The laser beam(s) may also be moved in a direction perpendicular to the length of the strip to provide the necessary directions of relative movement to cut the teeth.

In some embodiments, the laser cutting apparatus 402 comprises one or more pulsed fiber lasers arranged to cut the strip material 200. By using a pulsed fiber laser, the laser cutting apparatus can quickly cut the teeth into the strip material 200, 250 while minimising the extent of the heat-affected portion. In other embodiments, other suitable types of laser may be used, such as a C0 ₂ laser.

The production line 400 further comprises a mechanical machining apparatus 404 arranged to remove at least part of the heat-affected portion 206 of the edge resulting from the laser cutting. In some embodiments, the mechanical machining apparatus 404 may comprise a milling or grinding device arranged to remove at least the heat- affected portion of the strip material 200, 250.

The laser cutting apparatus 402 may be arranged to control the extent of the heat affected portion. In some embodiments, the laser cutting apparatus 402 may be arranged to produce a heat affected portion 206 extending less than 0.3 mm into a body of the strip material 200, 250. This may allow the heat-affected portion 206 to be removed by a rapid mechanical machining step that is fast enough to allow efficient continuous processing of the strip material 200, 250. The extent of the heat-affected portion 206 may be controlled by controlling the amount of heat imparted to the strip material 200, 250 during the laser cutting. Reducing the heat generated by the cutting laser(s) reduces the heat conducted from the cutting point into the surrounding metal and therefore reduces the extent of the heat-affected portion 206. A balance must however be found between reducing the level of conducted heat while still providing adequate heat to efficiently cut the strip.

The laser cutting apparatus 402 may be controlled to restrict the heat-affected portion 206 by controlling a parameter of the laser beam(s). In some embodiments, the laser beam(s) power may be controlled. In other embodiments, the intensity or spot size at the surface of the strip material 200, 250 may be controlled. Additionally or alternatively, the rate of relative movement between the strip material 200, 250 and the laser beam(s) may be controlled to limit the extent of the heat-affected portion 206. For example, greater relative movement between the strip material 200, 250 and the laser beam(s) may reduce the amount of time that heat has to conduct through the material and so may reduce the extent of the heat-affected portion 206.

The toothed blade production line 400 may further comprise a conveying mechanism (not shown in the Figures) arranged to provide relative conveying movement between the strip material 200 and the laser cutting apparatus 402 and between the strip material 200 and the mechanical machining apparatus 404.

The conveying mechanism may be arranged to convey the strip material 200, 250 along a processing path through the production line 400. The conveying mechanism may therefore be arranged to convey the strip material 200, 250 through both the laser cutting apparatus 402 and the mechanical machining apparatus 404, and through any other components of the production line (e.g. a heat treatment apparatus, tooth-setting apparatus, and a dividing apparatus if provided).

The conveying mechanism may comprise one or more rollers arranged to support the strip material 200, 250 along its length. In some embodiments, one or more of the rollers may be driven to move the strip material 200, 250 along the processing path.

The production line 400 may further comprise a feeder mechanism 406 for feeding (either directly or indirectly) the strip material 200, 250 from a spool, or coil, to the laser cutting apparatus 402. An output spool or coil 408 may also be provided on which the finished toothed strip material 200, 250 may be coiled.

Another embodiment of a toothed blade production line 500 is shown in Figure 5. The production line 500 shown in Figure 5 also comprises the laser cutting apparatus 402 and the mechanical machining apparatus 404. Any of the features described herein may be used in either the production line 400 shown in Figure 4 or the production line 500 shown in Figure 5.

As shown in Figure 5, the production line 500 further comprises a heat treatment apparatus 502. The heat treatment apparatus 502 may comprise a furnace or induction heating device or the like. The heat treatment apparatus may be arranged to heat the strip material 200, 250 to a temperature suitable to harden the metal from which it is formed. As discussed above, the heat treatment apparatus 502 may be arranged to heat treat the strip material 200, 250 before it is cut by the laser cutting apparatus 402.

In the described embodiment, the heat treatment apparatus 502 may be arranged such that it precedes the laser cutting apparatus 402 along the processing path followed by the strip material 200. The strip material 200 may therefore pass through the heat treatment apparatus 502 before reaching the laser cutting apparatus 402.

The toothed blade production line 400, 500 may further comprise a tooth setting apparatus 503. The tooth setting apparatus may be arranged to angle at least one, or a plurality of, the teeth once they have been cut. The tooth setting apparatus may be arranged to set the angle or rake of the teeth relative to the body of the toothed blade . The tooth-setting apparatus 503 may be arranged to receive the strip 200, 250 from the mechanical machining apparatus 404 and therefore after removal of at least part of the heat affected portion 206. The angle of the teeth may be varied along the length of the strip material. This may allow toothed cutting blades with varying tooth rake to be made from a single length of strip material. In other embodiments, the angle may be constant along the length of the material. The tooth setting apparatus may comprise a mechanical mechanism arranged to engage the teeth of the strip material and push them away from alignment with the body of the strip material as it moves along the processing teeth through the production line . The toothed blade production line 400, 500 may further comprise a dividing apparatus 504 arranged to divide the bi-metal strip material 200 into multiple toothed blade lengths 406. The dividing apparatus 504 may be arranged to receive the strip 200, 250 from the tooth-setting apparatus 503 (or the mechanical machining apparatus if the tooth setting apparatus is not provided) and therefore after removal of at least part of the heat affected portion 206 and setting of the individual teeth.

The dividing apparatus 502 may comprises a cutting tool or the like suitable for dividing the strip 200 into individual lengths. In other embodiments, the dividing apparatus 504 may comprise any device suitable for dividing the strip 200, 250 such as a grinding tool, milling tool or cutting torch. The strip material 200, 250 may therefore comprise a length from which multiple individual toothed blades can be produced. The toothed blade production line may, for example be arranged to process a single length of strip material 200, 250, which may for example have a length restricted only by dimensional, or weight limitation, of the conveying mechanism to produce a plurality of individual saw blades 506.

In some embodiments, the method of producing a toothed blade may further comprise attaching a cutting tip to one or more of the plurality of teeth. The cutting tip may be welded onto the strip material at one or each of the teeth to provide a cutting surface. The cutting tip may comprise a carbide tip, hi-speed steel tip or any other metallic tip. The method may further comprise mechanically shaping (grinding or milling) the cutting tip to provide a final tip. This grinding process may be deeper than the mechanical grinding to remove the heat-affected portion resulting from the laser cutting of the tooth profile. The light mechanical machining step is still needed across the profile of the saw tooth, in addition to the deeper mechanical shaping of the welded metallic tip and they may be provided in separate machining processes. In some embodiments, a tooth tipping apparatus may be provided to weld a tip to the teeth once the heat-affected portion has been removed. The teeth tipping apparatus may further comprise a second mechanical machining apparatus to shape the tipped teeth.