Patent Application
20210086393
The sawmill disclosed herein is directed to a mill with bidirectional bandsaw cutting capability provided by two directionally opposed cutting blades mounted on a traveling carriage for cutting horizontal sections from logs in successive back and forth passes.
The conversion of harvested logs into a finished lumber product comprises many steps from forest to sawmill and from sawmill to lumberyard. Because of increased competition, both foreign and domestic, the modern lumber industry has had to face a new range of problems to survive and prosper. Because of the increased cost of logs, their limited availability and generally smaller sizes, it is essential to obtain as much lumber value from each log as possible. Increasing equipment and labor costs have also made it necessary to obtain that lumber efficiently and economically. In addition, it has become important to limit waste, both to increase yield and for environmental reasons. These factors then make it essential to modernize the lumber-producing art.
In view of the above, it is advantageous to minimize the amount of time and energy required to produce a set number of board feet of lumber per unit of time. The current state of the art includes portable mills that are exceptionally capable of unidirectional sawing of logs. The time required to re-position the bandsaw to the opposing longitudinal end of the carriage is a needless drain on the time available to complete the production of a set number of board feet.
The sawmills disclosed herein utilize a bandsaw that is a long, sharp blade consisting of a continuous band of toothed metal stretched between two or more wheels to cut material. Bandsaw blades that are utilized in portable sawmill operations most commonly have a toothed edge and a flat blade back. The flat blade back portion of the blade has a thickness, generally referred to as the “gauge.” The toothed edge many times will have a tooth pattern that includes a side clearance angle that causes the toothed edge to have a “set” that is wider than the gauge. The set of the blade creates the “kerf,” the slit or notch made as the saw blade advances through the work piece to be wider than the gauge of the blade. When the sawmill is operating the flat blade back rides on the flat outer circumference surface of the blade wheel while the toothed edge overhangs the rotating blade wheel. The toothed edge must overhang, or extend beyond, the outer edge of the blade wheel to prevent loading of one side of the toothed edge and possibly adversely altering the set of the blade.
Also, when sharpening bandsaw blades that have become dull from extensive use or possibly from striking a metal object, such as a nail or a staple embedded in the work piece, it is important during the sharpening process for the flat blade back to provide a level surface so that the grinding of the tooth face is performed at the correct angle relative to the flat blade back.
The flat blade back of the single cutting-edge bandsaw is central to the functionality of the bandsaw saw mill. The “set” on the blade which results in a tooth area thickness greater than the “gauge” of the flat blade back restricts, and operationally prohibits, the riding of the bandsaw teeth on the outer circumference of the blade wheels and the guide rollers. The utilization of bandsaw blades with double toothed edges may appear to be an obvious solution to the challenge of increasing operational efficiency; however, double tooth edged bandsaw blades are far more expensive than single cutting edge and the ability to sharpen double-sided blades is also far more complicated and very costly. The operational and economic deficiencies associated with double cutting-edge bandsaw blades necessitates a much closer look at how to optimize the use of two single relatively inexpensive cutting-edge bandsaw blades to provide for cutting of the log in both directions.
While bidirectional band saw mills do exist in the marketplace, they are heavy industrial-scale machines and utilize very expensive and difficult-to-maintain two-sided blades. By using two, inexpensive, single-sided blades oppositely directed and closely spaced, the apparatus as disclosed herein eliminates the need for an expensive two-sided blade. This offers the benefits of bi-directional sawing to a light-industrial and hobby level of sawmill owner which heretofore have been financially out of reach.
Disclosed herein is a portable sawmill that utilizes two band saws mounted back to back on a carriage with a saw head for cutting through logs with successive back and forth passes as the carriage and saw head reciprocate on a frame. A section of the log is cut with one band saw in one pass and then a next section of the log is cut by the other oppositely directed band saw blade as the carriage and saw head travel in the opposite direction during the following pass.
The sawmill with bidirectional bandsaws also includes a mechanism that facilitates the simultaneous raising and lowering of both band saws for cutting sections from the log so that each respective band saw can be positioned for making the appropriate depth of cut through the section of the log during that respective pass of the respective band saw.
The disclosed sawmill may be configured in at least two separate embodiments. The first embodiment relies upon two laterally disposed across the frame blade wheels which restrain and provide rotational power to the two oppositely directed bandsaw blade wheels. The two blade wheels are disposed on opposite sides of the sawmill and along with either two or four spaced apart guide rollers, serve to guide and level the bandsaw blades and create the cutting throat through which the log passes during the sawing operation. The two blade wheels may optionally utilize a rib adjacent the trailing edge of the bandsaw blade to minimize, or preferably eliminate, the potential for the bandsaw blade to slide off the blade during sawing operations due to the high shearing forces experienced by the bandsaw blade during the sawing of the log.
An alternative second embodiment utilizes a total of four blade wheels, two per laterally opposite sides of the mill. With this second embodiment, a separate bandsaw blade is wrapped around each pair of oppositely disposed blade wheels. The bandsaw blades as in the first embodiment utilize a cutting edge and a trailing edge. The trailing edge of the bandsaw blade in this second embodiment may also butt up against a circumferential rib on the blade wheels that restrains the bandsaw blade against movement off the blade wheels. The two sets of blade wheels and bandsaw blades are preferably closely spaced from one another to avoid the potential for the trailing edge of the second blade binding against a surface of the log as the cutting-edge passes through the log.
This configuration of a sawmill with the bidirectional bandsaw capability is unique in that it saves the time required to recycle the saw head to the starting position and therefore this design can produce more board feet per unit of time than a sawmill without a dual bandsaw configuration.
It is an object of the disclosed saw mill with bidirectional bandsaw to substantially increase the throughput in board feet of lumber cut per unit of time by eliminating unnecessary carriage recycle time.
It is an object of the disclosed saw mill with bidirectional bandsaw to maintain a high mechanical efficiency by utilizing an bidirectional sawing system that does not rely upon a complicated mechanism for sawing or changing elevation of the saw head.
It is an object of the disclosed saw mill with bidirectional bandsaw to minimize mechanical maintenance requirements.
It is an object of the disclosed saw mill with bidirectional bandsaw to minimize operational and maintenance safety concerns.
Various objects, features, aspects and advantages of the disclosed subject matter will become more apparent from the following detailed description of preferred embodiments, along with the accompanying drawings in which like numerals represent like components. The contents of this summary section are provided only as a simplified introduction to the disclosure, and are not intended to be used to limit the scope of the appended claims.
The following description is of various exemplary embodiments only, and is not intended to limit the scope, applicability or configuration of the present disclosure in any way. Rather, the following description is intended to provide a convenient illustration for implementing various embodiments including the best mode. As will become apparent, various changes may be made in the function and arrangement of the elements described in these embodiments without departing from the scope of the appended claims.
Disclosed herein and as shown at
An energy chain 42, as seen in
The third major component of the sawmill with a bi-directional bandsaw 10 is the saw head 16. The saw head 16, as seen in
When the operator of the sawmill desires to cause rotation of the bandsaw blades for log cutting purposes, she engages the electromagnetic clutch 102, with a selectable switch, causing a first clutch pulley 104 to rotate under the power of the engine 92. In a fully assembled and functional configuration, the first clutch pulley 104 is partially surrounded by a saw mill drive belt 103. The same drive belt 103 also partially surrounds a drive wheel 106. The functionality of the drive wheel 106 will be further detailed below in this detailed description section.
A preferred embodiment of the electromagnetic clutch 102 includes a second clutch pulley 105 located distally from the first clutch pulley 104. Whenever the engine 92 is operating, the second clutch pulley 105 is rotating. A second drive belt 100 partially circumscribes the second clutch pulley 105 and partially circumscribes the drive pulley 98 of the hydraulic pump 96. The second clutch pulley 105 provides continuous rotational power to the hydraulic pump 96 so that sawmill's hydraulic accessories may be operated even when rotational power through the first clutch pulley 104 is not needed to drive the bandsaw blades.
The disclosed sawmill with bi-directional bandsaw 10 utilizes at least two distinct embodiments. Both embodiments rely upon the transfer of rotational motion to the drive pulley 106 as detailed above. In the first embodiment, as illustrated in
Both blade wheels 110, 116 rotate about bearings 120, 122 mounted upon the blade wheel shafts 112, 118. The blade wheel shafts 112, 118 and the blade wheels 110, 116 are supported in position by the saw head weldment 88. As noted above, partially surrounding the drive pulley 106 and the first clutch pulley 104 is at least one rubberized blade drive belt 103 that rotates the drive pulley 106 and the first blade wheel 110 that is attached to the drive pulley.
As also seen in
As seen in
At least two guide rollers 140, 142, as seen in
The width dimension (W) of the cutting throat 150, as seen in
The second embodiment of the sawmill 10 with bidirectional bandsaws 10, as seen in partial assembly and exploded
As with the first embodiment, this second embodiment utilizes band saw blades 126, 128 each having back edges 174, 176 and cutting edges 178, 180. The back edges 174, 176 of the band saw blades 126, 128 in this second embodiment, as with the first embodiment, are separated by a narrow gap. When fully assembled, a narrow gap separates the back edges 174, 176 and reduces the potential for snagging of the back edge of the trailing band saw blade on the horizontal surfaces of the log being sawed. Though not essential, an exemplary configuration, as seen in
As with the first embodiment, the second embodiment of the sawmill with bidirectional bandsaw 10 also utilizes guide rollers 190, 192, 194, 196 as seen in
A variant embodiment utilizes just two guide rollers beneath the blades 126, 128. The advantage of employing just two guide rollers, as opposed to four, is that it reduces the need for roller alignment. The leveling and alignment of two rollers requires less time and effort than the alignment and leveling of four rollers; however, the same high functioning operability can still be achieved with two rollers.
The blade wheels 110, 116 for the first embodiment and for the second embodiment 160, 162, 164, 166 are preferably fabricated from carbon steel and therefore are sufficiently robust and highly durable. The blade wheels, as seen in
In operation, whether in the first or second embodiment as detailed above, an actuating mechanism that is well known in the art is utilized to raise and lower the blade wheels 110, 116 or 160, 162, 164, 166 and saw blades 126, 128 as a unit so that both saw blades are raised above the log and lowered as necessary for engagement with the log. The saw head 16 and the carriage 14 that supports the saw head translate along the frame 12 at a preset height. As detailed above, the rotation of the blade wheels 110, 116 or 160, 162, 164, 166 is powered by the output shaft 94 of the engine 92 after transmission through the electromagnetic clutch 102 to the first clutch pulley 104. Once the electromagnetic clutch 102 is manually activated by the operator, the rotational energy of the clutch pulley 104 is transferred to the drive wheel 106 through the drive belt 100 thereby causing rotation of the blade wheels 110, 116 or 160, 162, 164, 166 and saw blades 126, 128.
Whether in the first embodiment configuration or the second embodiment configuration as disclosed above, the operator sets the height of the saw head 16 by activating the designated hydraulic or electrical controls thereby causing the carriage 14 and the saw head 16 mounted to the carriage to translate along the frame 12 on the rollers 40 in direction D1. The cutting edge 130 (first embodiment) 178 (second embodiment) of the distally disposed blade 126 advances through the log creating a horizontal cut and the trailing blade 128 following closely behind the advance of the distal blade 126 as seen in
Once the lead and trailing blades 126, 128 exit the log at the opposite end of the horizontal cut, the operator halts the advance of the carriage 12 and saw head 16. The operator then adjusts the elevation of the saw head, typically by lowering the saw head 16. Once the saw head 16 is brought to the desired elevation above the frame 12, the operator advances the cutting edge 132 (first embodiment) 180 (second embodiment) of the oppositely directed band saw 128 back into the log, direction D2, without the need to recycle the carriage 14 and saw head 16 to the starting location as seen in
The previously disclosed bidirectional bandsaw sawmill 10 utilizes blade wheels 110, 116 or 160, 162, 164, 166 that are horizontally disposed from one another. This disclosure should not be considered limiting as an alternative embodiment (not shown) may also be configured with blade wheels 110, 116 or 160, 162, 164, 166 that are oriented vertically from one another with the bandsaw blade cutting the workpiece log in a vertical plane. This alternative embodiment requires the guide rollers 140, 142 or 190, 192, 194, 196 be oriented vertically as opposed to horizontally.
The cutting throat in this embodiment would be height limited as the largest dimension of a workpiece that can be cut is limited to the span between the vertically disposed guide rollers. Power transmission to the bandsaw blades 126, 128 in this alternative embodiment would be accomplished in the same fashion with rotational power supplied by the output shaft of an internal combustion engine to an electromagnetic clutch. When activated by the operator, the pulley associated with the electromagnetic clutch would begin to rotate and drive a rubberized belt that partially circumscribes the electromagnetic clutch pulley and the drive pulley that is fastened to the first blade wheel.
Having shown and described various embodiments of the present invention, further adaptations of the methods and systems described herein may be accomplished by appropriate modifications by one of ordinary skill in the art without departing from the scope of the present invention. Several of such potential modifications have been mentioned, and others will be apparent to those skilled in the art. For instance, the examples, embodiments, geometries, materials, dimensions, ratios, steps, and the like discussed above are illustrative and are not required. Accordingly, the scope of the present invention should be considered in terms of the following claims and is understood not to be limited to the details of structure and operation shown and described in the specification and drawings. Moreover, the order of the components detailed in the system may be modified without limiting the scope of the disclosure.
