This invention relates to a wood chipper and, more specifically, to a heavy duty rotary disc wood chipper, however this same concept can also be applied to clamping of knives mounted in drum chippers.
Heavy duty wood chippers that are capable of producing large amounts of chips in a relatively short period of time typically employ a circular disc that is mounted for rotation upon a horizontally disposed drive shaft. A plurality of rectangular knives are radially extended upon the front face of the disc. Each knife is, in turn, aligned adjacent to a chip slots that passes through the disc between its front face and back face. Logs or similar work pieces are brought into contact with the front face of the rotating disc within a stationary work station where the moving knives act in association with a stationary bed knife to remove chips from the work pieces. The chips are conducted through the chip slots and exhausted from the machine.
The knives that are typically used in these heavy duty machines are subjected to high impact loads which, if not effectively resisted can adversely affect the life of the knives and quality of the product produced in the machine depending upon various loading factors. In an effort to combat these high loads, it has been customary in the industry to use knives that are relatively massive in not only size but also in weight. As a result, the apparatus for securing the knives within a chipper is generally rather complex and expensive to build and maintain. Removal of the knives from the machine for refurbishing or replacing is usually a time consuming procedure. In addition, handling the massive knives is a multi-worker task and can pose a danger to the workers and the knives if the knives are mishandled or dropped. Systems employing much smaller knives meanwhile typically compromise the strength of the knives and the holding system resulting in a weaker overall clamping and holding system.
Good knife support systems must also accommodate normal variations in thickness of knives due to variability in knife manufacture tolerances and also to accommodate for contamination such as wood dust, tree sap and debris that might work itself between mated parts while still safely and adequately holding the knives in place.
The apparatus used to secure a chipper knife to a disc most generally involves some type of clamping mechanism for releasably capturing the knife or knives between the clamp and a substrate on the disc. The clamping force is typically provided by bolts that pass through the clamp and are threaded into the substrate so that the axes of the bolt shanks are generally normal to the front face of the disc. When used with hardware that permits keyed or doweled contact and transmission of forces to the disc, this type of clamping arrangement is well suited to resist input loads acting parallel to or perpendicular with the axis of the bolts. The clamping arrangement, however, is not as well suited to resist loads other than those running along these two primary axes or to couples arising from loads not being applied concentrically with the disc key supports or the holding bolts. These off-axis loads and couples are generally concentrated along one edge section of the bolt heads, a condition referred to as “point loading” of the bolt head, which results in a reduction in the holding effectiveness of the clamp and clamping bolts. When point loading occurs, the bolts or knife clamps can fatigue and fail giving rise to an unsafe situation of inadequately clamped knives and knives rapidly become dull or damaged and the quality of the chips produced being greatly reduced. Gaps and clearances that are often present between clamping system components can permit parts to deflect from their stress-free manufactured states, further exacerbating the “point loading” problem referred to above and observed in practice.
It is therefore a primary object of the present invention to improve heavy duty rotary disc wood chippers.
It is a further object of the present invention to improve the apparatus for supporting chipper knives in a rotary disc chipper.
It is a still further object of the present invention to reduce the size and weight of the knives used in rotary disc chippers without sacrificing the strength of the holding system and efficiency of the machine or the quality of product produced.
Another object of the present invention is to reduce the amount of time and effort needed to remove, refurbish and replace knives in a rotary disc chipper.
Still another object of the present invention is to reduce the deleterious effects of off-axis loads and couples on the knives and knife clamping system of a heavy duty rotary chipper.
A still further object of the present invention is to provide a knife clamping system that is largely uncompromised by normal variations in thickness of knives and contamination therein between clamped or coupled parts.
These and other objects of the invention are attained in a heavy duty rotary disc chipper by a knife hold down system that concentrates the loads acting upon the knives along two primary axes that are either parallel with or perpendicular to the front face of the disc such that the impact loads on the system are more effectively resisted and the deleterious effects of off axis loads greatly reduced. This, in turn allows for the use of smaller knives in the system without adversely effecting the efficiency of the system or the quality of the product produced.
For a better understanding of these and other objects of the invention, reference shall be made to the following detailed description of the invention which should be read in conjunction with the accompanying drawings wherein:
Referring initially to
The disc 12 is enclosed within a protective housing, generally referenced 17, made up of a number of separtable sections. One of the sections 18 is shown moved back along a rail system 19 to permit clear access to the disc. A number of triangular shaped knife holders 20, sometimes referred to as segments, are secured to the front face of the disc. As will be described in greater detail below, each knife holder supports one or more chipper knives which are drawn through a stationary chipping station 25 as the disc rotates about the drive shaft 13. In the chipping station, the knives co-act with a stationary bedknife to remove chips from wooden work pieces, typically logs, that are brought into contact with the front face of the disc. In this particular embodiment, the work pieces are brought by a conveyor (not shown) into contact with the disc through a horizontal delivery spout 27 that is integral with the support frame 14. Although a horizontal feed station is intended for use in the illustrated machine, a vertical gravity feed system may be similarly utilized without departing from the teachings of the present invention.
Turning now more specifically to
The studs securing each knife holder body to the disc include a row of smaller diameter studs 40 (
When the knife holder is secured in place its side wall surface 36 runs radially along one edge of the adjacent chip slot 30 and protrudes slightly into the slot. A cutout 50 is provided in the protrusion and one end of a wear plate 51 is supported in the cutout. The wear plate passes out of the cutout along the wall 39 of the slot and turns at a right angle along the rear face 32 of the disc. The angled section 49 of the wear plate is provided with a series of clearance holes that allow this section of the wear plate to be placed over the studs 40 into contact against the rear face 32. Torquing down the stud nuts 43 secures the wear plate in place within the chip slot and helps to secure the knife holder in place with the bottom wall surface in parallel alignment with the front face of the disc.
Turning now more specifically to
A knife assembly 65 is shown mounted within the knife seat 53 in
A keyway 80 (
As best illustrated in
A number of recessed openings 95 are provided in the top surface of the clamp that are spaced apart along its radial length. Each opening contains a clearance hole 96 that allows a clamping bolt 104 to pass through the clamp. The bolt is mated with a threaded insert 98 contained within a receiving bore 99 formed within the knife holder body. Each insert contains an anti-rotation key 100 that prevents the insert from turning in the bore as the bolt is torqued down in assembly. This insert can also be made an integral component of the knife holder.
The bottom surface of each bolt receiving opening is provided with a concave spherical seat 101 that is centered upon the axial centerline 102 of the clearance hole 96. A spherical washer 103 is placed under the head of each bolt that has a convex spherical lower surface that compliments the shape of the seat 101 and which establishes a spherical joint between the bolt head 104 and the clamp when the bolts are torqued down. The spherical joint that is established between the bolt and the knife holder body serves to concentrate off-axis impact loads generating during the chipping process along the axis of the clamping bolts thereby considerably reducing the otherwise deleterious effects of unwanted off axis loads or couples. The spherical seat in the holder body can be replaced with a flat seat perpendicular to the axes of the bolt holes and separate washers with complimentary arcuate shaped mating surfaces to provide a spherical joint without departing from the teaching of the present invention.
Due to the present system ability to direct all impact loads acting upon the system along two primary axes, the overall loading upon the system is more effectively resisted and the size of the knives used in the chipper can be considerably reduced. This, in turn, allows for greater ease in handling of the knives when loading, refurbishing and reloading the knives. Tasks that normally had to be carried out by more than one person can now be carried out rapidly and safely by a single worker. In addition, test have shown that multiple smaller than normal chipping knives can be safely mounted in a side by side relationship within each knife holder seat thereby further reducing handling problems typically associated with larger more massive knives.
Here again the knife holder body contains a recessed clamp compartment 113 that opens into the knife seat through the back wall of the seat. A radially extended clamp 115 is mounted inside the compartment and includes a contact area 116 that rests in abutting contact with the top surface of the knife or knives located within the knife seat. A convex spherical shaped raised key 118 extends radially along the floor of the compartment and is arranged to mate with a complimentary concave keyway that is formed in the bottom wall of the clamp to support the clamp above the floor of the compartment. A series of cylindrical headed screws 120 are passed through clearance holes formed in the clamp between the contact area 116 and the key 118 and are threaded into the body of the knife holder to support the clamp within the body of the knife holder.
A rectangular shaped key 81 is mounted within a keyway that runs radially along the length of the holder body. The side walls of the key are perpendicular aligned with the bottom wall of knife holder while the top and bottom walls of the key are parallely aligned with the top and bottom walls of the holder. The key extends beyond the bottom wall of the knife holder and the extended portion of the key is received within an expanded keyway 85 formed in the front face of the disc. At least one side wall of the key is in abutting contact with one side wall of the expanded keyway 85 so as to resist loads that are generated on the system that act along the two primary load axes which, as explained above, run parallel with or perpendicular to the face of the disc. The spherical joint between the clamp and the knife holder body established by the spherical key serves to concentrate off-axis input loads generated during the chipping process along one of the primary load axes thereby reducing the otherwise deleterious effects of these otherwise harmful loads. The knife body is tightly secured against the front face of the disc by a series of studs such as stud 40.
While the invention has been described with reference to preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof to adapt to particular situations without departing from the scope of the invention. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope and spirit of the appended claims.