This invention relates to sawmill equipment. More particularly the invention relates to methods and apparatus for selectively diverting pieces of lumber. A particular application relates to sorting lumber into bins.
Lumber sorters are widely used in sawmills to sort pieces of lumber according to various criteria. For example, pieces of lumber (or “boards”) may be sorted by dimensions (e.g. width and/or length), grade or condition, tree species, and the like. A typical lumber sorter comprises a suitable number of bins for receiving sorted boards and a conveyer which carries boards that are to be sorted along a path extending across the tops of the bins. Each bin has a diverter gate which can be actuated to cause a board being carried by the conveyer to drop into the corresponding bin. A controller controls operation of the diverter gates such that each diverter gate opens at a suitable time to deliver into the corresponding bin a board that has been assigned for sorting into the bin.
There is a general desire throughout the sawmill industry to improve the efficiency of sawmills by operating at higher speeds. A disadvantage of existing lumber sorters is that the time taken for diverter gates to open and close limits the speed at which the lumber sorter can operate. Many current lumber sorters have a maximum operating speed of approximately 240 boards carried past each bin per minute. While this is reasonably fast there is a desire for lumber sorters which can operate at higher speeds still.
However, it is difficult to make sorters of existing designs operate faster. At high lug rates the diverter gates must be timed to open and close at precise times with respect to the positions of the boards so as not to lift a preceding board while it is still on the diverter gate, and not to interfere with a following board before the diverter gate is fully closed. In a modern sorter operating at rates of two hundred and forty lugs per minute or even faster, the total time available to open the diverter gate, allow a board to drop out clear of the diverter gate and close the gate again is approximately one-quarter of a second.
The foregoing examples of the related art and limitations related thereto are intended to be illustrative and not exclusive. Other limitations of the related art will become apparent to those of skill in the art upon a reading of the specification and a study of the drawings.
The invention has a number of different aspects. These include, without limitation, lumber sorters, methods for sorting lumber, methods for diverting pieces of lumber into a bin, sorting bins and diverters.
One example aspect provides a lumber sorter. The lumber sorter includes a plurality of bins. A conveyor carries lumber (e.g. boards) along a path extending above the plurality of bins. A diverter is selectively operable to allow the conveyor to carry the boards past one or more bins or to divert a selected board into a selected bin. The diverter may comprise an upstream gate and a downstream gate, each operable to move between respective closed positions and open positions. In the closed positions, the top surfaces of the upstream and downstream gates are substantially level and allow boards to travel along the path as directed by the conveyor. The diverter may be actuated to the open position in which the upstream and downstream gates are separated, thereby providing a path for a board to fall into a bin. A top surface of the upstream gate may travel substantially parallel to the path as it travels between the open position and the closed position. The downstream gate may be moveable across the path to leave a passage between the upstream gate and the downstream gate sufficiently wide for passage of a board into a bin.
Another example aspect provides a method for diverting pieces of lumber into a bin. The method may comprise blocking an opening of a bin using a diverter. The diverter may comprise an upstream gate and a downstream gate, each operable to move between respective closed positions and open positions. In the closed positions, the top surfaces of the upstream and downstream gates are substantially level and allow boards to travel along the path as directed by the conveyor. Boards may be carried along a path across the top surfaces of the upstream and downstream gates by a conveyor. If a piece of lumber is to be diverted into a bin, the method may comprise unblocking the opening by moving the upstream gate in a direction that is substantially parallel with the path of the lumber but opposite the direction of flow of the lumber. The downstream gate may be lifted across the path to leave a passage between the upstream gate and the downstream gate sufficiently wide for passage of the piece of lumber into the bin.
In addition to the exemplary aspects and embodiments described above, further aspects and embodiments will become apparent by reference to the drawings and by study of the following detailed descriptions.
Exemplary embodiments are illustrated in referenced figures of the drawings. It is intended that the embodiments and figures disclosed herein are to be considered illustrative rather than restrictive.
Throughout the following description specific details are set forth in order to provide a more thorough understanding to persons skilled in the art. However, well known elements may not have been shown or described in detail to avoid unnecessarily obscuring the disclosure. Accordingly, the description and drawings are to be regarded in an illustrative, rather than a restrictive, sense.
A conveyer 14 carries boards B along a path P extending above bin 12. A diverter 16 is selectively operable to allow conveyer 14 to carry boards B past bin 12 or to divert a selected board B into bin 12.
In some embodiments conveyor 14 is provided by what is commonly known as a “pusher lug” or a “drag chain” sorter top. In such conveyors, boards are carried in a forward direction from upstream to downstream by lugs attached to a lugged chain conveyor (also referred to as a “lugged transfer chain”). The lugged chain conveyor is located above the boards. The boards are supported by a plurality of fixed skid plates. The skid plates are mounted to the top of each sorter bin to provide a smooth, approximately level surface for the boards to slide over as the boards travel along above the bins. The fixed skid plates are further configured to provide open spaces through which boards can drop into each bin.
In the illustrated embodiment, conveyer 14 comprises a plurality of parallel chains 14A that are driven by a drive system (not shown in
Surfaces 14C are interrupted to provide openings 14D through which boards B can enter corresponding bins 12 when diverted by a corresponding diverter 16.
Diverter 16 comprises an upstream gate 16A and a downstream gate 16B.
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By comparing
In the illustrated embodiment, when upstream gate 16A is in its closed position, the upstream gate 16A provides a smooth approximately level surface at approximately the same elevation as support surfaces 14C. Thus upstream gate 16A effectively comprises movable skids which extend board supporting skid surfaces 14C part way across opening 14D. Similarly, downstream gate 16B effectively comprises movable skids which extend board supporting skid surfaces 14C part way across opening 14D, toward upstream gate 16A. If a larger opening 14D is desired, a longer gate 16A may be employed.
In moving from its closed position to its open position, downstream gate 14B moves primarily upwardly into and across path P such that a selected board B is diverted to pass beneath downstream gate 16B into opening 14D. The selected board B can then fall through opening 14D into bin 12.
Providing an upstream gate 16A that moves in a primarily horizontal direction between its open and closed configurations has the advantage that gate 16A can be made to operate without blocking path P and also without preventing a board that has already entered opening 14D from falling into bin 12. As long as the portion of opening 14D adjacent to leading edge 21A of upstream gate 16A (see
When returning to its closed position, upstream gate 16A may occasionally make contact with a falling board, but such contact is in a direction to cause the board to fall into bin 12 and cannot cause a jam. Therefore it is not necessary to delay the closing of upstream gate 16A to allow time for a board to fall completely past upstream gate 16A.
Contact between a board B in opening 14D and an upstream gate 14A that is being actuated in the downstream direction toward its closed configuration will merely push the falling board B toward the downstream side of opening 14D. A leading edge 21A of gate 16A may optionally be made concave to reduce the likelihood of contact between leading edge 21A and a falling board B. Leading edge 21A may also prevent boards B from bouncing into a position where they could cause jamming of gate 16A. Leading edge 21A may be vertical or nearly so when gate 16A is nearing its closed configuration. In some embodiments, gate 16A provides a ramp angling from upstream edge 19A into bin 12 when upstream gate 16A is in the open configuration.
Upstream gate 16A may move substantially parallel to path P. For example, upstream gate 16A may move in an arc with an apex that is approximately tangential with path P. In some embodiments upstream gate 16A moves through an angle of 50° or less between its open and closed configurations.
In some embodiments an elevation of downstream corner 19A of upstream gate 16A varies by no more than about one inch as upstream gate 16A moves between its open and closed configurations. In some embodiments, downstream corner 19A of gate 16A crosses a vertical line extending through pivot axis 18A as gate 16A is actuated between its open and closed configurations. In some embodiments, when the upstream gate is in the closed configuration, a downstream end of the upstream gate is within 10 or 12 degrees of vertical, as measured from pivot axis 18A.
In some embodiments, gate 16A comprises a plurality of arms. The plurality of arms optionally have upper edges that are arcuate. The centers of curvatures of the arcuate upper edges of the arms of gate 16A may coincide with pivot axis 18A.
In the embodiment illustrated in
Arms 23A extend from a shaft 24A. Arms 23A are offset in the transverse direction from skids 25 which carry surfaces 14C such that upstream gate 16A can move between open and closed configurations as described above. In some embodiments, shaft 24A is mounted in bearings with its longitudinal axis lying along pivot axis 18A such that gate 16A can be actuated between its open and closed configurations by rotating shaft 24A.
Downstream gate 16B also comprises a plurality of arms 23B that are spaced apart across the width of lumber sorter 10. Arms 23B extend from a shaft 24B. Arms 23B are offset in the transverse direction from skids 25 which carry surfaces 14C and from arms 23A of upstream gate 16A such that downstream gate 16B can move between open and closed configurations as described above. In some embodiments, arms 23B and arms 23A are interleaved. In some embodiments, shaft 24B is mounted in bearings with its longitudinal axis lying along pivot axis 18B such that gate 16B can be actuated between its open and closed configurations by rotating shaft 24B.
Controller 52 receives an input 55A from an encoder 54 mounted to provide an output indicative of the positions of lugs 14B of conveyor 14. Encoder 54 may, for example, comprise a rotary encoder driven by a drive motor or drive shaft for conveyor 14. Controller 52 also receives an input 55B that indicates which bin 12 should receive the board B being carried by each lug 14B. This information may, for example, come from a lumber grading system. For each board B, controller 52 determines based on input signal 55A when the board is approaching the diverter 16 for the bin into which the board will be sorted and controls the corresponding actuators 17A and 17B to move gates 16A and 16B of the corresponding diverter 16 to the open configuration. After the board has been diverted into the correct bin, controller 52 returns gates 16A and 16B to their closed configurations.
In some embodiments, controller 52 implements a “lazy” procedure in which a diverter 16 is kept in its open position in cases where a sequence of two or more boards are to be delivered to the same bin. The diverter may be actuated to its closed configuration after the last board in the sequence has been diverted into the bin.
The maximum opening of diverter 16 determines the maximum width of boards that can be effectively sorted using diverter 16. Providing diverters having two gates 16A and 16B allows a desired maximum opening to be achieved with a relatively small downstream gate 16B. In some embodiments, gate 16B may be shortened due to the existence of gate 16A, since boards B are able to begin falling before reaching gate 16B.
In some embodiments, downstream gate 16B extends across between 60% and 90% or 65% to 80% in some embodiments of the width of opening 14D when downstream gate 16B is in the closed configuration. For example, in such embodiments, if opening 14D is 14 inches wide, downstream gate 16B may extend in the range of 9 to 12½ inches into opening 14D when in the closed configuration.
The length of gate 16A may be selected based at least partially, on the length of gate 16B. In some embodiments, upstream gate 16A extends across between 30% and 50% of opening 14D when upstream gate 16A is in the closed configuration. For example, in such embodiments if opening 14D is 14 inches wide, upstream gate may extend between 4 and 7 inches into opening 14D when in the closed configuration.
A smaller gate 16B may be lighter and/or have a smaller moment of inertia and may be actuated to move between open and closed configurations relatively quickly with lower forces and reduced wear and tear on equipment as compared to the case where a longer single gate is used to provide a diverter having an equivalent maximum opening. Another advantage of a shorter gate 12B is that the time during which actuation of the gate must be inhibited because a preceding board is on top of the gate is reduced. For a given speed of conveyor 14, the time required for conveyor 14 to carry a preceding board across a shorter gate is smaller than would be required to carry the same board across a longer gate. A further advantage of the illustrated configuration is that the upstream edge of the downstream gate is downstream relative to the upstream edge of the opening and so downstream gate may be actuated later without interfering with an approaching board.
After downstream gate 16B has been opened to divert a board, it must be possible to close downstream gate 16B in time to allow a subsequent board to pass over downstream gate 16B. This requires upstream tip 19B of downstream gate 16B to reach its closed position before the leading edge of an approaching board reaches the same location. Because downstream gate 16B is shorter than a conventional single diverter gate, a greater clearance from the tip of downstream gate 16B to the leading edge of an approaching board allows conveyor 14 to travel at a higher speed without risk of interference between the primary diverter gate and approaching boards.
Upstream gate 16A may commence opening (
As soon as board B0 has passed over downstream gate 16B, downstream gate 16B may commence opening (
It is not mandatory that gates 16A and 16B are actuated at the same times.
After board B1 has passed below downstream gate 16B, downstream gate 16B can begin to close (
In a lumber sorter that includes diverters as described herein, it is not mandatory that all bins have the same type of diverter. For example, in some embodiments a sorter has diverters as described herein for bins at the upstream end of the sorter and conventional diverters for bins at the downstream end of the sorter.
Sorters as described herein may be optimized for different operating environments. In a sawmill sorter application, the geometry of gates 16A and 16B is selected to allow the widest board produced to be sorted. For example, boards may range in width from two or four inches to twelve inches. In a sawmill, boards of all widths may be randomly mixed together, so in sawmill applications diverters 16 may be designed and timed to handle the widest boards (which present a worst case for timing problems) at all times.
In a planer mill application it is common that all boards processed during a batch run, which may last for hours or days, will have the same width. This presents an opportunity to optimize the timing of operation of downstream gate 16B for best performance for each width of board. For example, during a run of four inch wide boards, there is a greater distance from the trailing edge of a board to the leading edge of the following board. This allows the timing of the primary diverter gate opening and closing to be based on a higher conveyor speed than would be possible when running twelve inch wide boards. Particularly for such applications a controller may automatically vary timing of downstream gate 16B and/or upstream gate 16A for best performance based on board width. In some embodiments a sensor measures the width of each board entering the sorter. In other embodiments a controller for the sorter receives information specifying the width of each board entering the sorter (e.g. from a saw mill control system). In some embodiments a user interface allows a user to specify a width for all boards to be processed by the sorter.
In an application such as a planermill where only one width of boards is processed during a batch run, the controller may be programmed to set the timing of movements of gates 16A and 16B so as to maximize the lug rate for each width of board.
It can be appreciated from the foregoing that certain embodiments have certain advantages over conventional lumber sorters which have a single diverter gate. These advantages may include:
While a number of exemplary aspects and embodiments are discussed herein, those of skill in the art will recognize certain modifications, permutations, additions and sub-combinations thereof. Some non-limiting examples of such modifications are:
While a number of exemplary aspects and embodiments have been discussed above, those of skill in the art will recognize certain modifications, permutations, additions and sub-combinations thereof. It is therefore intended that the following appended claims and claims hereafter introduced are interpreted to include all such modifications, permutations, additions and sub-combinations as are within their true scope.
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Number | Date | Country | |
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20170157650 A1 | Jun 2017 | US |