Fabrication System For Continuously Fabricating Graded Extended Length Lumber With Maximum Grade Utilization Of Input Low Quality Raw Lumber

Abstract

An extended length graded lumber fabrication system features a number of fabrication stages along a substantially continuous fabrication path providing high through put fabrication of graded lumber of extended length from low quality raw lumber. The fabrication stages include reject recognition stages, a supply lumber grading stage, a finger jointing stage and a final grading stage for the extended length lumber. The fabrication system is configured in conjunction with the particularities of low quality raw lumber to minimize grade fluctuations, increase grade bandwidth and minimize raw lumber waste during fabrication of extended length graded lumber, which may be used in wooden truss joists. The use of low quality raw lumber cut from small diameter tree trunks is environmentally beneficial. It contributes to preserve old growth and to use lighter and environmentally less invasive timber harvesting machinery and techniques.

Description

FIELD OF INVENTION

The present invention relates to fabrication systems and plants for fabricating extended length lumber. In particular, the present invention relates to fabrication systems and plants for continuously fabricating extended length graded lumber of low quality raw lumber.

BACKGROUND OF INVENTION

In the field of architectural construction, lumber is an important structural material needed in variable grades and lengths for trusses, wall frames and the like. Well known fingerjointing techniques are employed in the lumber industry to provide lumber at lengths independently of the length of the available raw lumber. Fingerjointing is also used to provide lumber substantially without lumber strength degrading elements such as wood eyes, wanes and bents. The grading of the lumber on the other hand is accomplished by well known machinery through which the lumber may be continuously feed. The minimal length of individual finger jointed pieces is determined by method and fabrication system by means of which extended length lumber may be economically feasible mass produced. At the time of this invention, the minimal length of individual finger jointed pieces and consequently the spacing between finger joints of common extended length lumber is down to about 1 foot. As may be well appreciated by anyone skilled in the art with reducing lumber piece length a larger percentage of the raw lumber may be utilized. Lumber utilization becomes increasingly important as strength degrading lumber elements increase. Therefore, there exists a need for a fabrication system that provides for economically feasible fabrication of extended length lumber with spacing between finger joints of less than 1 foot. The present invention addresses this need.

For environmental benefit it is desirable to utilize low quality raw lumber that may be cut from small diameter tree trunks, which may contribute to preserve old growth and may promote lighter and environmentally less invasive timber harvesting machinery and techniques. Unfortunately, low quality raw lumber has a relatively large percentage of wanes, wood rind, wood eyes, bents and other strength degrading elements that degrade the technical and economic feasibility of low quality raw lumber particularly for fabricating graded structural lumber in common fabrication systems and plants. Nevertheless, low quality raw lumber such as for example well known US No. 2 type utility lumber has a theoretical content of at least 75% of well known 1650 grade and higher. Therefore, there exists a need for a fabrication system and method for continuously fabricating graded extended length lumber with maximum grade utilization of input low quality raw lumber. The present invention addresses also this need.

SUMMARY

An extended length graded lumber fabrication system features a number of fabrication stages along a substantially continuous input-to-output fabrication path providing high through put fabrication of graded lumber of extended length in conjunction with the particularities of low quality raw lumber. The fabrication stages include reject recognition stages, a supply lumber grading stage, a lumber sorting stage with additional graded lumber buffer storage paths diverting off the continuous input-to-output fabrication path, a lumber length extension stage and an extended length grading stage.

The reject recognition stages may include a lumber appearance inspection and out-sorting stage, a moisture measuring stage and a grain inconsistency scanning stage. At a reject cutout and grade separation stage lumber strength degrading elements rejected in the previous scanning stage are cut out. Lumber segments with different grade ratings are also separated. The reject cutout and grade separation stage is computerized controlled in accordance with grade, grain inconsistency information obtained at their respective stages. Grade sorted nominal and shortened length lumber propagates along secondary and tertiary graded lumber buffer storage paths onto a storage paths switching stage at which buffer storage requirements of the continuously processed supply lumber are dynamically adjusted for a continuous buffer storing and grade selective in-feeding into the continuous input-to out fabrication path immediately prior to the lumber length extension stage.

At the lumber length extension stage well known finger jointing machinery joints the individual graded and reject cleared lumber pieces into a substantially endless single grade lumber string. Part of the lumber length extension stage may also be a well known finger joint proof loader and a travel saw. The finger joint proof loader tests the finger joints according to well known specific finger joint test criteria, which differ from lumber grading criteria. The travel saw cuts computerized controlled the endless lumber coming from the finger jointer into the final extended length and cuts out failed finger joints as well as grade transitions after a dynamic grade fabrication change in the fabrication system. Due to the lumber grading prior to the lumber length extension stage, grade fluctuations of the endless lumber string are brought to a minimum. In the second lumber grading stage the grade of the extended length lumber is verified in accordance with existing grading requirements at the end of the extended lumber fabrication.

Well known chord(s) and/or well known web strut(s) of a well known wooden truss joist may be made of the single grade extended length lumber fabricated by fabrication system of the present invention.

The fabrication system may also feature a reject back insertion path diverting off the continuous input-to-output fabrication path following the travel saw and terminating at begin of the continuous input-to-output fabrication path where the raw lumber is in-feed. The raw lumber, the failed finger joint lumber and grade transition lumber may define together with eventual other scrap lumber like from truss fabrication the supply lumber.

Two separate well known lumber testing machines are preferably employed at the respective first and second lumber grading stage. Nevertheless, the scope of the invention includes an embodiment in which a single lumber grading machine is employed such that the first and second lumber grading stages coincide. Consequently, the continuous input-to-output fabrication path crosses at the coinciding first and second lumber grading stages.

Dual lumber grading is highly advantageous in minimizing grade fluctuations in the final extended length lumber. Secondary and tertiary graded lumber buffer storage paths in combination with the automated lumber sorting and buffer storage path switching provide for economic mass production of single grade extended length with finger joint spacing of less than 1 foot down to about 4 inches. The tertiary lumber buffer storage path and the reject back insertion path assist also in increasing fabrication economy by reducing lumber waste. The secondary and tertiary lumber buffer storage paths are parallel to the continuous input-to-output fabrication path with computer controlled switching gates that provide together with buffer storage along the individual paths for real time grade switching during extended length lumber fabrication. In summary, minimized grade fluctuations in the final extended length lumber, extended lumber grade bandwidth, reduced lumber waste and real time grade switching contribute to a maximum utilization of input low quality raw lumber. In addition, dynamic grade transitions are accomplished without interrupting the fabrication flow. This is an important aspect in particular in combination with utilized low quality raw lumber and mass fabricated truss components with grade variations tailored to the well known diverse needs in architectural constructions,

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1a is a schematic prior art figure of standard quality raw lumber samples.

FIG. 1b shows a schematic prior art figure of low quality raw lumber samples as preferably utilized in the present invention.

FIG. 2 depicts a block diagram of a representative first embodiment of the invention.

FIG. 3 is a block diagram of a representative second embodiment of the invention.

FIG. 4 shows a schematic floor plan of a fabrication system according to the block diagram of FIG. 3.

FIG. 5 depicts a schematic wooden truss joist.

DETAILED DESCRIPTION

For the purpose of general understanding of the present invention in combination with the particularities of low quality raw lumber, prior art FIGS. 1a and 1b schematically depict a representative assortment of standard quality lumber SQ and low quality lumber LQ. The standard quality lumber SQ of FIG. 1a may be in minimum grade x along sections LGX. Standard quality lumber SQ has limited number of wood eyes WE and other well known lumber strength degrading elements and/or defects. Certain standards for lumber straightness may also apply to the standard quality lumber SQ

Low quality lumber LQ depicted in prior art FIG. 1b may be of a length between 1-20 feet, with an increased number of lumber strength degrading elements and/or defects such as, wood eyes WE, rinds RD, wanes WN and other well known grain inconsistencies. Standards for straightness may be also lower than in standard quality lumber SQ. The resulting minimum utilizable grade length LG1-LG4 in a low quality lumber LQ may be down to 4 inches. In case of well known United States No. 2 utility lumber, about 75% of the low quality LQ boards with their grade lengths LG1-LG4 of well known 1650 grade and higher.

For an economically and technically feasible fabrication of single grade extended length lumber from low quality lumber LQ, certain fabrication steps, stages and paths are introduced in the present invention to account for the particularities of low quality raw lumber LQ. Such particularities may include the minimum utilizable grade length LG1-LG2 of down to 4 inches, as well as larger grade fluctuations.

As shown in FIG. 2, a first embodiment of the invention includes the method steps 10 of providing generic lumber, followed by the step 13 of inspecting lumber pieces for defects and/or insufficiencies. The side step 131 of removing rejected pieces takes place in conjunction with step 13. Step 13 may include but is not limited to well known visual inspection, well known moisture scanning, and/or well known wood eye scanning. The next step 16 includes initial lumber piece grading into grades A-N and the associated step 162 of associating grade information with the graded lumber pieces. Step 16 and 162 may be performed by a well known lumber grading machine such as the METRIGUARD™ Model 7200 lumber tester. In the consecutive step 22, the lumber pieces are grade sorted in association with the grade information of step 162. In conjunction with step 22, grades B-N lumber pieces are buffer stacked in side step 221. Following both step 22 and step 221 is step 28 in which grade selective in-feeding of grade A-N lumber pieces is performed followed by step 30 of finger jointing the in-fed grade selected lumber pieces into a single grade A-N endless lumber. The endless lumber is then proof loaded in step 32 and in the associated step 322, a finger joint failure information is associated with the corresponding endless lumber location. After step 32, the single grade A-N endless lumber is lengthened into extended length single grade lumber and failed finger joints are removed in step 34. In a final grading step 36, the extended length lumber pieces are graded.

Steps 10, 13, 16, 22, 28, 30, 32, 34, 36 take place along a substantially continuous input-to-output fabrication path CP along which the lumber is substantially continuously propagating as single pieces and/or in stacks. The step 221 takes place along a secondary graded lumber buffer storage path SP. The secondary graded lumber buffer storage path SP diverts off the continuous input-to-output path CP following step 22 and rejoins the continuous input-to-output fabrication path CP at beginning of step 28.

In FIG. 3, a second preferred embodiment of the invention includes the method steps 10 of providing generic raw lumber, followed by the step 12 of in-feeding supply lumber pieces including the raw lumber and return in-fed lumber from steps 144 and 342. After scanning lumber moisture in step 18, lumber appearance is inspected in step 14 and excess moisture boards are removed in step 142 The side step 141 of removing rejected pieces that did not pass the appearance inspection takes also place in conjunction with step 14. Appearance inspection is preferably performed by trained personnel. The removed moist lumber may be dried as in step 143 and return in-fed as in step 144. The repeated appearance inspection of dried lumber warrants that well known excess lumber bending or well known lumber cracking that may occur during drying are recognized and removed. Moisture scanning of step 18 may be accomplished by a well known WAGNER™ Apex Moisture Detector.

The next step 16 includes initial grading of the supply lumber pieces into grades A-N and the associated step 162 of associating grade information with the graded lumber pieces. Steps 16 and 162 may be performed by a well known lumber grading machine such as the METRIGUARD™ Model 7200 lumber tester. The lumber pieces propagate along the continuous input-to-output fabrication path CP from the initial lumber grading towards the following step 20, in which the lumber pieces are scanned for grain inconsistencies such as wood eyes WE. The grain inconsistency information is associated with the lumber pieces in associated step 202. Steps 20 and 202 may be performed by a well known NEWNESS™ Advantage Scanner.

In the consecutive step 22, the nominal length lumber pieces grain inconsistency testing are grade sorted in association with the grade information of step 162. In conjunction with step 22, grades B-N nominal length lumber pieces are secondary buffer stacked in side step 221. Nominal length in context with the present invention means the length of the raw lumber without scrap lumber and finger joint failure lumber. The nominal length in a preferred embodiment of the invention is between 2-20 feet. Following both step 22 and step 221 is step 24 in which grain inconsistencies and excess moisture portions M are removed from the lumber pieces. In conjunction with step 241, grades A-N cut lumber pieces are tertiary buffer stacked in side step 241.

Next is step 28 in which grade selective in-feeding of grade A-N lumber pieces is performed followed by step 30 of finger jointing the in-fed grade selected lumber pieces into a single grade A-N endless lumber string. The endless lumber string is then proof loaded in step 32 and in the associated step 322, a finger joint failure information is associated with the corresponding endless lumber location. After step 32, the single grade A-N endless lumber string is lengthened into extended length single grade lumber in step 34. Lumber portions including the failed finger joints and/or grade transitions are removed in the corresponding side step 341. The cut out lumber portions are kept at a predetermined length for return in-feeding them at step 12 as indicated by step 342. In a final grading step 36, the extended length lumber pieces are graded.

Steps 10, 12, 14, 16, 18, 20, 22, 24, 28, 30, 32, 34, 36, 38 take place along a substantially continuous input-to-output fabrication path CP along which the lumber is substantially continuously propagating as single pieces and/or in stacks. The step 221 takes place along a secondary graded lumber buffer storage path SP. The secondary graded lumber buffer storage path SP diverts off the continuous input-to-output path CP following step 22 and rejoins the continuous input-to-output fabrication path CP at beginning of step 28. The step 241 takes place along a tertiary graded shortened lumber buffer storage path TP. The tertiary graded shortened lumber buffer storage path TP diverts off the continuous input-to-output path CP following step 24 and rejoins the continuous input-to-output fabrication path CP at beginning of step 28. Steps 341 and 342 take place along a reject back insertion path RP diverting off the continuous input-to-output fabrication path CP following step 34 and terminating at beginning of step 12.

The schematic floor plan of a preferred embodiment of the fabrication system 200 is shown in FIG. 4. Along the substantially continuous input-to-output fabrication path CP propagate lumber pieces of predetermined cross section such as 2 by 4 inches on well known conveyor and/or other transport systems commonly utilized for piecewise and/or stack wise continuous lumber transport. At the begin of the continuous input-to-output fabrication path CP is a multiple lengths supply lumber in-feed stage including a hydraulic break down hoist 2122 and small piece conveyor 2124. The hydraulic break down hoist 2122 breaks down stacked nominal length lumber that is in-fed via a first fork lift access 2101 and an in-feed deck 2121. Short length lumber pieces, which may be down to 1 foot length are in-fed into the continuous input-to-output fabrication path CP via a second fork lift access 2102 connecting to the small piece conveyor 2124.

After the moisture scanner 218, a lumber appearance inspection and out-sorting stage may include an inspection deck 214 and a third forklift access 2141. On the inspection deck, the spread lumber pieces gradually move along in lateral direction at a speed suitable for a preferred visual inspection and manual reject removal by trained personnel. The rejected boards are stacked at the third forklift access 2141 for removal.

Following the inspection deck 214 is a lateral chain feeder 2161 that redirects the remaining boards into longitudinal propagation direction towards the lumber tester 2162 of a first lumber grading stage, the moisture detector 218 of a moisture measuring stage, and the scanner 220 of a grain inconsistency scanning stage. Then the lumber enters an automated lumber sorter 222 in which the lumber pieces are laid out for further processing and/or out-sorting as part of a nominal length lumber grade sorting stage. From the sorter 222, a nominal length conveyor 2222 receives nominal length boards grade B-N that have passed the grain inconsistency scanning. The sorter 222 may utilize grade information from the first lumber grader 2162 and grain inconsistency information obtained from the scanner 220 to perform the out-sorting in a computerized controlled fashion. Ink marks imprinted on the lumber in the lumber grader 2162 and/or the scanner 220 may be recognized by well known machine vision systems, which may include a camera. Grade marking may be for example via bar code or color code. Additionally, length information may also be coded onto the shortened length boards. In context with the present invention grade A may be preferably a grade most common for the particular quality raw in-fed lumber. In a representative case of No. 2 utility raw lumber, grade A may be the well known 1650 grade. Hence, the highest capacity throughput directly along the continuous input-to-output fabrication path CP is utilized in the most economic fashion. The nominal length conveyor 2222 terminates at a storage path switching stage in the preferred configuration of a pull table 225 and a turn table 2252. At the pull table 225 the nominal length boards are manually sorted at secondary pull cart accesses 2225 in single grade stacks. The secondary graded lumber buffer storage path SP, which begins at the secondary pull cart accesses 2225 and terminates at the pull-cart in-feed 2287 may include well known temporary buffer storage locations not shown on the schematic plan.

Behind the automated lumber sorter 222 is a reject cutout and grade separation saw 224, from which a short piece conveyor 2242 diverts. A waste bin 2243 that automatically captures the out cut rejected lumber portions is placed along the short piece conveyor 2242. Also part of the storage path switching stage are tertiary cart accesses 2245, turn table 2252 and tertiary first fork lift accesses 2246. Lumber pieces having portions that failed the grain inconsistency scanning and/or have more than one grade LG1-LG4 along their length are computerized controlled diverted towards the saw 224 where the rejected lumber portions are cut out in accordance with the grain inconsistency information and grade lengths LG1-LG4 are separated in accordance with grade information from the supply lumber grader 2162. The remaining grade A-N shortened length lumber pieces end up on the pull table 225 together with the grade B-N sorted nominal length boards. Employing a storage path switching stage for grade selective sorting of nominal and shortened length boards provides necessary flexibility to adjust to varying grade compositions of the supplied and/or raw lumber. On the pull table 225 boards in the length down to about 2 feet are sorted. On the adjacent turn table 2252, boards of lengths down to about 6 inches are manually grade sorted stacked on pallets on the tertiary first fork lift accesses 2246 for further fork lift manipulation. The tertiary graded lumber buffer storage paths TP, which begin at the tertiary accesses 2245, 2246 and terminate at the in-feeds 2287 and 2280 may include well known temporary buffer storage locations not shown on the schematic plan. The manually operated pull table 225 and turn table 2252 may be substituted by an automatic tables and/or well known robotic equipment as may be well appreciated by anyone skilled in the art

The remaining grade A nominal length lumber passes through a stacker in-feed 2261, a stacker 2262 and stack jump roll case 2263, where it is either directly redirected via a stack cross over rollcase 2281 towards a single grade lumber length extension stage or buffer stored in between an stack out-feed deck 2264 and stack in-feed deck 2283. Stack out-feed deck 2264 has a forth fork lift access 2265 and the stack in-feed deck 2283 has a fifth fork lift access 2282.

Buffer storing of the nominal length grade A lumber may be at a well known buffer storage location (not shown) along the continuous input-to-output fabrication path CP. It may be utilized while grade B-N lumber is in-fed at the grade selective in-feeding stage, which further includes a stack jump rollcase 2284 for alternately receiving nominal length grade A lumber from stack crossover rollcase 2281 or from stack in-feed deck 2283. Pull cart stacked boards may be manually in-fed from stack in-feed 2287 onto a singulation station at which the lumber may be held back temporarily while single grade shortened pieces are in-fed via sixth fork lift access 2280, pallet dumper 2289 and spreader conveyor 2288.

The lumber sorter 222, stack jump rollcases 2263, 2284, stack cross over roll case, singulation station 2286 and short piece conveyor 2288 with pallet dumper 2289 are computer controlled switching gates that provide together with buffer storage along the individual paths CP, SP, TP in between the switching gates for real time grade switching with substantially uninterrupted extended length lumber fabrication.

The grade selective in-fed lumber pieces are transported towards a lumber length extension stage including a well known profile machine where the ends of the lumber pieces are machined for finger jointing. The lumber length extension stage further includes well known components such as an assembler conveyor 2304, crowder 2305, curing station 2306, retarder 2307, a proof loader 232 and a travel saw 234. An incline chain deck 2302 and a corner feeder 2303 transport the lumber between the profile machine 2301 and the assembler conveyor 2304.

The endless lumber string propagating out of the curing station 2306 passes through the proof loader 232, where finger joint testing is performed in accordance with well known finger joint test criteria. Finger joint failure information is passed onto the travel saw 234 for a computerized controlled out-cutting of failed finger joints in accordance with the finger joint failure information. Failed finger joint portions as well as grade transitions are kept at a minimum length of preferably about 1 foot for out-sorting at sweep table 2344 and reinsertion via seventh fork lift access 2345 and second fork lift access 2102 via reject back insertion path RP. The travel saw 234 also cuts the endless lumber string into extended length lumber of preferably 66 feet length, which is diverted by the sweep table 2344 towards a second lumber grader 236 and a paddle stacker 2381. There, the extended length lumber is stacked and transported away via eight fork lift access 2382. The second lumber grader may be similar to the first lumber grader 2162.

In a further embodiment of the invention, a single lumber graded is utilized instead of two lumber graders 2162 and 236. Consequently, the continuous input-to-output fabrication path CP crosses at the first raw lumber grading stage coinciding with the second extended length lumber grading stage.

In FIG. 5, a wooden truss joist 300 has top chords 301, bottom chords 302 and web struts 303. Chords 301, 302 and/or struts 303 may be fabricated from extended length graded lumber fabricated as above described and/or in accordance with the above described fabrication system 200.

Accordingly, the scope of the invention described in the specification and figures is set forth by the following claims and their legal equivalent:

Claims

1. An extended length graded lumber fabrication system comprising:

a. a continuous input-to-output fabrication path;

b. a lumber reject recognition stage along said continuous input-to-output fabrication path;

c. a supply lumber grading stage along said continuous input-to-output fabrication path;

d. a grade sorting stage along said continuous input-to-output fabrication path behind said lumber reject recognition stage and said first supply lumber grading stage;

e. a single grade lumber length extension stage along said continuous input-to-output fabrication path and following said grade sorting stage; and

f. an extended length lumber grading stage along said continuous input-to-output fabrication path and behind said single grade length extension stage.

2. The extended length graded lumber fabrication system of claim 1, further comprising a secondary graded lumber buffer storage path diverting off said continuous input-to-output path behind said grade sorting stage and rejoining said continuous input-to-output fabrication path before said single grade lumber length extension stage.

3. The extended length graded lumber fabrication system of claim 1, wherein said reject recognition stage is behind said first lumber grading stage along said continuous input-to-output fabrication path, and wherein said extended length graded lumber fabrication system further comprises:

a. a reject cutout and grade separation stage following said reject recognition stage along said continuous input-to-output fabrication path;

b. a tertiary graded shortened lumber buffer storage path diverting off said continuous input-to-output fabrication path behind said reject cutout stage and rejoining said continuous input-to-output fabrication path before said single grade lumber length extension stage.

4. The extended length graded lumber fabrication system of claim 1, wherein at least a portion of said extended length graded lumber is a chord of a truss joist.

5. The extended length graded lumber fabrication system of claim 1, wherein at least a portion of said extended length graded lumber is a web strut of a truss joist.

6. The extended length graded lumber fabrication system of claim 1, wherein said extended length graded lumber has a spacing between finger joints of less than 1 foot and down to about 4 inches.

7. The extended length graded lumber fabrication system of claim 1, wherein a first lumber grader is provided at said supply lumber grading stage and wherein a second lumber grader is provided at said extended length lumber grading stage.

8. The extended length graded lumber fabrication system of claim 1, wherein a single lumber graded is at said supply lumber grading stage coinciding with said extended length lumber grading stage and wherein said continuous input-to-output fabrication path crosses at said supply lumber grading stage coinciding with said extended length lumber grading stage.

9. An extended length graded lumber fabrication system comprising:

a. a continuous input-to-output fabrication path;

b. a lumber reject recognition stage along said continuous input-to-output fabrication path;

c. a supply lumber grading stage along said continuous input-to-output fabrication path;

d. an automated lumber sorting stage along said continuous input-to-output fabrication path following said lumber reject recognition stage and said first raw lumber grading stage;

e. a secondary graded lumber buffer storage path diverting off said continuous input-to-output fabrication path at said automated lumber grading stage;

f. a reject cutout and grade separation saw following said automated lumber sorting stage;

g. a tertiary graded shortened lumber buffer storage path diverting off said continuous input-to-output fabrication path at said reject cut out and grade separation saw;

h. a storage path switching stage along said secondary graded lumber buffer storage path and said tertiary buffer storage path;

i. a single grade lumber length extension stage along said continuous input-to-output fabrication path and following said grade sorting stage; and

j. an extended length lumber grading stage along said continuous input-to-output fabrication path and following said single grade length extension stage;

wherein said secondary graded lumber buffer storage path and said tertiary graded shortened lumber buffer storage path rejoin said continuous input-to-output fabrication path before said single grade lumber length extension stage.

10. The extended length graded lumber fabrication system of claim 9, wherein at least a portion of said extended length graded lumber is a chord of a truss joist.

11. The extended length graded lumber fabrication system of claim 9, wherein at least a portion of said extended length graded lumber is a web strut of a truss joist.

12. The extended length graded lumber fabrication system of claim 9, wherein said extended length graded lumber has a spacing between finger joints of less than 1 foot and down to about 4 inches.

13. The extended length graded lumber fabrication system of claim 9, wherein a first lumber grader is provided at said supply lumber grading stage and wherein a second lumber grader is provided at said extended length lumber grading stage.

14. The extended length graded lumber fabrication system of claim 9, wherein a single lumber graded is at said supply lumber grading stage coinciding with said extended length lumber grading stage and wherein said continuous input-to-output fabrication path crosses at said supply lumber grading stage coinciding with said extended length lumber grading stage.

15. A fabrication system for continuously fabricating multiple grade extended length lumber from low quality variable length supply lumber, said fabrication system comprising:

a. a continuous input-to-output fabrication path along which lumber pieces of predetermined cross section propagate;

b. a multiple lengths supply lumber in-feed stage at begin of said continuous input-to-output fabrication path, said multiple lengths supply lumber in-feed stage being configured for receiving and in-feeding supply lumber in form of said lumber pieces in an original length and shorter;

c. a moisture measuring stage following said multiple lengths supply lumber in-feed stage along said continuous input-to-output fabrication path, wherein at said moisture measuring stage a moisture information is associated with said lumber pieces;

d. a lumber appearance inspection and out-sorting stage following said multiple lengths supply lumber in-feed along said continuous input-to-output fabrication path;

e. a supply lumber grading stage following said lumber appearance inspection and out-sorting stage along said continuous input-to-output fabrication path, wherein at said lumber grading stage a grade information is associated with said lumber pieces;

f. a grain inconsistencies scanning stage following said lumber appearance inspection and out-sorting stage along said continuous input-to-output fabrication path, wherein at said grain inconsistencies scanning stage a grain inconsistency information is associated with said lumber pieces;

g. a grade sorting stage following said grain inconsistency scanning stage along said continuous input-to-output fabrication path, wherein at said grade sorting stage said lumber pieces are computerized controlled diverted onto a secondary graded nominal length lumber buffer storage path in accordance with at least one of said grade information and said grain inconsistency information;

h. a reject cutout and grade separation stage following said grade sorting stage along said continuous input-to-output fabrication path, wherein at said reject cutout grade separation stage said lumber pieces are computerized controlled diverted towards a cutout saw and onto a tertiary shortened length graded lumber buffer storage path in accordance with said grade information and said grain inconsistency information, and wherein said cutout saw is computerized controlled in accordance with said grain inconsistency information such that portions of said lumber pieces having a grain failure are removed;

i. a grade selective in-feeding stage at which said secondary graded original length lumber buffer storage path and said tertiary graded lumber shortened length buffer storage path are rejoining said continuous input-to-output path, and wherein at said grade selective in-feeding stage at least one of said graded original length lumber and said shortened length graded lumber of a predetermined single grade are in-fed into said continuous input-to-output path;

j. a single grade lumber length extension stage following said grade selective in-feeding stage along said continuous input-to-output fabrication path, wherein said single grade lumber extension stage features: i. a finger jointer joining said at least one of said graded original length lumber and said shortened length graded lumber into a propagating endless lumber; ii. a finger joint proof loader at which a finger joint failure information is associated with an endless lumber location; iii. a travel saw computerized controlled cutting said endless lumber into said extended length lumber and out-cutting failed finger joints in accordance with said finger joint failure information; and

k. an extended length lumber grading stage along said continuous input-to-output fabrication path and following said single grade length extension stage.

16. The fabrication system of claim 15, further comprising a reject back insertion path diverting off said continuous input-to-output fabrication path behind said travel saw, wherein said reject back insertion path terminates at said multiple lengths supply lumber in-feed stage such that cutout lumber having a failed finger joint is reinserted at begin of said continuous input-to-output path.

17. The fabrication system of claim 15, wherein at least a portion of said extended length graded lumber is a web strut of a truss joist.

18. The fabrication system of claim 15, wherein at least a portion of said extended length graded lumber is a chord of a truss joist.

19. The extended length graded lumber fabrication system of claim 15, wherein said extended length graded lumber has a spacing between finger joints of less than 1 foot and down to about 4 inches.

20. A method for maximizing graded lumber output from low quality input lumber, said method comprising the steps of:

a. providing generic lumber pieces;

b. inspecting lumber pieces for at least one of defects, excess moisture and insufficiencies and removing rejected lumber pieces;

c. initial lumber piece grading into grades A-N and associating a grade information with said lumber pieces;

d. lumber piece grade sorting in association with said grade information and buffer stacking grades B-N lumber pieces;

e. grade selective in-feeding of grade A-N lumber pieces;

f. finger jointing into single grade A-N endless lumber;

g. proof loading endless lumber and associating finger joint failure information with endless lumber location;

h. lengthening single grade A-N endless lumber into extended length and removing failed finger joints in association with said finger joint failure information; and

i. final lumber piece grading.

21. A method for maximizing graded lumber output from low quality input lumber, said method comprising the steps of:

a. providing generic lumber pieces;

b. in-feeding generic lumber pieces;

c. scanning moisture of generic lumber pieces;

d. inspecting appearance of lumber pieces and removing rejected and excess moisture lumber pieces;

e. drying excess moisture lumber pieces and reinserting said dried lumber pieces at step b;

f. initial lumber piece grading into grades A-N and associating initial grade information with lumber pieces;

g. grain inconsistencies scanning and associating grain inconsistency information with lumber pieces;

h. nominal length lumber grade sorting in association with said initial grade information, said moisture information and said grain inconsistency information and secondary buffer stacking grade B-N nominal length lumber;

i. grain inconsistencies and excess moisture removing in association with said moisture information and said grain inconsistency information and tertiary buffer stacking grade A-N cut lumber in A-N grade and a-n length Aa-Nn stacks;

j. grade selective in-feeding of grade A-N lumber pieces;

k. finger jointing into single grade A-N endless lumber;

l. proof loading endless lumber and associating finger joint failure information with endless lumber location;

m. lengthening single grade A-N endless lumber into extended length, removing failed finger joints in association with said finger joint failure information and return in-feeding failed joint lumber at said step of in-feeding generic lumber pieces; and

n. final lumber piece grading.