US3618646A - Means for pressure-conditioning wood veneer for application to contoured cores - Google Patents

Abstract

Wood veneer to be bent is subjected initially, along closely spaced lines parallel to its grain, to pressures of many tons p.s.i. which disrupt its fibrous structure. The special mechanism for this purpose embodies a pair of rollers, one being circumferentially scored to impress relatively deep score lines in one face of a veneer strip which is fed between the rollers when rotated. The bearings for these rollers are supported in upstanding walls of a framework to be rested firmly upon or against extended areas of horizontal faces thereof whereby to be adequately braced against the thrust forces proceeding from the rollers when pressure engaging the veneer strips passed between them. The upstanding frame walls are spaced apart sufficiently to successively accommodate between them many veneer strips of normal widths. For accommodation of wider strips, however, one frame wall is made of two sections, one above the other with a horizontal gap therebetween through which wider veneer strips may be extended to lie in part exteriorly of the frame and beyond the proximate ends of the pressure rollers. This operation of pressure conditioning may be applied to a relatively narrow area of each strip along one edge portion thereof, or to wider areas of the strip if the latter be reversed and subjected to a second pass between the rollers. The frame so provided in one wall with a horizontal gap is so constructed and braced as to retain adequate strength for support of the two rollers, one below and the other above the gap, that its capacity for application of very high pressures to the veneer strip is assured.

Description

United States Patent [72] inventor Raymond H. Lewis Fort Lluderdlie, Fla.

[21.] Appl. No. 53,790

[22] Filed July 10, 1970 [45] Patented Nov. 9, 1971 [73] Assignee Roberts Consolidated Industries, Inc.

City oi Industry. Calli- 54] MEANS FOR PRESSURE-CONDITIONING WOOD VENEER FOR APPLICATION TO CONTOURED CORES 7 Claims. I 1 Drawing Figs.

[51] Int. Cl 827d 3/00 [50] Field of Search 144/282,

[56] References Cited UNITED STATES PATENTS 480,522 8/1892 Skekel 100/168 X 1.085.568 1/1914 Knights 72/246 1,809,681 6/1931 Elmendorf 144/282 2.812.798 11/1957 Antwerpen et a1. 100/176 2,896,68l 7/l959 Elmendorf 144/327 Primary Examiner-Donald R. Schran Almmey- Ephraim Banning, llI

ABSTRACT: Wood veneer to be bent is subjected initially.

along closely spaced lines parallel to its grain. to pressures of many tons p.s.i. which disrupt its fibrous structure. The special mechanism for this purpose embodies a pair of rollers. one

being circumferentially scored to impress relatively deep score lines in one face of a veneer strip which is fed between the rollers when rotated. The bearings for these rollers are supported in upstanding walls of a framework to be rested firmly upon or against extended areas of horizontal faces thereof whereby to be adequately braced against the thrust forces proceeding from the rollers when pressure engaging the veneer strips passed between them. The upstanding frame walls are spaced apart sufficiently to successively accommodate between them many veneer strips of normal widths.

For accommodation of wider strips, however. one frame wall is made of two sections. one above the other with a horizontal gap therebetween through which wider veneer strips may be extended to lie in part exteriorly of the frame and beyond the proximate ends of the pressure rollers. This operation of pressure conditioning may be applied to a relatively narrow area of each strip along one edge portion thereof. or to wider areas of the strip if the latter be reversed and subjected to a second pass between the rollers. The frame so provided in one wall with a horizontal gap is so constructed and braced as to retain adequate strength for support of the two rollers. one below' and the other above the gap. that its capacity for application of very high pressures to the veneer strip is assured.

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"ill 1 ll PATENTED NOV 9 IQH v INVENTOR. RAYMOND H. LEWIS ATTORNEY MEANS FOR PRESSURE-CONDITIONING WOOD VENEER FOR APPLICATION TO CONTOURED CORES A full disclosure of this invention is contained in my earlier application for patent filed Oct. 9, I967 under Ser. No. 677,495 of which this case is a division, now U.S. Pat. No. 3,54l,592.

This invention relates to a mechanism for conditioning selected areas of a strip of wood veneer whereby a degree of flexibility is imparted thereto sufficient for its self-conformation to one or more faces of a base to which it is permanently united. It involves two steps, (I) initially breaking down the grain configuration in selected areas of the wood and/or disrupting its fibrous structure, without noticeable damage thereto or change in its appearance, and (2) when initially affixed to the base, of vapor heating such conditioned areas thereof whereby to facilitate its bonding to a core, in exact conformity therewith. The present invention is concerned primarily with suitable pressure-engaging mechanism for performing the first step above noted.

Wood veneer is commonly produced with a standard thickness of about one thirty-second inch. An ever-ready tendency to crack or split requires that it be handled carefully. It is also difficult to apply such a veneer to any contoured core or base because of insufi'rcient flexibility in its body structure. Although veneered furniture is attractive and greatly in demand, application of the veneer is generally confined to relatively flat surfaces thereof. Use of the finer woods, such as walnut, cherry, maple, rosewood, etc., is attended with all these same difiiculties. It is accordingly a primary objective of this invention to provide a pressure-engaging means whereby to condition veneers of diverse woods for facile bending preliminary to application of such conditioned veneers to their permanent cores or bases, and to conforming the veneer to one or more nonplanar faces thereof. The furniture industry is but one market for this invention. Other products to benefit therefrom are frames for pictures and mirrors, mouldings, building trim, cabinet doors, stair rails, etc.

Further objects and advantages residing in the present invention relate to its adaptability to veneers of different woods some of which have commonly been rejected as too difficult for assembly with contoured bases; and to expeditious handling and treatment of wood veneers through the initial stage of conditioning prior to application thereof to any base or core.

These and other objects of this invention will appear more fully from the detailed description to follow wherein reference is made to the accompanying drawing exhibiting a suggestive embodiment of means suitable for employment of the invention.

In the drawing:

FIG. I is a front elevational view of the framework which encloses and mounts a pair of rollers, one adjustable toward and from the other to vary the clearance therebetween, the framework front wall being broken away to exhibit portions of the two rollers, also the bearings therefor;

FIG. 2 is a vertical sectional view, taken on line 2--2 of FIG. 1, showing in elevation the inside face of the divided framework end wall, together with the bearings carried thereby, but omitting the roller shafts therefrom;

FIG. 3 is an enlarged schematic view showing a piece of veneer in operative position between the two rollers, ready to be pressure conditioned;

FIG. 4 is an enlarged fragmentary section, taken on line 4- 4 of FIG. 3;

FIG. 5 is an enlarged fragmentary plan view of one end portion of a piece of veneer as it appears after being pressure conditioned;

FIG. 6 is an enlarged end elevation of the conditioned veneer piece as it appears after leaving the rollers; and

FIGS. 71 I are schematic views showing the veneer and its base during successive stages of application of the former to the latter.

The work to be operated upon, according to this invention, consists of an elongated wood veneer piece V and an elongated base C of wood, plywood, chipboard, or other suitable material. Such a base is known as a core, and will be so referred to herein. In cross section the core is substantially uniform from end to end, its length running up to perhaps 16 feet or so. Its cross-sectional contour, also uniform throughout its length, is usually such as to provide an attractive design, and may involve one or more faces, with curves convex and/or concave, connected by variously rounded corners, depending largely upon the use for which the finished product is intended. The veneer piece, by contrast, is relatively flat and inflexible, its length is usually coterminous with that of the core, and its form is generally that of a strip elongated in the direction of its grain structure. The strip width desirably is such as to cover one or more selected faces of the core when flexibilized and wrapped therearound in response to a bending operation.

Obviously a piece of normally inflexible wood veneer presents a problem when efforts are made to bend it closely around and into exact conformity with one or more faces of a core preparatory to its inseparable bonding therewith. As a first step, the veneer strip must be pressure conditioned for bending; then the faces of the strip and core which are to confront each other should receive a spread of adhesive; then the strip, still fiat, is adhesively affixed to one of the core faces; then, while so assembled, the strip and core are advanced together lengthwise adjacent to and/or between a multiplicity of agencies which subject the strip briefly to vapor heating confined to the area to be bent and then to pressure forces which bend the veneer strip around and down upon the face or faces of the core which are to be covered thereby; and finally an evenly distributed and continuing pressure is directed against the strip for a time sufficient to conform it closely to the confronting contoured face or faces of the core and to induce its bonding therewith. in a general way, this is the present mode of operation involved in the application of relatively inflexible wood veneer strips to cores which may be variously contoured on one or more of their faces. A suggestive mechanism for thus applying conditioned veneer strips to cores of diverse designs is disclosed in the Bechtold U.S. Pat. No. 3,296,056 of Jan. 3, 1967, but only when importantly modified as hereinafter noted.

This invention is concerned primarily with the conditioning unit of FIGS. 1-4 prior to subjecting the veneer strip to the bending steps outlined in FIGS. 7-11. These two stages in the method may be performed separately, each independent of the other, or the means therefor may be combined into a single mechanism. Each strip of wood veneer V of a desired width is initially passed through the rollers of the conditioning unit. Thereafter it is stacked along with other similarly conditioned wood veneer pieces, awaiting further treatment by the bending unit at a convenient time; or, alternatively, each such veneer strip, upon delivery from the conditioning unit, may immediately be operated upon by the several instrumentalities comprised in the bending unit. With these preliminary observations, the conditioning unit of FIGS. 1-4 will now be described.

A sturdy type of machine is used, placed desirably between the ends of two tables arranged in tandem (not shown), one for holding a supply of veneer pieces ready for conditioning, and the other for accommodating such pieces after conditioning. A stout stand having a top 15 fixedly supports an enclosing framework comprising an upstanding end wall 16 opposite a two-part end wall formed of upper and lower plates 17 and 18 spaced slightly apart to leave a gap 19 therebetween. The end walls are fixedly joined, as by bolts 20, to opposite ends of upstanding elongated front and rear walls 21 and 22 respectively. Between the end walls is extended a pair of horizontal rollers U and L, one above the other with a very slight potential clearance therebetween that is aligned with the gap 19 in one end wall. The front and rear walls are each provided with a horizontal slot 23 in line with the gap I9 and extending away therefrom for the major portion of the lengths of the two rollers U and L.

The lower roller L is mounted fast upon a shaft 25 which is rotatably supported at opposite ends within bearing blocks 26, one affixed to each end wall 16 and 18. Similarly the upper roller U is carried upon a shaft 27 whose opposite ends are mounted in bearing blocks 28, one affixed to each end wall 16 and 17. A sprocket wheel 29 is mounted fast on the shafi 25 near one end thereof to receive thereover a chain 30 adapted to be driven from a reduction gear 31 to which power is transmitted from a motor M. The lower bearing blocks 26 are fixedly anchored in place with the aid of bolts 32 which traverse the walls l6 and w for threaded engagement with the blocks. A bottom support for each bearing block is also provided in the form of a bar 35 in engagement with its under face; a substantial part of this bar is closely fitted within a recess 36 which is extended horizontally across the end wall to which it is connected as by bolts 37. Since this bar abuts the lower face of the recess and also the bearing block thereabove-both confronting faces lying in a horizontal plane-a very substantial vertical support for the latter is provided. Without this abutment bar, the bolts 32 would tend to shear off in response to the tremendous pressure generated.

The upper bearing blocks 28 are very slightly vertically adjustable. As by bolts 41 traversing the walls 16 and 17 and vertically elongated slots 42 in the blocks, provision for slight vertical movement is made. Overlying the upper face of each of these blocks are horizontally elongated wedge blocks 45 and 46, the former being the upper one. Bolts 47 are extended through this block and the proximate end walls to fixedly secure the upper wedge block 45 in place. The lower wedge block 46, however, is mounted for sliding movement in a horizontal direction, thereby to shift its body vertically whenever its beveled face is advanced along the similar face of the upper wedge block. A support for each lower wedge block which permits such limited movements to take place is provided by bolts 50 which are anchored in the end walls 16 and 17 to extend therefrom through oblique slots 51 formed in the block 46. The lower wedge block rests upon the upper face of the proximate bearing block 28 to exert a variable pressure thereupon. To provide a fixed abutment for each upper wedge block whereby it may resist vertical movement in response to great upward pressures transmitted from the wedge block therebelow, I provide an enclosing recess 54 wherein a substantial portion of both blocks 45 and 46 may be fitted. Each recess is extended horizontally across the end wall 16 or 17, as the case may be, its upper face adapted to abut the top face of the upper block 45. Operation of the movable wedge block is facilitated by a bolt 57 in rotatable connection therewith and extended through the front wall 21 with which it is in threaded engagement. A locknut 58 fitted upon the bolt is adapted to engage with the front wall with varying degrees of friction, depending upon its adjusted position. It will be noted that the uppermost vertical position of the upper roller U is fixed in response to rotation of the operating bolt 57 working through the wedge blocks 45 and 46; also that the wedge blocks, being partly enclosed within the end walls, serve as horizontal abutments which are adjustable to effectively prevent any upward movement of the upper roller U beyond a selectively fixed point, thereby limiting its clearance with the lower roller L.

The maximum spacing at the nip between the rollers is somewhat less than the thickness of the veneer pieces to be passed therethrough. Assuming the veneer thickness to be about 0.03 1-0.032 inch, the operating clearance between the rollers U and L should be adjusted to about 0.017 inch, or nearly one-half the thickness of the veneer (FIG. 3). The surface of the lower roller is specially formed to provide a multitude of closely spaced projections capable of pressing into the body of the wood to produce therein indentations which have the effect of breaking down its grain configuration and/or disrupting its fibrous structure. As a result, resistance to bending of the veneer around axes parallel with its grain is somewhat reduced, although its body is still generally inflexible. As a simple form of projections suitable for the lower roller l... circumferential scorings are quite effective. A desirable spacing of the score lines s (see FIG. 4) is 0.030 inch, with uniform depths therebetween of 0.010 inch. A single pass between the rollers requires that the veneer yield momentarily to the clearance provided thereat, viz, about 0.017 inch, but with emergence from between the rollers the veneer tends to expand to about 0.029 inch (FIG. 6). The effect upon the fibrous structure of the veneer body, resulting from the pressure forces transmitted momentarily to its under face, is primarily to condition it for subsequent flexibilization. A return to substantially its normal thickness tends to follow, but this is unimportant. it is important, however, that the pressure forces at the nip of the rollers be very considerable, ranging perhaps from 30 to 50 tons p.s.i. The upper roller U, it will be noted, is free to occupy a very slightly lower position when not in use. At such times it may even rest upon the lower roller with no clearance therebetween. Advance of a veneer piece into the nip between the rollers forces the upper roller to move upwardly as far as permitted by adjustment of the wedge block 46. This adjustment may be very fine, thereby controlling accurately the degree of compressive forces exerted. There is no lost motion or play between the adjusting components involved-an important consideration if generation of desired compressive forces is to be achieved with precision.

To operate dependably and with a wide safety margin where pressures of many tons are involved, it is necessary that the four walls enclosing the rollers provide mountings therefor that are strong and heavy. For this purpose, steel plates of ap proximately 1% inch in thickness are suggested. Particularly is more than usual strength required for such a roller framework because of the horizontal slots 23 and gaps 19 provided in the front and rear walls and at one end thereof for a special purpose. This is to permit accommodation between the rollers of veneer pieces whose widths may vary widely-from less than 6 inches up to perhaps 2 feet or more. Assuming a length for each roller of 1 foot, any veneer piece up to that width can be conditioned by the rollers in one pass. Wider veneer pieces can also be operated upon, the rollers optionally confining their engagement with the veneer to one side portion thereof in a first pass and to an opposite side portion in a second pass. Furthermore, it is possible to run a wide veneer piece through the rollers when only a single edge portion thereof is to be conditioned. in such a case, a major portion of the veneer piece would not be engaged by the rollers, but would remain outside the housing beyond the gap 19 in one end wall. These are some of the several advantages to be derived from use of compressor rollers whose clearance is extended out through the slots and gap of the framework walls permitting veneer pieces of varying widths to be moved in, out, and through the machine as circumstances may require from time to time.

Each veneer piece, when conditioned as above described, is ready for application to its core or base and to be conformed thereto-a second stage of the operation. This involves initially the application of a spread of suitable adhesive to the raw face of each veneer piece. Desirably this is a contact adhesive which may be conveniently applied in the form of a spray. The adhesive spread a so applied adds considerable strength to the veneer. It is not necessary that the adhesive be as completely dry as when applied to a plastic material, since the porous character of thin wood veneer promotes escape of the volatile solvents from the adhesive. A similar spread b of adhesive is also applied to each face of the core which is to be covered by the veneer in the operation of bending. With the adhesive spreads so applied, the wood veneer, still relatively flat, is then indexed to the core. This adhesive union between the veneer and core is initially confined to a relatively narrow band extending the full length of the work which is then ready to be advanced lengthwise through a bending machine whose essentials will now be described.

A plurality of aligned knurled rollers 59 interconnected for rotation in unison provides a moving support for the work when rested thereon as indicated in FIGS. 7-11. The cross sectional contour of the core may well determine whether the work shall be positioned with the veneer down or up during its movement through the machine. The simple contour of the core, which is shown in these figures at that of a plain rail, makes it advantageous that the work proceed through the machine with the veneer on the down face of the core (FIG. 7). Its movement through the machine is continuous, one piece of work following closely upon another, when handlaid in operative positions by experienced workmen.

The first agency to operate upon the work is a heat-applying means. The heat transmitted to a veneer of wood must be applied uniformly and with care, otherwise the veneer will tend to become brittle rather than flexible. To meet this problem, the heat is delivered in the form of vapor into the path of movement of the work at a point proximate to its raw face. For this purpose, an electrically operated vapor-generating unit 60 may be utilized, with a short pipe line 61 therefrom terminating in a plurality of spray jets or nozzles 62 proximate to the raw face of the veneer. The vapor discharged from these jets forms a stationary cloud through which the work is advanced during a time interval sufficient for safe and effective heating of the veneer and without noticeable increase in its moisture content. A speed of as much as 20 feet per minute for advance of the work is permissible. As an example, the vapor may be steam generated from water at approximately 40 p.s.i., this being a temperature of close to 350 F., and relatively dry. Enough moisture still remains in the vapor, however, to flexibilize the work in the ensuing bending operation.

This high-pressure application of vapor disrupts the cellulose structure in the veneer which then becomes flexibilized to permit prompt subsequent bending through a curve having a radius as short as three-sixteenth inch. In this crucial step of applying vapor heat to condition wood veneer, this invention marks a distinct advance in the art. The bending machine itself need not be essentially different from that disclosed in the Bechtold U.S. Pat. No. 3,296,056 already mentioned, except for the heating unit. Here a different type of heat must be employed to meet the special problems posed by wood veneer, and the use of controlled heat which is transmitted through vapor particles has proved an adequate solution.

FIGS. 8-11 indicate schematically some essential steps through which the work proceeds in the bending operation. After heating, opposite free portions of the oncoming veneer are engaged by certain stationary hollow cam shoes 63 angled to gradually deflect these portions of the veneer toward the sides of the core while a holddown roller 64 engages its top (FIG. 8). The chamber within each shoe is in communication through a pipe 65 with the vapor-generating unit 60. Jet openings (not shown) confronting the shoe-engaged faces of the veneer are also provided whereby to release vapor therethrough for discharge against the raw surfaces of the engaged veneer piece. The heat is thus carried to the very point at which the veneer is constrained to execute a bend through a curve of relatively short radius to assure against failure in this delicate operation.

Other rollers 69 thereafter engage the oncoming veneer portions so deflected by the cam shoes, to advance such portions into firm engagement with the opposite sides of the core, leaving free end portions extending thereabove (FIG. 9), then other cam shoes 70, similar to the shoes 63 and in communication with a source of vapor, engage the free end portions upstanding above the core while discharging vapor thereagainst, to deflect them downwardly toward the core top (FIG. 10), and finally there free end portions so deflected are pressed down by other top rollers 71 into firm engagement with the core top (FIG. 11). These several operating agencies may involve multiple rollers at successive points lengthwise of the machine, also other rollers having special profiles to assure conformation of the veneer with any nonpianar contours present in the core design. The positions of these various instrumentalities remain stationary, while the work is in constant motion to be acted upon successively by these agencies, thereby assuring successful bending of the wood veneer pieces after being previously conditioned and heated, as herein described.

It is to be noted that the surface of the veneer is not cut during its passage through the rollers U and L. The profile of the score lines s (FIG. 4) which are impressed upon one face of the veneer is such as to avoid duplication of those scores upon its opposite face. Rather, the relatively shallow depths between the tops of the scores are so designed as to compress the veneer body linearly with the end in view of disrupting its fibrous structure, but leaving it otherwise undamaged. The unyielding smooth face of the upper roller U which backs up the veneer when linear compression takes place affords full protection to its opposite face whose appearance remains unaffected. The preliminary conditioning, when followed by vapor heating, imparts a degree of flexibilization to the veneer which permits it to execute bends through curves of short radius. Each such bend may proceed about a single axis or several axes, and involves a single radius or more than one, depending upon the core contours to which the veneer must be conformed. By the means herein disclosed, these operations of conditioning the veneer and applying it to a core may be performed dependably and expeditiously, thus assuring volume production at a minimum cost.

Iclaim:

1. Means for conditioning wood veneer for bending comprising an elongated framework having interconnected front and rear walls and two upstanding end walls one of which is divided to provide a horizontal gap at a medial point vertically thereof, each front and rear wall being formed with a horizontal slot in communication with the horizontal gap and extending away therefrom through a major portion of the distance toward the opposite upstanding end wall, a pair of rollers extending lengthwise between the two ends of the framework, one above the other, the rollers when rotated being adapted to propel and compress between them a strip of wood veneer when advanced through the slot in the front wall and/or the gap in one end wall for subsequent discharge through the slot in the rear wall, a shaft extended axially beyond opposite ends of each roller, bearings wherein opposite ends of each shaft are mounted, means fixedly securing the bearings for the lower roller to opposite upstanding end walls of the framework at a point below the horizontal gap, means fixedly securing the bearings for the upper roller to opposite end walls of the framework at a point above the horizontal gap, but with capacity for limited vertical movements whereby the upper roller is free to be shifted toward or from the lower roller, and adjustable stop means in engagement with the upper roller bearings for fixing the maximum clearance between the upper and lower rollers.

2. Means as specified in claim 1 wherein interengaging horizontal faces are provided on the lower bearings and the upstanding supporting end walls therefor, adapted to furnish an abutment whereby to resist downward movement of the bearings in response to vertical thrust forces generated by passage of a veneer strip between the rollers, and wherein interengaging horizontal faces are provided on the upstanding end walls, the upper bearings supported thereby, and the stop means engaging therewith to furnish an abutment limiting upward movement of the upper bearings.

3. Means as specified in claim 1 wherein interengaging horizontal faces are provided between the upper and lower bearings and the upstanding supporting end walls therefor comprising, in each case, a recess means of substantial depth for each bearing inset in the end wall proximate thereto and extending horizontally thereof to provide therein spaced upper and lower horizontal faces, and elongated means disposed partly within each recess means and in engagement with its upper and lower faces to be fixedly anchored therein, and extended in part exteriorly thereof, one to overlie the upper bearing for engagement therewith and the other to underlie the lower bearing for engagement therewith, thereby to provide therefor abutments for resisting vertical thrust forces tending to vertically separate the two rollers.

4. Means as specified in claim 1 wherein the interengaging faces on the upper roller bearings and the upstanding supporting end walls therefor include an adjustable wedge adapted to fix an upper limit for upward movements of the upper bearings whereby to control the maximum clearance between the upper and lower rollers.

5. Means as specified in claim 1 wherein the surface of the lower roller is provided with a plurality of projections of uniform height and close spacing in a geometric pattern adapted to compress and/or disrupt the fibrous structure of the veneer piece as an incident preliminary to subsequent flexibilization thereof.

6. Means, as specified in claim 1, wherein the means fixedly securing the lower roller hearings to opposite upstanding end walls of the framework comprise recess means inset into each end wall to provide therein spaced upper and lower horizontal faces at an elevation below the bearings, abutment means fitted partly within such inset means in engagement with its upper and lower faces to be fixedly anchored therein and extended exteriorly thereof to underlie the proximate bearings for supporting engagement therewith in a horizontal plane, thereby to provide therefor an abutment to prevent downward movement of each lower bearing in response to thrust forces proceeding from above, and wherein the means for fixedly securing the upper roller hearings to opposite upstanding end walls of the framework comprise means inset into each upstanding end wall at an elevation above the upper roller bearings to provide therein spaced upper and lower horizontal faces between which the upper roller bearings are free to be vertically adjusted, and cam means fitted partly within each upper recess means in engagement with its upper and lower faces to be fixedly anchored therein and extended exteriorly thereof to overlie the proximate upper bearings for engagement therewith in a horizontal plane, thereby to provide therefor an adjustable abutment to limit upward movement of the upper roller bearings in response to thrust forces proceeding from below.

7. Means, as specified in claim 1, wherein one upstanding end wall of the framework consists of upper and lower sections with a horizontal gap therebetween in substantial alignment with the nip between the rollers to permit feeding therethrough of veneer strips having a width substantially greater than the space between the framework end walls, and wherein the means interconnecting the upstanding end walls provides an unyielding support for the two-section wall and is extended along front and rear sides of the two rollers to provide therefor an enclosure with horizontal slots therethrough at front and rear, the slots communicating with the gap at one end of the framework to join therewith in furnishing ample clearance for movement therethrough of veneer strips having a width greater than the space between the opposite upstanding end walls of the framework.

Claims (7)

1. Means for conditioning wood veneer for bending comprising an elongated framework having interconnected front and rear walls and two upstanding end walls one of which is divided to provide a horizontal gap at a medial point vertically thereof, each front and rear wall being formed with a horizontal slot in communication with the horizontal gap and extending away therefrom through a major portion of the distance toward the opposite upstanding end wall, a pair of rollers extending lengthwise between the two ends of the framework, one above the other, the rollers when rotated being adapted to propel and compress between them a strip of wood veneer when advanced through the slot in the front wall and/or the gap in one end wall for subsequent discharge through the slot in the rear wall, a shaft extended axially beyond opposite ends of each roller, bearings wherein opposite ends of each shaft are mounted, means fixedly securing the bearings for the lower roller to opposite upstanding end walls of the framework at a point below the horizontal gap, means fixedly securing the bearings for the upper roller to opposite end walls of the framework at a point above the horizontal gap, but with capacity for limited vertical movements whereby the upper roller is free to be shifted toward or from the lower roller, and adjustable stop means in engagement with the upper roller bearings for fixing the maximum clearance between the upper and lower rollers.

2. Means as specified in claim 1 wherein interengaging horizontal faces are provided on the lower bearings and the upstanding supporting end walls therefor, adapted to furnish an abutment whereby to resist downward movement of the bearings in response to vertical thrust forces generated by passage of a veneer strip between the rollers, and wherein interengaging horizontal faces are provided on the upstanding end walls, the upper bearings supported thereby, and the stop means engaging therewith to furnish an abutment limiting upward movement of the upper bearings.

3. Means as specified in claim 1 wherein interengaging horizontal faces are provided between the upper and lower bearings and the upstanding supporting end walls therefor comprising, in each case, a recess means of substantial depth for each bearing inset in the end wall proximate thereto and extending horizontally thereof to provide therein spaced upper and lower horizontal faces, and elongated means disposed partly within each recess means and in engagement with its upper and lower faces to be fixedly anchored therein, and extended in part exteriorly thereof, one to overlie the upper bearing for engagement therewith and the other to underlie the lower bearing for engagement therewith, thereby to provide therefor abutments for resisting vertical thrust forces tending to vertically separate the two rollers.

4. Means as specified in claim 1 wherein the interengaging faces on the upper roller bearings and the upstanding supporting end walls therefor include an adjustable wedge adapted to fix an upper limit for upward movements of the upper bearings whereby to control the maximum clearance between the upper and lower rollers.

5. Means as specified in claim 1 wherein the surface of the lower roller is provided with a plurality of projections of uniform height and close spacing in a geometric pattern adapted to compress and/or disrupt the fibrous structure of the veneer piece as an incident preliminary to subsequent flexibilization thereof.

6. Means, as specified in claim 1, wherein the means fixedly securing the lower roller bearings to opposite upstanding end walls of the framework comprise recess means inset into each end wall to provide therein spaced upper and lower horizontal faces at an elevation below the bearings, abutment means fitted partly within such inset means in engagement with its upper and lower faces to be fixedly anchored therein and extended exteriorly thereof to underlie the proximate bearings for supporting engagement therewith in a horizontal plane, thereby to provide therefor an abutment to prevent downward movement of each lower bearing in response to thrust forces proceeding from above, and wherein the means for fixedly securing the upper roller bearings to opposite upstanding end walls of the framework comprise means inset into each upstanding end wall at an elevation above the upper roller bearings to provide therein spaced upper and lower horizontal faces between which the upper roller bearings are free to be vertically adjusted, and cam means fitted partly within each upper recess means in engagement with its upper and lower faces to be fixedly anchored therein and extended exteriorly thereof to overlie the proximate upper bearings for engagement therewith in a horizontal plane, thereby to provide therefor an adjustable abutment to limit upward movement of the upper roller bearings in response to thrust forces proceeding from below.

7. Means, as specified in claim 1, wherein one upstanding end wall of the framework consists of upper and lower sections with a horizontal gap therebetween in substantial alignment with the nip between the rollers to permit feeding therethrough of veneer strips having a width substantially greater than the space between the framework end walls, and wherein the means interconnecting the upstanding end walls provides an unyielding support for the two-section wall and is extended along front and rear sides of the two rollers to provide therefor an enclosure with horizontal slots therethrough at front and rear, the slots communicating with the gap at one end of the framework to join therewith in furnishing ample clearance for movement therethrough of veneer strips having a width greater than the space between the opposite upstanding end walls of the framework.

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