US1714785A - Machine for the manufacture of paper articles - Google Patents

Machine for the manufacture of paper articles Download PDF

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Publication number
US1714785A
US1714785A US685987A US68598724A US1714785A US 1714785 A US1714785 A US 1714785A US 685987 A US685987 A US 685987A US 68598724 A US68598724 A US 68598724A US 1714785 A US1714785 A US 1714785A
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gear
machine
shaft
web
rolls
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US685987A
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Hudson Alden
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Priority to US355158A priority patent/US1852576A/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B31MAKING ARTICLES OF PAPER, CARDBOARD OR MATERIAL WORKED IN A MANNER ANALOGOUS TO PAPER; WORKING PAPER, CARDBOARD OR MATERIAL WORKED IN A MANNER ANALOGOUS TO PAPER
    • B31DMAKING ARTICLES OF PAPER, CARDBOARD OR MATERIAL WORKED IN A MANNER ANALOGOUS TO PAPER, NOT PROVIDED FOR IN SUBCLASSES B31B OR B31C
    • B31D1/00Multiple-step processes for making flat articles ; Making flat articles
    • B31D1/04Multiple-step processes for making flat articles ; Making flat articles the articles being napkins, handkerchiefs, towels, doilies, or the like
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T83/00Cutting
    • Y10T83/202With product handling means
    • Y10T83/2092Means to move, guide, or permit free fall or flight of product
    • Y10T83/2207Means to move product in a nonrectilinear path
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T83/00Cutting
    • Y10T83/202With product handling means
    • Y10T83/2092Means to move, guide, or permit free fall or flight of product
    • Y10T83/2209Guide
    • Y10T83/2216Inclined conduit, chute or plane
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T83/00Cutting
    • Y10T83/485Cutter with timed stroke relative to moving work
    • Y10T83/492With means to vary timing of tool feed
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T83/00Cutting
    • Y10T83/485Cutter with timed stroke relative to moving work
    • Y10T83/494Uniform periodic tool actuation
    • Y10T83/50Reciprocating tool
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T83/00Cutting
    • Y10T83/727With means to guide moving work
    • Y10T83/73Guide fixed to or integral with stationary tool element
    • Y10T83/731Tool element cooperates with a second tool
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T83/00Cutting
    • Y10T83/869Means to drive or to guide tool
    • Y10T83/8769Cutting tool operative in opposite directions of travel

Definitions

  • This invention relates to improvements in machines for the manufacture of paper articles; More particularly, this invention relates to a machine which'is peculiarly adapted for making napkins, toilet paper and the like, but which may be used for the purpose of making other articles embodying sheets of paper or otherfiexible substances.
  • the present invention contemplates the provision of a machine which can be adjusted to produce, within certain limits, any desired size or' shape of folded paper article, and therefore it is adapted to overcome the objections noted above.
  • a further very important object of this invention consists in the arrangement by which adjustments are made for the manufacture of different sizes of folded paper articles. It will be understood that a machine of this type involves a considerable number of parts to act on the paper, and it is necessary that such parts be actuated in synchronism. Therefore, a change of adjustment as to the operation of one of such parts will usually require a corresponding change in-adjust-ment to con- ⁇ trol others of said parts, and it is one of the objects of this invention to. provide means for controlling simultaneously adjustments of a plurality of synchronously operated parts so that the independent adjustment of each of. such parts will be unnecessary.
  • vIt is also an importantobject of this invention to provide means-for producing in an article, such as a napkin or the like, a fold at a point which is not fixed intermediate the I ends of a napkin but may be adjusted within limits to the end that the napkin fold maybe disposed exactly between the ends of the napkin or may be disposed at points otfset from the center line thereof.
  • Figure 1 is a diagrammatic side elevation of a device embodying the invention to which this application is directed.
  • Figure 2 is an end elevation of the device shown in Figure 1.
  • Figure 3 is a plan View of the majority of the working parts of the device, the superstructure being cut away substantially to the sectionindicated at 33 in Figure 2.
  • Figure ⁇ I is terconnecting gear as it appears from the rear of the machine.
  • Figure 5 is a detail view in front elevation of a crank-disk.
  • Figure 6 is a view similar to Figure 5, of a disk with which Figure-5 co-operates.
  • Figure 7 is a vertical axial sectionthrough the assembled disks shown in Figure 8 is a view similar to Figure 1, showing one sheet passin through the foldof web being fed parts as well as their. respecinto the machine.
  • Figure 9 is a view similar to Figure 8, showing a deflector acting on the infed portion of the web, and showing the tucking blade fully retracte
  • Figure 10 shows the tucking blade commencing to act upon the web.
  • FIG 11 is a detail view taken on the section indicated at 11-11 in FigurelO.
  • Figure 12 is a sectional view on an enlarged scale of the paper severing mechanism taken on the line 12-12 of Figure 3.
  • the frame work of the machine is indi cated in its entii ety by the-reference character 1.
  • Paper webs 2 are fed into the machine from supply rolls 3 and pass about the guide rolls 4 from which ,they extend downwardly through the folding devices 5.
  • Such devices are well known in the art and are adapted to put any desired number of longitudinal accordion folds in a moving web of paper or other flexible material. These devices are retained in place through the medium of gravity actuated links 6, whereby they may readily be removed for the substitution of other similar devices adapted to produce a different number of folds.
  • each of the rolls 8 is mounted on a shaft 10 which comprises the primary drive shaft of the machine and, for power receiving purposes, carries a pulley 11.
  • each of the rollers 9 is mounted on a shaft 12 which is parallel to shaft 10 and is connected thereto through the medium of gears 13 and 14, respectively (see Figure 3)
  • Extending between the uprights of frame 1 are the bridge members 15 which may be integrally connected by means of bearing members 16 providing a pair of parallel dovetailed channels within which the slides 17 are operable.
  • each slide may rest on one side upon a take-up member 18 which is adjustable centrally of its slide by means of a set screw 19.
  • the take-up member 18 will conform in angularity to-the dovetailed portion of the slide, and consequently, will act like a wedge to keep the slide pressed against the retaining or cover plate 20.
  • cover plate 20 is shown inbroken lines in Figure 1.
  • the cover plate is provided with an aperture or transverse slot 21 which will preferably have square cut margins between which the longitudinally folded web 7 will be fed.
  • I preferably provide theupstanding fingers 22 and 23 which are spaced apart at substantially the width of the slot and are received into suitable peripheral grooves 24 in the feed rolls. This arrange- 'ment makes it impossible for the web to follow the rolls through adherence.
  • the slide 17 carries a transverse shearing bar 25 which, for clearness, is shown in section in Figure 1, although Figure 1 is primarily a side elevation. Due to the angular position of the take-up gibs 18, the slide will be maintained'with shear bar 25 in a position to co-operate with the square cut margins of slot 21.
  • the slide 17 and shear bar 25 are reciprocable through vmeans hereinafter to be described and, in each direction of reciprocation of the shear bar 25, it will cooperate with one margin of slot 21 to sever the web portion projecting therethrough. 1n the position of the parts illustrated in Figure 1, this severing operation is just occurring and, for purposes of illustration, the shear bar 25 may be considered to be moving in the direction indicated by the arrow immediately beneath it.
  • the newly infed web portion will be considered from the timeof its arrival through slot 21 until it is discharged from the machine.
  • shear bar 25 will move to the position'in which it is indicated in Figure 8, and simultaneously the rotation of rolls 8 and 9 will advance web 7 until its end contacts with the deflector 27.
  • This deflector may be stationary but will preferably be mounted for oscillation upon a cross shaft 28 and will, through actuating mechanism hereinafter to be described, be oscillating at this point of the cycle in a clockwise direction. It is the function of the deflector 27 to prevent the advancing end of the web from adhering-to the extremity of the preceding napkin, or may otherwise be caught between the folding rollers 29 and 30.
  • the tucking blade 31 which, in the positions of the parts shown in Figures 1 and 8 is in the path of the advancing web. is being retracted at this time in the direction indicated by the arrow in Figure 8 and eventually reaches the position in which it appears in Figure 9. At this point the shear knife 25 is practically at the end of its stroke, and the tucking blade 31 is also almost fully retracted.
  • the end of the longitudinally folded web porportion 7 has now been fed by 9 onto a transverse series of belts 32. These belts pass over spaced pulleys 33 and 34 upon shafts 35 and 36, respectively.
  • a sufficient number of belts is employed to provide adequate support for the end of the advancing web.
  • These belts advance in the direction indicated by thearrows, either at the speed of web advance or at a slightly greater speed, so that they assist in maintaining the web in position and under that slight degree of tension which is desirable for the most perfect operation of the machine.
  • the size and location of pulleys 39 is such that these pulleys will be disposed in staggered relation with pulleys 34. and a belt 37 will lie between each pair of belts 32. This arrangement is such as to ensure frictional. contact of both belts with the web so that by the time the web reaches the position in which it appears in Figure 10 the extremity of the web will be corrugated to lie 37 and pulleys 34 and 39.
  • the tucking blade When the web reaches the point in its advance in which it is shown in- Figure 10, the tucking blade will be-well advanced on its operating stroke and will be engaged with the paper, as indicated in Figure 10, while moving in the direction of the arrow in said figure.
  • the engagement of the belts 32 and 37 with the paper will hold it under tension at the time of contact of the tucking blade there-' With, and will thereby ensure a perfect fold on a line normal to the margins of the web. If the sheet is not so held the fold will not always be straight.
  • the upper belt 37 also serves to prevent the sheet or web from snapping backward.
  • the shearing knife 25 will also be on its return stroke and will be approaching rapidity to the point where it will again sever that portion of the web with which the tucking blade 31 is engaged. The fact that the web is unsevered at this time ensures that it will be under tension, due to the pull of the belts thereon.
  • the tucki-ng blade 31 will force an intermediate portion of the web between the folding rolls 29 and 30 which will act upon-the web in the usual manner. first to crease the fold made by the tucking blade and then to draw the severed portion of the web between themselves in the form of a completed paper article.
  • the shearing knife 25 will be so synchronized with the movements of the tucking blade that the shear knife will sever the web substantially exactly at the time when the portion to be severed is forced by the tucking blade into the operative grip of folding rolls or vise rolls 29 and 30.
  • the severed napkin is a: trough 141 down which it slides until it reaches a point of registry with chute 42. At this point it is brought to rest by means of a suitable stop 43. At this point thepacker 45, which is mounted on rock shaft 46 and is in course of'retraction in Figures 1 and 8, moves downwardly as indicated by the arrows in Figures 9 and 10 until it contacts With the newly formed folded article and compresses it above chute 42. Thus, upon each of the active such rolls.
  • roller 55 directed by roller 55 into previously formed articles in the strokes of the packer the articles in the chute will be advanced-for a distance equivalent to the thickness of the newly added article.
  • gears 14 and, 13 on shafts 10 and 12, respectively, connect such shafts for simultaneous rotation. From gear 13 power is transmitted not only to shaft 12 but also to a transmission gear 47 which may be mounted on a stud shaft 47 carried by the frame 1. Gear 47 meshes at the back of the machine with a gear 48' on the shaft 49 which carries one of the folding or vise rolls 29. This gear 48 meshes in turn With a gear 50 on shaft 51 Whichcarries the other folding or vise roll 30.
  • the shaft 51 which carries the vise roll 30 i is driven by gear 50 atits rear end and at its forward end it carries a gear 52, which 1s shown In dotted lmes in Figure 4, by reason Due to the reduction gearing emof the fact that it is at the front of the machine.
  • Gear 52 meshes with a gear 53 which is likewise at the front of the machine and is carried by a shaf 54. upon Which the rotary deflecting roller 55 is mounted.
  • the shafts 35 and 40 carrying respectively pulleys 33 and 38, are interconnected by means of inter-meshing gears 57 and 58 on shafts 41 and 36, and by the belts 32 and 37 already described. These shafts are both driven through a gear 59 disposed centrally on shaft 35 which meshes with ring gear 50 on the vise roll 30.
  • the belts.32 and 37 and the rotary deflector 55, as well-as the vise rolls 29 and 30, are all driven at constant speed with reference to thefee-d rolls 8 and 9, inasmuch as it is unnecessary to change the relative speed of movement.
  • the two driving rolls 9 on shaft 12 are axially spaced apart to receive between them a gear 60 which, if the rolls 9 are integrally connected, may comprise a ri'nggear-
  • the rolls 8 which are illustrated in Figure 3 as, being integrally constructed are grooved at 60 to provide clearance for gear 60.
  • the groove 60' lies between and defines the independent rolls 8 which act upon different webs of paper.
  • Meshing with gear 60 is an intermediate gear 61 adj ustably supported on a stud 62 in the end of an arm 63 on a rock shaft 6 1.
  • the rock shaft may be constructed in any desired manner to be supported in any adjustment with reference to the frame. For example, it may, as indicated in dotted lines in Figure 1, be provided with an arm.
  • a cross shaft 70 upon which are slidably mounted a series of gears 71, 72, and 73 which may either be splined to the shaft or may be provided with set screws 74: for securing them in any desired position of adjustment thereon.
  • the arrangement is such that any of the gears just described can be positioned selectively upon the shaft in the plane of intermediate gear 61 to receive motion therefrom.
  • the adjustment of rock shaft 64 and arm 63 which carry gear 61 are intended and adapted to permit gear 61 to be moved into mesh simultaneously with its driving gear 60 and its driven gears 71, 72, or 73. While only three gears have been illustrated on shaft 7 0, it will be obvious that the number of gears on said shaft could be multiplied indefinitely to produce any desired relative speed between said shaft and the driving gear 60 on shaft 12.
  • each crank pin is rotatably adjustable with reference to the shaft 7 0 with which it is connected for operation.
  • the adjustment of the crank pins provides for the independent timing of the members driven through shaft 70, whereas the several gears 71, etc., on shaft 7 0 permit of the simultaneous adjustment for timing purposes of all elements driven through said shaft.
  • crank pin 82 connected with shaft 70 at the rear of the machine receives a connecting rod 83, whereby it is joined to a rocker arm 84. on the rock shaft'85 which carries the tucker 31.
  • the rotative movement of shaft 70 is thus transmitted to rock Q1121 H 85 to produce oscillation of said shaft and the corresponding movement of they tucker as previously described.
  • shaft 85 carries a cam 105 which actuates a roller cam follower 106 on the reciprocable link 107.
  • This link is connected at 108 with an arm 109 on rock shaft 28 which carries the deflector 27.
  • a spring 110 presses link 107 downwardly to maintain cam follower 106 in operative contact with cam 105.
  • the link 107 may be guided inany suitable means, such as the spaced rollers 11.1 and 112 connected with the frame of the machine.
  • a retaining member 113 mounted on the axle studs of roller 111 and 112 maintains the link in operative position between the rollers.
  • crank pin 82" at the front of the machine actuates a connecting rod 86 which is engaged with arm 87 on the rock shaft 46 which supports the packer 45. Therefore, the rotative movement .of shaft 70 produces the above described oscillations of the packer and such oscillations are not only adjustable simultaneously with the adjustment of the tucking blade but are also adjustable independently thereof through the medium of the adjustable crank pin support through which each of the connecting rods 83 and 86 is independently operated.
  • gear 1 1 on driving shaft 10 through which all of the above described gearing and motion transmitting connections are operated.
  • This gear also actuates a further line of power transmitting mechanism, including a gear 90 adjustably mounted on a stud shaft 91 which is carried in an arcuate slot 92 in the frame, the slot being concentric with the axis of shaft 10.
  • a gear 90 adjustably mounted on a stud shaft 91 which is carried in an arcuate slot 92 in the frame, the slot being concentric with the axis of shaft 10.
  • a cross shaft 94 in the frame is adapted to carry interchangeably at its rear end any one of a series of any desired number of gears, of which the gear 95 is one.
  • This gear is held in place by means of a nut 96 on the end of shaft 9 or by any other equivalent means adapted to permit of the ready removal of the gear 95 for the substitution of another gear of diifercnt size.
  • This arrangement constitutes a well known type of change speed mechanism embodying change speed gearing of the so called take-01f variety. Other change speed mechanism might be employed, but inasmuch as there are ordinarily few changes or adjustments in a machine of this character no complicated change speed gearing would be warranted, and that illustrated has the advantage of being extremely simple and easy to operate.
  • Disk 80 Opposite to the end of shaft 94 which carries gear 95 is a disk 75 and a complementarydisk 80f corresponding to disks 7 5 and 80 previously described.
  • Disk 80 carries a crank pin 82 which is connected by pitman 97 with the rocker arm 98 on rock shaft 99.
  • This rock shaft also carries arms 100, which are illustrated in Figure 1, in any intermediate position from which they oscillate ,in both directions during the operation of the device. These arms 100 will correspond in number to the number of cutters to be actuated. For whileI have illustrated and described only two cutters side by side, it will be obvious that a machine of this character can be extended from front to rear to operate simultaneously upon as many webs as may be desired. The showing of means for operatingon two webs will be understood to exemplify the fact that a plurality of Webs may be treated with a machine of this type as readily as a single web may be acted upon. 7
  • the arms 100 on rock shaft 99 are provided at their upper extremities with clevises 101, whereby the adjustable links 102 are pivotally connected thereto.
  • Each of the links includes a barrel 102 interiorly threaded to receive .right and left hand threaded members 103 and 104 (see F ig. 3)
  • This arrangement permits of the. ready adjustment of the length of the links.
  • the end of each link remote from its pivotal connection with the clevises of arms 100 is connected pivotally with one of the slides 17 which carry the shear bars 25.
  • the arrangement is such that the rotation of shaft 94 causes the oscillation of shaft 99 and the correspondingreciprocation of the slides carrying the shear bar.
  • disks 75 and 80' the relative timing between the shear bars and the remainder of themachine may be varied without altering the synchronization of the parts.
  • gear 95 has a ratio of two to one as compared with the gear- 14 from which it is driven. In other words, gear 95 will make one rotation for each two rotations of rolls 8 and 9. As a result of this proportion, and as a further result of the fact that the shear bar 25 severs a blank from the web twice during each complete cycle, it
  • each blank will have a length equal to the circun'iference of rolls 8 or 9. .By substituting for gear 95 a gear of adifierent ratio with respect to gear 14, it is possible to cut from the longitudinally folded web portion 7 a blank having a length lesser or greater than the'circumference of roll 8. The length of' the blank will always be one-half of the circumference of gear 95, due to the fact that the shear bar 25 makes two cutting strokes for each rotation of said gear. Consequently, the operator can conveniently determine the size of gear 95 by selecting a gear which has a circumference equal to twice the length-of the desired blank.
  • disks 7 6 and 80 provides for a change in the relative position of the tucker so that a greater or lesser length of the blank may be allowed to pass the blade before being acted upon thereby.
  • the blank may either be folded in its exact center or to one side of the center as may be desired, and consequently, it is possible to secure a wide variety of folds on a machine of this character.
  • a change in the relative position of the tucker blade such as may be accomplished by adjustment of plate or disk 80, has no effect upon the synchronization of the partsand permits them to continue to operate with the same timing as that previously employed. In other words, the number of operations performed in a complete rotation of the driving gear will be constant, although the point of the cycle at which each operation is performed may be adjusted.
  • the combination with web feeding mechanism of a pair of relatively stationary shear bars associated with said mechanism and positioned to receive between them a web acted upon by said mechanism, a reciprocable shearbar associated with said stationary shear bars and adapted to interact with each of said stationary shear bars in the :eourse of each complete reciprocation, and driving connections for said feeding mechanism and said reciproeable s'he'aibar, said connections including change speed mechanism'operable to control the relative rates of operation of said feeding mechanism and shear bar.
  • a rotary driving member operatively connected therewith, a driven member rotatable concentrically with the driving member and rotatably adjustable with reference thereto, and a web cutter connected to be operated from said driven member and disposed to act upon material fed by said feeding device.
  • a web cutting device comprising a bed member providing a longitudinally extending downwardly tapering bearing surface, a shear bar reciprocable on said surface, and a pair of '5 relatively stationary, closely spaced shearing surfaces positioned for co-opcration with said bar.
  • a web shearing mechanism comprising a bed member having longitudinally extending, downwardly tapering bearing surfaces, a head reciprocable .on said surfaces and provided with a transversely extending shear bar. means for adjusting one of said bearing surfaces toward the other bearing surface, whereby to take up wear, and a plate confining said head upon said surfaces and provided with a transverse slot having margins co-operative with said bar.

Landscapes

  • Folding Of Thin Sheet-Like Materials, Special Discharging Devices, And Others (AREA)

Description

'May ZS, 1929. A. HUDSON MACHINE FOR THE MANUFACTURE OF PAPER ARTICLES Filed Jan. 14. 1924 6 She ts-Sheet 1 ATTDRNEYQ May 28, 1929. A. HUDSON 1,714,785
MACHINE FOR THE MANUFACTURE OF PAPER ARTICLES Filed Jan. 14. 1924 s Sheets-Sheet 2 INVEN TOR.
'w ,4 Y J/LA, I wiam 7 I @WJM,%MW%4 ATTORNEYS.
May 28, 1929. AHHUDSON 1,714,785
MACHINE FOR THE MANUFACTUREOF PAPER ARTICLES Filed Jan. 14, 1924 6 Sheets-Shet' 3 II VVENTOR.
A TTORNE S'.
May 28, 1929. A. HUDSON 1,714,785
- MACHINE FOR THE MANUFACTURE OF PAPER ARTICLES Filed Jan. 14. 1924 6'Sheets-Sheet 4 INVENTOR.
A TTORNEYS A. HUDSON May 28, 1929."
MACHINE FOR THE MANUFACTURE OF PAPER ARTICLES Filed Jan. 14. 1924 6 Sheets-Sheet -5 ATTORNEYS,
May 28, 1929. A. HUDSON 1. 14. 8
MACHINE FOR THE MANUFACTURE OF PAPER ARTICLES Filed Jan. 14, 1924 6 Sheets-Sheet 6 I Ff /Z. 2/ H 7 XM XK 32 '2 C345 ATTORNEYS Patented May 28, 1929.
UNITED STATES ALIDEN HUDSON, OF
GREEN BAY, WISCON SIN, ASSIGNOR TO DAVID WILLIAM HUDSON, OF GREEN BAY, WISCONSIN.
MACHINE FOR THE MANUFACTURE OF PAPER ARTICLES.
Application filed January 14,1924. Serial No. 685,987.
This invention relates to improvements in machines for the manufacture of paper articles; More particularly, this invention relates to a machine which'is peculiarly adapted for making napkins, toilet paper and the like, but which may be used for the purpose of making other articles embodying sheets of paper or otherfiexible substances.
. It is the primary object of this invention to provide a novel and simple machine which will be'susceptible of adjustment to cut and fold sheets of varying sizes. It has heretofore been the practice to provide a separate machine for each size of folded article to be produced. This practice has necessitated large investments in machinery of this character as well as large areas of floor space to accommodate such machines. The disadvantages of the fixed type of machine are obvious and, in the case of a small industry, are serious. The present invention contemplates the provision of a machine which can be adjusted to produce, within certain limits, any desired size or' shape of folded paper article, and therefore it is adapted to overcome the objections noted above.
A further very important object of this invention consists in the arrangement by which adjustments are made for the manufacture of different sizes of folded paper articles. It will be understood that a machine of this type involves a considerable number of parts to act on the paper, and it is necessary that such parts be actuated in synchronism. Therefore, a change of adjustment as to the operation of one of such parts will usually require a corresponding change in-adjust-ment to con-\ trol others of said parts, and it is one of the objects of this invention to. provide means for controlling simultaneously adjustments of a plurality of synchronously operated parts so that the independent adjustment of each of. such parts will be unnecessary.
vIt is also an importantobject of this invention to provide means-for producing in an article, such as a napkin or the like, a fold at a point which is not fixed intermediate the I ends of a napkin but may be adjusted within limits to the end that the napkin fold maybe disposed exactly between the ends of the napkin or may be disposed at points otfset from the center line thereof.
Other objects of this invention are to pro- ,which is particularly adapted ing rolls'and a new lengt vide a simple, compact construction for the purposes aforesaid; to provide a machine easily susceptible of adjustment and easily operated; to provide a machine having a novel type of paper shearing mechanism for association with the folding mechanism of .an adjustable machine; to provide a type of machine which consists of a plurality of units adapted to act simultaneously upon a corresponding number of webs of paper and all controlled by the same'driving and adjusting mechanism to produce simultaneously napkins of a given size and having a given location of fold.
The drawings are largely diagrammatic but are intended to show ingeneral the relative sizes of the tive location.
.In the drawings:
Figure 1 is a diagrammatic side elevation of a device embodying the invention to which this application is directed.
Figure 2 is an end elevation of the device shown in Figure 1.
Figure 3 is a plan View of the majority of the working parts of the device, the superstructure being cut away substantially to the sectionindicated at 33 in Figure 2.
Figure {I is terconnecting gear as it appears from the rear of the machine.
Figure 5 is a detail view in front elevation of a crank-disk.
Figure 6 is a view similar to Figure 5, of a disk with which Figure-5 co-operates.
Figure 7 is a vertical axial sectionthrough the assembled disks shown in Figure 8 is a view similar to Figure 1, showing one sheet passin through the foldof web being fed parts as well as their. respecinto the machine.
Figure 9 is a view similar to Figure 8, showing a deflector acting on the infed portion of the web, and showing the tucking blade fully retracte Figure 10 shows the tucking blade commencing to act upon the web.
Figure 11 is a detail view taken on the section indicated at 11-11 in FigurelO.
Figure 12 is a sectional view on an enlarged scale of the paper severing mechanism taken on the line 12-12 of Figure 3.
disk the disk shown in.
Figures 5 and 6.
a view of the driving and in- Like parts are identified b the same reference characters throughout t 1e several views.
The frame work of the machine is indi cated in its entii ety by the-reference character 1. Paper webs 2 are fed into the machine from supply rolls 3 and pass about the guide rolls 4 from which ,they extend downwardly through the folding devices 5. Such devices are well known in the art and are adapted to put any desired number of longitudinal accordion folds in a moving web of paper or other flexible material. These devices are retained in place through the medium of gravity actuated links 6, whereby they may readily be removed for the substitution of other similar devices adapted to produce a different number of folds.
The longitudinally folded webs, one of which appears at 7 in Figure 1, are led downwardly between feed rollers 8 and 9. As is clearly shown in Figure 2, there are two of such rollers in axial alignment for the two parts of the machine. Each of the rolls 8 is mounted on a shaft 10 which comprises the primary drive shaft of the machine and, for power receiving purposes, carries a pulley 11. Similarly, each of the rollers 9 is mounted on a shaft 12 which is parallel to shaft 10 and is connected thereto through the medium of gears 13 and 14, respectively (see Figure 3) Extending between the uprights of frame 1 are the bridge members 15 which may be integrally connected by means of bearing members 16 providing a pair of parallel dovetailed channels within which the slides 17 are operable. These 'slides are preferably accurately fitted to their respective bearing members inasmuch as each slide carries a shearing knife. In order to maintain the slides operative despite any wear which may occur in the use of the machine, each slide may rest on one side upon a take-up member 18 which is adjustable centrally of its slide by means of a set screw 19. The take-up member 18 will conform in angularity to-the dovetailed portion of the slide, and consequently, will act like a wedge to keep the slide pressed against the retaining or cover plate 20.
To facilitate an understanding of the operation of the device, a portion of the cover plate 20 is shown inbroken lines in Figure 1. Immediately beneath each pair of feed rolls 8 and 9 the cover plate is provided with an aperture or transverse slot 21 which will preferably have square cut margins between which the longitudinally folded web 7 will be fed. To ensure that the web will be guided through slot 21, I preferably provide theupstanding fingers 22 and 23 which are spaced apart at substantially the width of the slot and are received into suitable peripheral grooves 24 in the feed rolls. This arrange- 'ment makes it impossible for the web to follow the rolls through adherence.
The slide 17 carries a transverse shearing bar 25 which, for clearness, is shown in section inFigure 1, although Figure 1 is primarily a side elevation. Due to the angular position of the take-up gibs 18, the slide will be maintained'with shear bar 25 in a position to co-operate with the square cut margins of slot 21. The slide 17 and shear bar 25 are reciprocable through vmeans hereinafter to be described and, in each direction of reciprocation of the shear bar 25, it will cooperate with one margin of slot 21 to sever the web portion projecting therethrough. 1n the position of the parts illustrated in Figure 1, this severing operation is just occurring and, for purposes of illustration, the shear bar 25 may be considered to be moving in the direction indicated by the arrow immediately beneath it.
Disregarding for the moment the portion of the web which has just been severed by the shear bar, the newly infed web portion will be considered from the timeof its arrival through slot 21 until it is discharged from the machine. Thus a complete cycle of operation will be described. After severing the web, shear bar 25 will move to the position'in which it is indicated in Figure 8, and simultaneously the rotation of rolls 8 and 9 will advance web 7 until its end contacts with the deflector 27. This deflector may be stationary but will preferably be mounted for oscillation upon a cross shaft 28 and will, through actuating mechanism hereinafter to be described, be oscillating at this point of the cycle in a clockwise direction. It is the function of the deflector 27 to prevent the advancing end of the web from adhering-to the extremity of the preceding napkin, or may otherwise be caught between the folding rollers 29 and 30.
The tucking blade 31 which, in the positions of the parts shown in Figures 1 and 8 is in the path of the advancing web. is being retracted at this time in the direction indicated by the arrow in Figure 8 and eventually reaches the position in which it appears in Figure 9. At this point the shear knife 25 is practically at the end of its stroke, and the tucking blade 31 is also almost fully retracted. The end of the longitudinally folded web porportion 7 has now been fed by 9 onto a transverse series of belts 32. These belts pass over spaced pulleys 33 and 34 upon shafts 35 and 36, respectively. A sufficient number of beltsis employed to provide adequate support for the end of the advancing web. These belts advance in the direction indicated by thearrows, either at the speed of web advance or at a slightly greater speed, so that they assist in maintaining the web in position and under that slight degree of tension which is desirable for the most perfect operation of the machine.
Co-operating with belts 32 are belts 37 feed rolls 8 and between belts 32 and which are disposed above the path of the advancingweb and are carried by upper and lower pulleys 38 and 39 mounted respectively on shafts 40 and 41. The size and location of pulleys 39 is such that these pulleys will be disposed in staggered relation with pulleys 34. and a belt 37 will lie between each pair of belts 32. This arrangement is such as to ensure frictional. contact of both belts with the web so that by the time the web reaches the position in which it appears in Figure 10 the extremity of the web will be corrugated to lie 37 and pulleys 34 and 39.
When the web reaches the point in its advance in which it is shown in-Figure 10, the tucking blade will be-well advanced on its operating stroke and will be engaged with the paper, as indicated in Figure 10, while moving in the direction of the arrow in said figure. The engagement of the belts 32 and 37 with the paper will hold it under tension at the time of contact of the tucking blade there-' With, and will thereby ensure a perfect fold on a line normal to the margins of the web. If the sheet is not so held the fold will not always be straight. The upper belt 37 also serves to prevent the sheet or web from snapping backward. The shearing knife 25 will also be on its return stroke and will be approaching rapidity to the point where it will again sever that portion of the web with which the tucking blade 31 is engaged. The fact that the web is unsevered at this time ensures that it will be under tension, due to the pull of the belts thereon.
As the parts continue to move they will complete the cycle by reaching the positions in which they appear in Figure 1. The tucki-ng blade 31 will force an intermediate portion of the web between the folding rolls 29 and 30 which will act upon-the web in the usual manner. first to crease the fold made by the tucking blade and then to draw the severed portion of the web between themselves in the form of a completed paper article. The shearing knife 25 will be so synchronized with the movements of the tucking blade that the shear knife will sever the web substantially exactly at the time when the portion to be severed is forced by the tucking blade into the operative grip of folding rolls or vise rolls 29 and 30.
As the cycle just described recommences, the severed napkin is a: trough 141 down which it slides until it reaches a point of registry with chute 42. At this point it is brought to rest by means of a suitable stop 43. At this point thepacker 45, which is mounted on rock shaft 46 and is in course of'retraction in Figures 1 and 8, moves downwardly as indicated by the arrows in Figures 9 and 10 until it contacts With the newly formed folded article and compresses it above chute 42. Thus, upon each of the active such rolls.
directed by roller 55 into previously formed articles in the strokes of the packer the articles in the chute will be advanced-for a distance equivalent to the thickness of the newly added article.
The operation of the machine in general has been described before its specific mechanical connections were set forth in order that the adjustable features of the machine might be the more fully appreciated. It will be understood from the foregoing that it is necessary that the shear knife 25, tucking blade 31, the oscillatory deflector 27, and the packer 45 must all operate upon the work with synchronized action, and their operation must also be synchronizedwith the rate of advanceof the web by the feedrolls 8 and 9. Furthermore, it will also be appreciated that for spec al work it is desirable to provide for the independent adj ustment of several of these mechanical elements to change theirtime of ac tion with respect to the action of others of the elements. It is also desirable, however, to
provide for the simultaneous adjustment of the relative time of action of a plurality of elements when simultaneous adjustment is possible consistent with the desired operation of the machine. One set of mechanical connections for accomplishing the results ex-' I pressed immediately above will now be described, but inasmuch as it is obviously. a simple matter to design equivalent means for obtaining this result I do not desire to limit myself to the specific construction herein disclosed, except as specifically pointed out here inafter in the claims.
As has already been stated, power is ap plied to-the machine through pulley 11 Which is mounted on shaft 10. Gears 14 and, 13 on shafts 10 and 12, respectively, connect such shafts for simultaneous rotation. From gear 13 power is transmitted not only to shaft 12 but also to a transmission gear 47 which may be mounted on a stud shaft 47 carried by the frame 1. Gear 47 meshes at the back of the machine with a gear 48' on the shaft 49 which carries one of the folding or vise rolls 29. This gear 48 meshes in turn With a gear 50 on shaft 51 Whichcarries the other folding or vise roll 30. Thus, the rotation of both of the vise rolls is provided'for, and it will be noticed that no adjustment is necessary to control the relative rates of rotation on ployed betweenfdrive shaft 10 and the shafts 49 and51, these shafts and the vise rolls 29 and 30 carried thereby will always rotate at relatively high speeds, and will thereby be adapted to handle any length of napkin which can be fed to them by thefced rolls 8 and 9. With respect to the feeding rolls 8 and 9, the speed of the clamping rolls 29 and 30 is constant.
The shaft 51 which carries the vise roll 30 i is driven by gear 50 atits rear end and at its forward end it carries a gear 52, which 1s shown In dotted lmes in Figure 4, by reason Due to the reduction gearing emof the fact that it is at the front of the machine. Gear 52 meshes with a gear 53 which is likewise at the front of the machine and is carried by a shaf 54. upon Which the rotary deflecting roller 55 is mounted.
The shafts 35 and 40, carrying respectively pulleys 33 and 38, are interconnected by means of inter-meshing gears 57 and 58 on shafts 41 and 36, and by the belts 32 and 37 already described. These shafts are both driven through a gear 59 disposed centrally on shaft 35 which meshes with ring gear 50 on the vise roll 30. Thus, the belts.32 and 37 and the rotary deflector 55, as well-as the vise rolls 29 and 30, are all driven at constant speed with reference to thefee-d rolls 8 and 9, inasmuch as it is unnecessary to change the relative speed of movement.
As best shown in Figure 3, the two driving rolls 9 on shaft 12 are axially spaced apart to receive between them a gear 60 which, if the rolls 9 are integrally connected, may comprise a ri'nggear- The rolls 8 which are illustrated in Figure 3 as, being integrally constructed are grooved at 60 to provide clearance for gear 60. The groove 60' lies between and defines the independent rolls 8 which act upon different webs of paper. Meshing with gear 60 is an intermediate gear 61 adj ustably supported on a stud 62 in the end of an arm 63 on a rock shaft 6 1. The rock shaft may be constructed in any desired manner to be supported in any adjustment with reference to the frame. For example, it may, as indicated in dotted lines in Figure 1, be provided with an arm. 65 substantially at right angles to arm 63'and provided with a slotted head 66 which may be secured in any position of oscillatory adjustment by means of a set screw 67 in threaded engagement with the frame. There is also a slot in arm 63 at 68 to permit the adjustment of stud shaft'62 radially of arm 63, whereby to maintain gear 61 in mesh despite the oscillatory adjustment of rock shaft 61 and arms 63 and 65.
J ournaled in the frame 1 is a cross shaft 70 upon which are slidably mounted a series of gears 71, 72, and 73 which may either be splined to the shaft or may be provided with set screws 74: for securing them in any desired position of adjustment thereon. The arrangement is such that any of the gears just described can be positioned selectively upon the shaft in the plane of intermediate gear 61 to receive motion therefrom. The adjustment of rock shaft 64 and arm 63 which carry gear 61 are intended and adapted to permit gear 61 to be moved into mesh simultaneously with its driving gear 60 and its driven gears 71, 72, or 73. While only three gears have been illustrated on shaft 7 0, it will be obvious that the number of gears on said shaft could be multiplied indefinitely to produce any desired relative speed between said shaft and the driving gear 60 on shaft 12.
.tively. Thus,
Keyed to shaft 70 at its ends are the disks 75 and 76 located respective at the front, and back of the machine. One of these disks is illustrated in elevation in Figure 6 and in sectionjln Figure 7. The disks are each apertured at 78 to receive threaded bolts '77. Co-operating with disks 75, 76 are disks 80 having "arcuat-e slots 81 to receive bolts 77 and carrying crank pins 82 and 82", respecthe arrangement is such that each crank pin is rotatably adjustable with reference to the shaft 7 0 with which it is connected for operation. The adjustment of the crank pins provides for the independent timing of the members driven through shaft 70, whereas the several gears 71, etc., on shaft 7 0 permit of the simultaneous adjustment for timing purposes of all elements driven through said shaft.
The crank pin 82 connected with shaft 70 at the rear of the machine receives a connecting rod 83, whereby it is joined to a rocker arm 84. on the rock shaft'85 which carries the tucker 31. The rotative movement of shaft 70 is thus transmitted to rock Q1121 H 85 to produce oscillation of said shaft and the corresponding movement of they tucker as previously described.
At the front of the machine, and preferably exterior to the frame thereof, shaft 85 carries a cam 105 which actuates a roller cam follower 106 on the reciprocable link 107. This link is connected at 108 with an arm 109 on rock shaft 28 which carries the deflector 27. A spring 110 presses link 107 downwardly to maintain cam follower 106 in operative contact with cam 105. The link 107 may be guided inany suitable means, such as the spaced rollers 11.1 and 112 connected with the frame of the machine. A retaining member 113 mounted on the axle studs of roller 111 and 112 maintains the link in operative position between the rollers.
The crank pin 82" at the front of the machine actuates a connecting rod 86 which is engaged with arm 87 on the rock shaft 46 which supports the packer 45. Therefore, the rotative movement .of shaft 70 produces the above described oscillations of the packer and such oscillations are not only adjustable simultaneously with the adjustment of the tucking blade but are also adjustable independently thereof through the medium of the adjustable crank pin support through which each of the connecting rods 83 and 86 is independently operated.
Reference has already been made to the gear 1 1 on driving shaft 10 through which all of the above described gearing and motion transmitting connections are operated. This gear also actuates a further line of power transmitting mechanism, including a gear 90 adjustably mounted on a stud shaft 91 which is carried in an arcuate slot 92 in the frame, the slot being concentric with the axis of shaft 10. Thus, while the shaft 91 is adj nstable, the gear 90 carried thereby Will always mesh with gear 14 to be driven therefrom.
A cross shaft 94 in the frame is adapted to carry interchangeably at its rear end any one of a series of any desired number of gears, of which the gear 95 is one. This gear is held in place by means of a nut 96 on the end of shaft 9 or by any other equivalent means adapted to permit of the ready removal of the gear 95 for the substitution of another gear of diifercnt size. This arrangement constitutes a well known type of change speed mechanism embodying change speed gearing of the so called take-01f variety. Other change speed mechanism might be employed, but inasmuch as there are ordinarily few changes or adjustments in a machine of this character no complicated change speed gearing would be warranted, and that illustrated has the advantage of being extremely simple and easy to operate.
Opposite to the end of shaft 94 which carries gear 95 is a disk 75 and a complementarydisk 80f corresponding to disks 7 5 and 80 previously described. Disk 80 carries a crank pin 82 which is connected by pitman 97 with the rocker arm 98 on rock shaft 99. This rock shaft also carries arms 100, which are illustrated in Figure 1, in any intermediate position from which they oscillate ,in both directions during the operation of the device. These arms 100 will correspond in number to the number of cutters to be actuated. For whileI have illustrated and described only two cutters side by side, it will be obvious that a machine of this character can be extended from front to rear to operate simultaneously upon as many webs as may be desired. The showing of means for operatingon two webs will be understood to exemplify the fact that a plurality of Webs may be treated with a machine of this type as readily as a single web may be acted upon. 7
The arms 100 on rock shaft 99 are provided at their upper extremities with clevises 101, whereby the adjustable links 102 are pivotally connected thereto. Each of the links includes a barrel 102 interiorly threaded to receive .right and left hand threaded members 103 and 104 (see F ig. 3) This arrangement permits of the. ready adjustment of the length of the links. The end of each link remote from its pivotal connection with the clevises of arms 100 is connected pivotally with one of the slides 17 which carry the shear bars 25. The arrangement is such that the rotation of shaft 94 causes the oscillation of shaft 99 and the correspondingreciprocation of the slides carrying the shear bar. By means of disks 75 and 80' the relative timing between the shear bars and the remainder of themachine may be varied without altering the synchronization of the parts.
driven s By' interchanging gear 95 with other gearsof different ratios relative to gear 14, and by adjusting the intermediate gear 90 accordingly, the synchronization of shaft 94 with the remainder of the machine may be altered to vary the length of sheet which will be severed during the forward and rear strokes of the shear bar. Independent adjustments of the shear bars may be made when necessary by means of the adjustable lengths 102.
The operation of the machine has already been fully described, and I have also described means for making adjustments in the driving connections to vary the relative positions of different elements acting upon the paper, and also to vary the timing or synchronization of such elements. As illustrated in the accompanying, drawings, gear 95 has a ratio of two to one as compared with the gear- 14 from which it is driven. In other words, gear 95 will make one rotation for each two rotations of rolls 8 and 9. As a result of this proportion, and as a further result of the fact that the shear bar 25 severs a blank from the web twice during each complete cycle, it
will be obvious that with the gear 95 as illustrated each blank will have a length equal to the circun'iference of rolls 8 or 9. .By substituting for gear 95 a gear of adifierent ratio with respect to gear 14, it is possible to cut from the longitudinally folded web portion 7 a blank having a length lesser or greater than the'circumference of roll 8. The length of' the blank will always be one-half of the circumference of gear 95, due to the fact that the shear bar 25 makes two cutting strokes for each rotation of said gear. Consequently, the operator can conveniently determine the size of gear 95 by selecting a gear which has a circumference equal to twice the length-of the desired blank. If such a subsitution be made, it is obvious that a corresponding substitution will have to be made in the gears through which the tucking blade is operated. Otherwise, the shortened blank would pass the tucking blade to a greater proportionate extent with each successive cycle of operation. In order to ensure that the tucking blade will strike the same relative portion of each successive blank acted upon by it, the severalgears 71, 72, and 73 are provided to corres 0nd in their ratios with gear 60 to the ratio a opted between gear 95 and gear 14. Note that a corresponding rather than an identical ratio is used. The tucking blade completes but one operation in its cycle of movement, whereas the shear bar-completes two operations in its cycle of movement. Thus, the circumference of that ear 71, 72, or 73 which is selected on iaft will always be equal to the length of the desired sheet in order that the tucker may 'of the chosen gear.
. The adjustment made possible by the use operate once during each rotation,
of disks 7 6 and 80 provides for a change in the relative position of the tucker so that a greater or lesser length of the blank may be allowed to pass the blade before being acted upon thereby. Thus, the blank may either be folded in its exact center or to one side of the center as may be desired, and consequently, it is possible to secure a wide variety of folds on a machine of this character. Note particularly that a change in the relative position of the tucker blade, such as may be accomplished by adjustment of plate or disk 80, has no effect upon the synchronization of the partsand permits them to continue to operate with the same timing as that previously employed. In other words, the number of operations performed in a complete rotation of the driving gear will be constant, although the point of the cycle at which each operation is performed may be adjusted.
I claim: I
1. In a device of the character described, the combination with web feeding mechanism, of a pair of relatively stationary shear bars associated with said mechanism and positioned to receive between them a web acted upon by said mechanism, a reciprocable shearbar associated with said stationary shear bars and adapted to interact with each of said stationary shear bars in the :eourse of each complete reciprocation, and driving connections for said feeding mechanism and said reciproeable s'he'aibar, said connections including change speed mechanism'operable to control the relative rates of operation of said feeding mechanism and shear bar.
2. In a device of the character described,
thecombin'at-ion with a rotary feeding device,
of a rotary driving member operatively connected therewith, a driven member rotatable concentrically with the driving member and rotatably adjustable with reference thereto, and a web cutter connected to be operated from said driven member and disposed to act upon material fed by said feeding device.
3. In a device of the character described,
the combination with a rotary web feeder, of a,
sociation with said feeder to sever blanks from webs acted upon by said feeder.
4. In a device of the character described, a web cutting device" comprising a bed member providing a longitudinally extending downwardly tapering bearing surface, a shear bar reciprocable on said surface, and a pair of '5 relatively stationary, closely spaced shearing surfaces positioned for co-opcration with said bar.
5. In a device-of the character described, a web shearing mechanism comprising a bed member having longitudinally extending, downwardly tapering bearing surfaces, a head reciprocable .on said surfaces and provided with a transversely extending shear bar. means for adjusting one of said bearing surfaces toward the other bearing surface, whereby to take up wear, and a plate confining said head upon said surfaces and provided with a transverse slot having margins co-operative with said bar.
ALDEN HUDSON.
US685987A 1924-01-14 1924-01-14 Machine for the manufacture of paper articles Expired - Lifetime US1714785A (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2579750A (en) * 1949-12-01 1951-12-25 Western Electric Co Shearing machine
US2757733A (en) * 1948-03-24 1956-08-07 Standard Brands Inc Double edged reciprocable cutting device
US3309952A (en) * 1964-01-08 1967-03-21 Yoder Co Flying cut-off
DE19548814A1 (en) * 1995-12-27 1997-07-03 Koenig & Bauer Albert Ag Funnel folding roller for a rotary printing press

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2757733A (en) * 1948-03-24 1956-08-07 Standard Brands Inc Double edged reciprocable cutting device
US2579750A (en) * 1949-12-01 1951-12-25 Western Electric Co Shearing machine
US3309952A (en) * 1964-01-08 1967-03-21 Yoder Co Flying cut-off
DE19548814A1 (en) * 1995-12-27 1997-07-03 Koenig & Bauer Albert Ag Funnel folding roller for a rotary printing press
US5718661A (en) * 1995-12-27 1998-02-17 Koenig & Bauer-Albert Aktiengesellschaft Folding roller for rotary printing press
DE19548814C2 (en) * 1995-12-27 1999-09-30 Koenig & Bauer Ag Funnel folding roller for a rotary printing press

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