US3871809A

US3871809A - External swivel connections for corrugating machine

Info

Publication number: US3871809A
Application number: US431227A
Authority: US
Inventors: James W Williams
Original assignee: Individual
Current assignee: Individual
Priority date: 1951-10-23
Filing date: 1974-01-07
Publication date: 1975-03-18
Anticipated expiration: 1992-03-18
Also published as: US2663351A

Abstract

A corrugating machine includes a series of longitudinally axially elongated rods and two generally parallel chains, and means interconnecting the ends of the rods with chain links of the two chains so that the rod ends can swivel relative to the links to which they are connected, and including a universal joint between each rod end and associated link, the joint including a member having axially slidable telescopic connection with the rod end.

Description

United States Patent [191 Williams Mar. 18, 1975 1 EXTERNAL SWIVEL CONNECTIONS FOR CORRUGATING MACHINE [76] Inventor: James W. Williams, 3029 Country Club Dr., Costa Mesa, Calif. 92626 [22] Filed: Jan. 7, 1974 [21] Appl. No.: 431,227

[52] US. Cl 425/370, 425/336, 425/396, 198/175 I51] Int. Cl. B29c 15/00 [58] Field of Search 425/336, 370, 396, 369;

[56] References Cited UNITED STATES PATENTS 1,293,295 2/1919 Amidon 425/370 2,236,932 4/1941 Aventsen 425/336 X 2,663,351 12/1953 Osborne et a1. 425/370 2,814,332 11/1957 M0113 425/336 X 3,032,452 5/1962 Magnaguagno 425/370 X 3,165,783 1/1965 Martelli 425/370 X 3,586,591 6/1971 Munters et a1 425/370 X Primary Examiner-Robert L. Spicer, Jr. Attorney, Agent, or Firm-William W. Haefliger [57] ABSTRACT A' corrugating machine includes a series of longitudinally axially elongated rods and two generally parallel chains, and means interconnecting the ends of the rods with chain links of the two chains so that the rod ends can swivel relative to the links to which they are connected, and including a universal joint between each rod end and associated link, the joint including a member having axially slidable telescopic connection with the rod end.

7 Claims, 6 Drawing Figures Fi-IEHTEB 3 87 1 809- SHEET 2 OF 3 Jars-.3.

EXTERNAL SWIVEL CONNECTIONS FOR CORRUGATING MACHINE BACKGROUND OF THE INVENTION This invention relates generally to improvements on corrugating machines, and more particularly concerns improvement in machines of the type disclosed in US. Pat. No. 2,663,351 to Osborne et al.

The Osborne machine incorporates parallel corrugating rods advanced by endless chains, the rods connected with the chains to swivel relative thereto. Such connections are provided by ball and socket elements located within rod end portions; however, in practice this required a relatively small diameter pin connection to the ball element, which was subject to breakage under operating loads. No way was known prior to the present invention to overcome this problem, considering the space and operating limitations imposed by the special type of corrugating machine to which the invention is applicable. I

SUMMARY OF THE INVENTION It is a major object of the invention to provide a solution to the above described problem. Basically, the invention involves the provision of a universal joint connection between the rod end and chain link and which is principally external to the rod end, the joint including a member having axially slidable telescopic connection with the rod end. Further, the telescopic connection may be defined by a bore in the rod end to receive the member for rotation therein, the joint may include parts external to the rod and having tongue and groove interfit, with a transverse pin interconnecting such parts for relative pivoting about a transverse axis normal to the longitudinal axis defined by the rod and member. One of such parts may be integral with the member and the other past removably connected with a chain link; and there may be a stop flange on the one part to engage the end of the rod and limit penetration of the member into the bore as the rod swivels in the manner to be described.

These and other objects and advantages of the invention, as well as the details of an illustrative embodiment will be more fully understood from the following description and drawings, in which:

DRAWING DESCRIPTION FIG. 1 shows a side view of a corrugating machine embodying the invention;

FIG. 2, a top plan view of the same;

FIG. 3, shows diagrammatically a horizontal section DETAILED DESCRIPTION Referring to the drawings in detail, a typical machine comprises in its principal features, a base 1, a pair of frames 2 and 3'having a series of sprocket wheels revolvable therein, and a pair of

endless conveyors

4 and 5 carried by the sprockets.

The base 1 is suitable supported, at a desired elevation, on a table 6, and presents a Hat and horizontal top surface.

The two frames 2 and 3 are substantially identical in form, except for some minor details to be described, and may be of any suitable shape for accommodating the. elements supported thereby. Each frame is here shown as comprising a pair of plates 7 set on edge and joined by straps 8, and'each frame has two brackets 9 and. 10 projecting inwardly .from the lower portion thereof. I i

The brackets9 of thetwo frames are pivoted to the base 1, as atll, on vertical axes, and with freedom of swinging movement in horizontal planes, the pivots being suitably spaced, as shown.

The brackets 10 carry pins 12 which are slidable in slots 13 in the base curved circularly about the pivots 11, and the distance between the pivots 11 and the pin 12 of one frame corresponds to that of the other.

A bar 14 connects the two pins 12 in such a manner that the distance between the pins 12, center to center, is the same as the distance between the two pivots ll, center to center.

Thus the two pivots 11 and the two pins 12 may be positioned to form the four corners of a rectangle, as in FIG. 3, with the two frames occupying positions of parallelism with respect to a median plane of the machine, indicated at 15, or they may be positioned to occupy the four corners of any desired shape of parallelogram, within the range of the machine, as shown in FIG. 4, with the two frames arranged parallel to one another but obliquely .with respect to the former position. Any desired change in the angularity of the frame may be brought about by the mere turning of one of the frames about its pivot 11.

Each frame carries a pair of upper sprockets 16, mounted on shafts 17, and a pair of lower sprockets 18 mounted on shafts 19, the upper sprockets of each frame being in horizontal alinement with one another, longitudinally of the machine, and the lower sprockets being also horizontally alined longitudinally of the machine. The sprockets are all of the same size and corresponding sprockets of the two frames are axially alined. All the sprockets of each frame are disposed in the same vertical plane.

The sprockets are mounted parallel to the frames, and the upper and lower sprockets are closely related, while there is a certain amount of spacing between the front and rear sprockets.

The two conveyors 4 and Sare ofidentical construction and are made for training over the upper and lower sprockets respectively. Each conveyor comprises a pair of side chains 20 and transverse rods 21 connecting the same. Each of the chains comprises a series of pivot pins 22 and'double sets of links 23 connecting the same with spacers 24 on the pins serving to space the links. These chains are dimensioned and proportioned for training over the sprockets. The inner links, that is the links of opposing chains facing each other, are formed with outwardly projecting lips 25 (see FIG. 6), and the outer ends of these lips have short stubs 26 projecting therefrom perpendicularly toward the opposing chain. The stubs may be secured by studs 104a for easy removal and replacement.

The two chains of each conveyor are mounted on their respective sprockets in such a manner, that the stubs of one chain are alined with registering stubs of the other chain when the two frames occupy the positions of FIG. 3, which may be described as the rectangular position.

. More comprehensively, and referring to FIGS. 5 and 6, means is provided to interconnect the ends of the rods 21 with chain links of the two chains so that the rod ends can swivel relatively to the chain links to which they are connected. Such means includes a universal joint 100 between each rod end and associated chain link, the joint including a member as for example at 101 having axially slidable telescopic connection with the rod end 21a. Such telescopic connection is with unusual advantage defined by a bore 102 in the rod end,- the circular cross section member 101 rotatably received in the bore and having a diameter at least half that of the rod, for strength. Further, the joint 100 may also include first and second parts external to the rod, as for example tongue part 103 and yoke part 104, having tongue and groove intertit, a transverse pin 105 interconnecting the parts for relative pivoting about transverse axis 106 normal to the longitudinal axis 107 defined by the rod 21 and member 101. Note the sliding engagement of

parts

103 and 104 along flat sides at planes 115, for added strength. Part 103 is integral with swivel member 101, and part 104 has removable connection with chain link 23a. The latter connection may include a threaded stud 104a on part 104 projecting through the link 2311 and a nut 108 on that stud, as

shown.

It will be noted that each rod bears upon the material at the same time throughout the width of the material and is free to roll into the wave thus eliminating any tendency of the material to tear or crack, and causing the material to travel in a straight line.

If the strip of material is to be corrugated obliquely with respect to its length, the operator may grasp either of the frames and turn it to the desired angle. The two frames being interconnected by the member 14, both will swing in unison on their pivots 11 and will retain their parallel positions. The feeding devicewill swing with one of the frames and will retain its position along the median plane between the two frames.

The chains along the sides of the two conveyors will turn with the frames, and the rods 21 will swing on their pivots, as shown in FIG. 4, to assume the desired angularity with respect to the median plane between the frames.

It should be noted that the entire swing movement is in a horizontal plane, and that each rod retains its horizontal position, not only while passing through the horizontal stretches of the conveyors, but also when passing around the sprockets. While the sprockets have shifted with respect to one another in a fore and aft direction, still each rod is connected to both chains at the same elevation, no matter where positioned in its endless path, which is an important factor in the forming of the waves in the strip of material.

As now the strip of material is passed between the conveyors in a horizontal plane, the first rod to engage it, also approaches it while positioned horizontally,

with the result that, in spite of the angularity, the entire active length of the rod strikes the material at the same time to form a uniform wave in the strip.

This feature is desirable since it prevents tearing or rupturing of the sheet material, such as would tend to occur if the rods were to engage the material in a tilting movement, beginning at one end and ending up at the other end.

Any suitable and conventional means 'may be employed for heat-treating and drying the material as it passes through the machine, for applying flat sheets of material to the upper or lower surfaces of the corrugated material or both, and for'spiralling the material upon a mandrel, which should be positioned and dimensioned to apply the corrugations parallel to the axis of rotation.

It is not necessary to combine all the novel features in order to produce an operative machine. Where a manufacturer, for instance, desires to only corrugate material at a right angle to the length of the strip, the feature of adjustability to different angles might be omitted. Where again, the manufacturer desired to corrugate the strip at a definite single angle throughout its v operation, the machine might be. built to conform to that particular angle, again omitting the feature of angular adjustability.

Where a manufacturer desired a universal machine that may be set for any desired angle, the novel features may be combined into a single structure.

If any one of the rods 21 should break or become deformed, it may be readily removed, with its stubs 26, upon unscrewing of the threaded part 104a, as permitted by rotation of stem member 101 in bore 102, for replacement of a new rod.

While one specific means for mounting the frames 2 and 3 with freedom of adjustment to produce angularity of the corrugating elements has been shown, it is apparent that other means serving the same purpose may be substituted. The two endless conveyors, here shown as being of the same length, may be made of different lengths, and it is also feasible to carry the conveyors on single pairs of sprockets, in which case each rod would follow a circular path.

The rods 21, which have been shown as single units pivoted centrally, may be made in groups of two or more parallel rods pivoted about a common center, particularly where the corrugations are to be closely spaced. The rods. might also be made in the form of bars having multiple serrations and mounted in the same manner.

The upper plates 7 are preferably mounted on the straps 8 with freedom of vertical adjustment, as by the bolt and slot arrangement 8 to allow of control of the depth of the corrugations.

If desired, idler sprockets may be substituted for the shoes 28.

Further, a stop shoulder is provided on part 103, and may take the form of an integral flange 109 engagable with the end 210 of the rod to limit axially slidable penetration of member 101 into bore 102.

It should be noted that the rods, from pivot to pivot, should correspond in length to the distance between the pivots l1, and to the distance, center to center, between the pins 12 on the base, and that all the ball and socket joints, on each side of the machine, should lie in the vertical planes defined by the pivots 11 and the pins 12, these planes being indicated in FIGS. 3 and 4 and 5 by the numeral 30. This arrangement allows therods to follow any swinging movement of the frames about their pivots.

The confronting stretches of the conveyors between the sprockets are guided by shoes 28 to prevent sagging or buckling.

Rotary movement may be imparted to the sprockets by any suitable drive. In the form shown, I provide a central vertical power shaft 31 mounted in a bearing 32 secured upon the table. This shaft drives, through a gear 33, two gears 34 mounted concentric with the fixed axes or pivots 11. The gears drive, through gears 35, vertical shafts 36 mounted upon the outer faces of the frames 2 and 3. And each of the shafts drives the upper and lower front sprockets through bevel gears indicated at 37 and 38.

One of the frames has a forward extension 39 which carries a shaft 40 and a spool 41, the latter being in central alinement with conveyors. The extension may also carry a suitable material treating tank 42, used as a rule for heating or pre-treating the material coming from the spool, and having an exit roller 43, over which the strip ofmaterial is guided toward the space between the two conveyors, the material passing over the crossmember 44 and possibly an inclined guide 45, which is old in the art and is used to bias the strip to follow a straight track while passing through the machine.

The machine can be used on any sheet material having such characteristics that it may be corrugated as is well known to those familiar with corrugating machines and methods.

If it is desired to corrugate the strip of material transversely to its length, the machine is adjusted to the position illustrated in FIGS. 1, 2 and 3, with the pins 12 in the inner ends of the slots l3,'and the pivots 11 and pins 12 arranged to form a rectangle.

Assuming that the material is such as to require softening before being corrugated, it can be fed into the machine, that is, between the two conveyors, in slightly moistened condition. The confronting stretches of the two conveyors are sufficiently close to cause the projecting rods 21 to interlace and, as the strip enters, the

extended time period so as to allow the wave to set be-' each rod end and associated link, the joint including a member having axially slidable telescopic connection with the rod end and wherein said telescopic connection is defined by a bore in the rod end, the member rotatably received in the bore.

2. The combination of claim 1 wherein said joint includes first and second parts having tongue and groove interfit, and a transverse pin interconnecting said parts for relative pivoting about a transverse axis normal to the longitudinal axis defined by said rod and said memher.

3. The combination of claim 2 wherein one of said parts is integral with said member, and the other of said parts is removably connected with a chain link.

4. The combination of claim 3 including a stop shoulder on said one part and engagable with the end of the rod to limit axial penetration of said member into said bore.. i

5. The combination of claim 3 including a first vertical frame and means for swingably mounting said frame on a vertical axis, a second vertical frame and means for swingably mounting said second frame on avertical axis and in confronting and spaced relation to the first frame, upper and lower sprockets carried by each frame in parallel relation thereto, and a pair of conveyors mounted on the sprockets so as to present confronting sections, the conveyors including said rods operable to change their angularity when the frames are swung on their respective axis and mounted to interlace at the confronting sections. I

6. The combination of claim 3 wherein said parts are external of the rod end.

7. The combination of claim 6 including a stop flange on said one part and located'in spaced relation to the rod end, said flange directly facing the rod end.

Claims

1. In a corrugating machine, the combination comprising a. a series of longitudinally axially elongated rods and two generally parallel chains, b. means interconnecting the ends of the rods with chain links of the two chains so that the rod ends can swivel relative to the links to which they are connected, and including a universal joint between each rod end and associated link, the joint including a member having axially slidable telescopic connection with the rod end and wherein said telescopic connection is defined by a bore in the rod end, the member rotatably received in the bore.

2. The combination of claim 1 wherein said joint includes first and second parts having tongue and groove interfit, and a transverse pin interconnecting said parts for relative pivoting about a transverse axis normal to the longitudinal axis defined by said rod and said member.

4. The combination of claim 3 including a stop shoulder on said one part and engagable with the end of the rod to limit axial penetration of said member into said bore.

5. The combination of claim 3 including a first vertical frame and means for swingably mounting said frame on a vertical axis, a second vertical frame and means for swingably mounting said second frame on a vertical axis and in confronting and spaced relation to the first frame, upper and lower sprockets carried by each frame in parallel relation thereto, and a pair of conveyors mounted on the sprockets so as to present confronting sections, the conveyors including said rods operable to change their angularity when the frames are swung on their respective axis and mounted to interlace at the confronting sections.

6. The combination of claim 3 wherein said parts are external of the rod end.

7. The combination of claim 6 including a stop flange on said one part and located in spaced relation to the rod end, said flange directly facing the rod end.