US3376726A

US3376726A - Sheet material folding method and machine for carrying out said method

Info

Publication number: US3376726A
Application number: US422087A
Authority: US
Inventors: Rouyer Georges; Molin Charles
Original assignee: NORD AVIAT SOC NAT DE CONSTRNC
Current assignee: NORD AVIAT SOC NAT DE CONSTRNC; NORD-AVIATION NATIONALE DE CONSTRNCTIONS AERONAUTIQUES Ste
Priority date: 1964-01-14
Filing date: 1964-12-29
Publication date: 1968-04-09
Anticipated expiration: 1985-04-09
Also published as: GB1089999A; DE1452800A1; NL6500438A; FR86671E

Description

April 9, 1968 ROUYER ET AL 3,376,726

SHEET MATERIAL FOLDING METHOD AND MACHINE FOR CARRYING OUT SAID METHOD Filed Dec. 29. 1964 8 Sheets-Sheet 1 INVENTORS CHARLES MOLIN GEORGES ROUYER ATTORNEY Aprll 9, 1968 ROUYER ET AL 3,376,726

SHEET MATERIAL FOLDING METHOD AND MACHINE FOR CARRYING OUT SAID METHOD Flled Dec 29 1964 8 Sheets-Sheet 23 \NVENTORS CAQRLES MOLAN GEORGES ROUYER ATTORNEY April 9, I968 ROUYER ET AL 3,376,726

SHEET MATERIAL FOLDING METHOD AND MACHINE FOR CARRYING OUT SAID METHOD Filed Dec. 29, 1964 8 Sheets-Sheet 5 INVENTORS CHARLES MOUN GEORG ES ROUYER ATTORNEY April 9, 1968 ROUYER ET AL SHEET MATERIAL FOLDING METHOD AND MACHINE FOR CARRYING OUT SAID METHOD Filed Dec. 29, 1964 8 Sheets-Sheet 4 \NVENTQRS CHARLES MOUN GEORGES ROUYEQ ATTORNEY G. ROUYER ET AL SHEET MATERIAL FOLDING METHOD AND MACHINE FOR CARRYING OUT SAID METHOD 8 Sheets-Sheet 5 April 9, 1968 Filed Dec. 29. 1964 \NVENTORS CHARLES MOUN GEORGEfi ROUYER April 9, 1968 G. ROUYER ET AL 3,376,726

SHEET MATERIAL FOLDING METHOD AND MACHINE FOR CARRYING OUT SAID METHOD Filed Dec. 29. 1964 8 Sheets-Sheet 6 mvzu'roas CHAR LE5 MOLJN GEORGES ROUYER ATTOQNEY April 9, 1968 8 Sheets-Sheet 7 G. ROUYER ET AL SHEET MATERIAL FOLDING METHOD AND MACHINE FOR CARRYING OUT SAID METHOD Filed Dec. 29. 1964 \NVENTQR S mm a L M 00 0 w 5 A EE mm L mm April 9, 1968 ROUYER ET AL 7 3,376,726

SHEET MATERIAL FOLDING METHOD AND MACHINE FOR CARRYING OUT SAID METHOD Filed Dec. 29. 1964 8 Sheets-Sheet 8 2 \NVEN'TORS CHARLES MOUN GEORGES ROUYER BY A 4w ATTORNEY United States Patent 3,376,726 SHEET MATERIAL FOLDING METHOD AND MA- CHINE FOR CARRYING OUT SAID METHOD Georges Rouyer, Paris, and Charles Molin, Chatenay- Malahry, France, assignors to Nord-Aviation Societe Nationale de Constructions Aeronautiques, Paris, France, a French body corporate Filed Dec. 29, 1964, Ser. No. 422,087 Claims priority, appiication France, Jan. 14, 1964, 960,220; Oct. 26. 1964, 992,709 22 Claims. (Cl. 72-379) ABSTRACT OF THE DISCLOSURE A folding method for the formation of folds or corrugations on sheet material, which is preferably folded in the form of a cylindrical sleeve, the corrugations being formed in a single helical path on the sleeve by a pair of fixed forming rollers; while the sleeve is passed between these rollers.

The invention relates to a folding method, namely the formation of folds or corrugations on sheet material, these corrugations having various profiles and the folded sheet being in the form of a flat or other surface and in particular a cylindrical or conical sleeve.

The object of the invention is to provide a new method having multiple applications such as for example the production of the following products:

Elements forming part of the sandwich-type of panels for aeronautic or space travel (cowlings for aircraft engines or connecting skirts for missile stages).

Large-size expanding bellows (having a diameter of several metres).

Flexible pipes or conical sleeves of great length obtained by the screwing or fish-plating together of cylindrical or conical elementary sleeves.

Cylindrical enclosures having fluidtight walls obtained by the appropriate association of corrugated and uncorrugated sleeves assembled in the form of a sandwich structure.

The folding method according to the invention comprises in accordance with the well-known technique diagrammatically shown in FIG. 1, the use of two forming rollers G G of interengaged or conjugate shapes, namely male and female rollers, between which a thin sheet F of a material having characteristics suitable for the formation of a pressing constituted by a fold or corrugation O in the form of a continuous recess which is formed as the rollers are driven in rotation in opposite directions about their fixed axes X X as shown by the arrows f f the sheet moving in the direction of arrow f In the part of the sheet located immediately to the rear of the pinching zone P of the rollers, namely above the rollers relative to the direction of motion of the sheet F, a blister C is formed immediately before formation of the portion of the corrugation which is about to take shape. This blister is the result of a state of equilibrium, which is created at each relative position of the rollers and the sheet, between the bending created by the rollers in the portion of the sheet inserted therebetween and the internal tensions or stresses in said part of the sheet above the rollers, These tensions are complex and often in unstable equilibrium so that the instantaneous shape and dimensions of the blister C vary constantly in an irregular and unpredictable manner.

It has been discovered by the applicant that this phenomenon of the fluctuating formation of the blister can be utilized for preparing the regular formation of the portion of corrugation on the point of being formed, on condition that the blister is contained within predeter- 3,376,725 Patented Apr. 9, 1968 mined limits which are fixed relative to the zone P in such manner as to prevent undesirable excessive deformations of the blister. This blister then distributes the material at the moment of formation of the corrugation and by a regulating effect, corrects certain defects, such as the imperfect state of the surface, variations in the mechanical characteritsics which might exist in the sheet.

According to one feature of the invention, consequently, there is employed the forming method comprising the passage between forming rollers of conjugate shape, said method constantly ensuring that the blister, which is formed at the end of the corrugation being formed, is held within predetermined limits which are fixed relative to the pinching zone of the rollers.

This restraining action is obtained by pressing means which have rolling or sliding contacts with the sheet, these means being applied with such pressure as to form abutment lines which constantly prevent the blister from extending beyond these lines, the latter being fixed with respect to the pinching zone and above, aid zone relative to the direction of movement of the sheet.

According to another feature of the invention, in the case where the folding to be carried out comprises a series of evenly-spaced juxtaposed parallel corrugations-which is in practice the most frequent case-each corrugation is utilized as a guide for the formation of the following corrugation.

The corrugations can be formed on a plane sheet or on a cylindrical sleeve. In the latter case, it is advantageous to form a single corrugation in the form of a helix and to start with a sleeve made from a rolled sheet whose ends are butt-welded, a step or offset proportional to the developed length of the profile of the corrugation to be formed being provided between the two ends of the sheet,

1 the first spire of the helix being formed by employing the edge of the sleeve as a guide and the other coils being produced by employing the preceding coils as a guide. The folded or corrugated sleeve can be transformed into a plane folded sheet by cutting the sleeve along the weld line and developing the collar in a plane.

A variant of this method is applicable to the folding of a sleeve comprising at least one section of a conical surface, the folding resulting in the course of this operation in a reduction in the length of the apothem of the frustum of a cone and in an increase in the angle of conicity.

According to the method of this variant, in the course of the folding operation the sleeve is constantly supported by a support and guide means in contact with the surface of the sleeve, and the position and orientation of these means is progressively modified in accordance with the changes in shape, dimension, position and orientation undergone by the sleeve in the course of this folding operation, whereby these means constantly perform thei sleeve supporting and guiding functions.

Another object of the invention is to provide a machine for carrying out the method defined hereinbefore, said machine comprising at least one pair of forming rollers having conjugate profiles, means for driving said rollers at the same linear speed, supports for carrying and guiding the sheets to be folded, said machine further comprising means for containing the blister which are in sliding or rolling contact with the sheet to be folded (a plane sheet or collar).

Each of the male and female forming rollers can be replaced by a pair of rollers rigidly coupled together,

zrava'zaev the two rollers, namely the male roller and the self-guidin g female roller.

If the sheet to be folded is a sleeve and the folding comprises a single corrugation in the form of a helix, said pitch of the corrugations is equal to the pitch of the helix.

If the sleeve is frusto-conical, the support and guide means of the sleeve comprise a first series of cylindrical means mounted on a fixed unit and positioned and orientated in such manner as to be constantly in contact with the smooth uncorrugated part of the sleeve along generatrices whose extensions are concurrent at the moving geometric apex of this smooth part, and a second series of cylindrical means mounted on a movable unit and positioned and orientated in such manner as to be constantly in contact with folded part of the sleeve along lines of contact which are concurrent at the moving geometric apex of this folded part.

Another object of the invention is to provide sheets (this expression being intended to mean plane sheets and sleeves) folded by means of the method and machine defined hereinbefore, and a sleeve formed from a smooth rolled sheet whose two ends are welded and offset so as to produce a folded sleeve having a helical corrugation.

Further features and advantages of the invention will be apparent from the ensuing description with reference to the drawings to which the invention is in no way limited.

In the drawings:

FIG. 1 illustrates the known method as mentioned hereinbefore;

FIG. 2 is a diagram explaining the self-guiding method constituting one of the features of the invention;

FIG. 3 is a view of a variant of said self-guiding method permitting a progressive folding;

FIG. 4 is a diagrammatic view of a smooth circular sleeve prepared in a special way for carrying out the foldin g method;

FIG. 5 is a diagrammatic assembly view of one embodiment of the folding machine according to the invention;

FIG. 6 is a diagrammatic view of said machine at 90 to FIG. 5;

FIGS. 7, 8, 9 and 10 are partial diagrammatic detail views of various production stages showing, in the course of these stages, the positions of the various holding, positioning and containing elements;

FIG. 11 is a partial perspective view of the support means and the means controlling the various maintaining, positioning and containing elements;

FIG. 12 is a diagram corresponding to a longitudinal sectional view of a conical sleeve before and after fold- FIG. 13 is a diagram of the sleeve in the course of folding;

FIG. 14 is a perspective view of the formation of a corrugation by the machine employed in the ease of a frusto-conical sleeve;

FIG. 15 shows by way of example a machine for adapting special holding and guiding supports in the case of a frusto-conical sleeve, and

FIGS. 16 and 17 are longitudinal diagrammatic sections of a bi-concave folded sleeve and a bi-convex folded sleeve respectively.

The machine described hereinafter as one embodiment of the invention and shown in FIGS. 5-11, is a machine for producing cylindrical large-diameter folded sleeves by means of the principle of self-guiding rollers defined hereinbefore and forming on the sleeve 21 single helical spire or corrugation.

The principle of the self-guiding is shown as an example in FIG. 2 which illustrates a couple of forming elements 1 and 2 consisting of two pairs of rollers. The pair 1 comprises two or more male rollers 1a, 1b, rigidly coupled together or formed in one piece; the pair 2 comprises two or more

female rollers

2a, 2b rigidly coupled together or formed in one piece, the profiles of the female rollers being respectiveely conjugate with those of the rollers 1a, 1b. These two pairs are driven at the same linear speed so as to rotate about their parallel axes X X The

rollers

1a, 2a form the corrugation in a portion of the large-diameter sleeve V. In the drawing, coil 0 of this corrugation is in the course of formation. The rollers 1b, 2b are guide rollers, the coil 0 being interposed between these rollers and acting as a guide for the path of the corrugation 0 The distance between the planes of symmetry of the coils (or pitch of the helix) is obviously equal to the distance between the median planes of the rollers 1a and 111 (or 2a or 2b).

It is clear that the coil 0 will itself act as a guiding coil for the formation of the following coil and so forth.

When it is necessary to form deep corrugations or when these corrugations must be formed on thick sheets, forming elements could be employed which consist of rollers of different diameters, for example the forming elements shown in FIG. 3, each of which comprise three rollers, namely three

male rollers

1d, 1e, 1 in one piece or three

female rollers

2d, 2e, 2f. The profiles of the pairs of rollers ld-Zd, 1e-2e and lf-Zf have increasing values, the profile of the pair 1f2f corresponding to the profile of the corrugation to be obtained. In the drawing, the corrugation 0 being formed in the smooth part of the sleeve V, which undergoes a first forming through the pair of rollers 1d-2d, is of shallow depth; the corrugation 0 which is submitted to a second forming operation by the pair of rollers 1e2e, has a depth greater than the depth of the corrugation 0 the corrugation O is formed at normal depth by a third forming stage effected by the pair of rollers 1f-2f; the corrugation 0 was formed in the course of the preceding revolution of the sleeve.

FIG. 4 shows a mounted sleeve 3 prepared for constructing a circular large-diameter corrugated sleeve (for example having a diameter of 2.20 metres). This sleeve 3 consists of a strip of sheet steel 4 having a thickness of 0.1 mm. and of suitable grade corresponding, for example, to the grade Z12CNl8/8AFNOR or AISI301 of US. standards. This strip is wound in the form of a cylinder and it abuting ends are welded alng the weld line 5. No special preparation of the strip from the metallurigical or appearance point of view is necessary (variation for example in the surface finish can even exist in different zones of the strip). A step or offset 6 whose length is proportional to the development of the corrugation, is formed on one end of the sleeve. After welding, this sleeve is slipped onto a sylindrical support 7 having suitable outside diameter (slightly less than 2.20 mm. in the presently-described embodiment). The width of the smooth sleeve V is selected in accordance with the width to be obtained after folding, bearing in mind the number of corrugations to be formed and the shape and dimensions of the profile of the corrugations. For example, this profile could be a triangle having a pitch of 4 mm. (representing the pitch of the helix to be formed) and a height of 2.5 mm.

The forming machine according to the invention on which the sleeve 3 shown in FIG. 4 is disposed (the smooth sleeve being shown at 4 and the part therof already folded at 4P), comprises, as shown in FIGS. 5 and 6, a stand 8 carrying a motor speed-reduced unit 9 driving at the same linear speed and in opposite directions two

parallel cylinders

10, 11. The lower cylinder 11 is rotatable in a fixed bearing block 12, the upper cylinder 10 is mounted at its left end, as viewed in FIG. 5, on a bearing 13 which is pivotal on the bearing 12 in the direction of arrow f4 so as to permit pivoting the cylinder 10 and separating it from the cylinder 11.

These cylinders carry forming and self guiding elements, namely: on the cylinder 10, the

male rollers

10, 1b, 1c and on the cylinder 11, the

female rollers

2a, 2b, 2c The two sets of rollers are driven at the same speed by two gears 14, respectively keyed to the cylinders or

shafts

10 and 11 and meshed together.

I The pivoting of the cylinder 10 enables a mounted sleeve 3 to be inserted between the two sets of rollers. Guide supports 16a, 16b, 16c, 16d connected to the stand and applied to the periphery of the sleeve, hold the latter in position. These supports are movable so as to be adaptable to the various diameters of the sleeves. For example, in respect of the sleeve 3 shown in dotted line in FIG. 6, these supports could assume the positions shown at 1-6a to 1 6d.

Rollers, such as 17a to 17d, are so arranged as to permit the sleeve to be screwed along as the formation of the helical corrugation proceeds on the smooth surface of the sleeve.

The machine further comprises a number of rotary elements (rollers and cylinders) which can be seen in FIGS. 7 to 10.

Some of them are mounted on movable supports shown in FIG. 11.

These elements are the following:

Horizontal roller 18a, 18b, 180 (FIG. 7) which are in contact with one of the edges of the sleeve 4.

Horizontal rollers

18d, 18c which are in contact with the other edge of the sleeve.

Rollers

19 and 20a to 200 in contact with the cylindrical surface of the sleeve.

Shafts 21a to 21d provided with shouldered collars 22a to 22d applied under pressure against the whole of the sleeve (the collar 22d is not shown in the drawing but its position is obvious) and keyed to these shafts, are forming rollers 23a to 23d.

Two

arms

24a, 24b (FIGS 8 to 11) carrying cylindrical rollers or

cylinder

25a, 25b, and forming rollers Horizontal rollers 18a to 18a (FIG. 11) are mounted on forks controlled by slidable mechanisms 27a to 27c which are for example hydraulic jacks. The roller 19 is mounted on a slidable mechanism 28 which is, for example, a hydraulic jack. The rollers 20a to 200 are mounted on pivotal forks controlled by slidable mechanisms which can be, for example, jacks 29a to 290 the shafts 21a to 21d (FIG. 7) are rotative about fixed axes, as isthe roller 25d; the roller 250 (FIG. 11) is rotative about its axis, and the arm 24a which carries the roller is pivotable about a horizontal transverse pin (not shown in the drawing) so that it can be raised to the position shown in FIG. 11 or lowered so that the roller 26a is applied against the roller 26b.

All the hydraulic control mechanisms, or others, are

connected to the stand 12 of the machine. They can be controlled by a remote-control unit 30 (FIG. 11) which is so' arranged asto control the mechanisms in accord- .ahce with given frquencies; for example, as a function of .the angular position of the sleeve 4 relative to the stand of the machine.

The pivotable system 13 (FIG. 5) permits raising the cylinder 10 and introducing between the

cylinders

10 and 11, the sleeve 4 to be corrugated, which is mounted on the sleeve support 7. The step or offset 6 is so disposed that is interposed between the forming

rollers

1a and 2a.

The detail of the operations is shown in FIGS. 7, 8, 9 and 10.

In FIG. 7 it can be seen that the sleeve is maintained in position by the various rollers. The correct positioning of the step 6 between the forming

wheels

1a, 2a is insured by the

horizontal rollers

18a, 18b, 18c against which the sleeve 4 bears; the

rollers

19 and 20a, 20b, 20c, 20d control the path of movement of the step. The

rollers

18d and 18a maintain a constant pressure of the sleeve 4 against the rollers 18a to 180. Further, the shafts 21a,

- 21d carrying the shouldered collars 22a to 22d, which are applied under pressure against the whole of the sleeve 4 and its support 7, insure firstly that there is a constant distance between the support 7 and the forming

rollers

1a, 2a owing to the shoulder on the collars, and, secondly, in combination with the

cylinders

10 and 11, the three points of support necessary for the sleeve in its working zone.

When the

cylinders

10 and 11 are untightened, the sleeve on its support 7 is free to rotate but it is in abutting relation to the rollers 18a to and the support 7 is also in abutting relation to the shouldered collars 22a to 220. After the

cylinders

10, 11 are tightened and made to rotate, the step 6 automatically places itself between the wheels in, 2a.

The

cylinders

10, 11 drive the sleeve and this starts the formation of the corrugation in the step 6. As the corrugation is being formed (FIG. 8), the corrugation portion is inserted between the rollers 23a, 2311 keyed t0 the

shafts

21a, 21b. The bubble or blister C is created and this requires putting the pivotable roller 25a under pressure on the roller 2511, these

rollers

25a and 25b then performing the function of containing elements which maintain the blister and prevent an excessive spreading of the latter. When the corrugation has thus been started, the

rollers

18a, 20a (FIG. 7) can be withdrawn as they are now useless owing to the stiffness of the sleeve resulting from the corrugation. This withdrawal of the

rollers

18a, 20a is achieved by acting on their jacks 27a, 29a

(FIG. 11).

As the sleeve continues its movement of rotation, the corrugation (FIG. 9) is then inserted between the

rollers

23c and 23d (the latter is not visible in FIG. 9) respectively mounted on the

shafts

21c, 21d and between the rollers 26a, 2612 whose position is predetermined. The positioning rollers 18b to 182, 19, 20a, 20b are no longer needed and are withdrawn.

As the sleeve continues to rotate, the step 6 is inserted between the self-guiding rollers 1b, 2b and thereafter the corrugation is formed in a continuous manner (FIG. 10) by the screwing effect between the

rollers

17a, 17b, 17c etc., which was previously arranged for this purpose.

The machine can further comprise accessory mechanical regulating means permitting precise regulations.

The application of the process according to the invention, and the carrying out of this process by means of the machine whose embodiment has just been described, pro duces a sleeve whose corrugations have a strictly constant profile without the material employed undergoing any deformation.

It is also possible by means of the invention to obtain fiat corrugated sheets obtained from corrugated sleeves obtained in the above-described manner, these sleeves being subsequently split along a generatrix, preferably in the region of the weld line, and developed on a plane.

Although a specific embodiment of the invention has been described, many modifications and changes may be made therein without departing from the scope of the invention as defined in the appended claims.

In particular, according to a variant of the invention, a frustoconical corrugated sleeve can be obtained in a manner substantially similar to that described. The corrugations can be helical or perpendicular to the axis of the cone.

FIGS. 12-17 relate to this variant.

FIG. 12 shows a conical sleeve 4A before folding and at 4AP this sleeve in the folded state, it being clear that the folding of this sleeve results in a variation in the conicity owing to the decrease in the length from 1 to l consequential to the folding the diameters d d being unchanged. Another consequence of this folding is the dis placement of the apex of the cone from the point S to the point S The folding method described hereinbefore is applicable to the folding of a conical sleeve under the same conditions as a cylindrical sleeve when the conical sleeve is so disposed (FIG. 13) that the generatrix G 0f the cone (which has its apex at S is parallel to the axes X and X of the forming

rollers

10 and 11 and between the latter, the point a of intersection of the generatrix G and the generatrix G of the unfolded sleeve coincides with the pinching zone P of said rollers and, when it is desired to obtain a continuous corrugation, the preparation of the sleeve (FIG. 12) includes steps or offsets 6 on the weld line as in the case of a cylindrical sleeve described hereinbefore.

FIG. 14 shows a conical sleeve 4A in the course of folding. There is employed when folding a conical sleeve, a special support 7A. FIG. 14 also shows the

cylinders

10, 11 carrying the folding rollers 1 (the rollers 2 are not seen) and the

arms

24a, 24b carrying the

cylindrical rollers

25a, 25b and the forming

rollers

26a, 26b, these arms acting as means restraining the blister C.

The support must be completed by complementary supports adapted to maintain and guide the sleeve 4A.

The function of the additional supports depends on the modification of the geometry of the cone during its folding. It is obvious (FIGS. 12 and 13), that at the start of folding, the generatrices of the non-folded cone are protected at G and intersect the apex S that as the corrugations are being formed the generatrices of the folded cone are projected along a moving line G (FIG. 13) intersecting a moving apex S which moves toward S with the displacement of :1 toward the large base having a diameter d and that, relative to the

rollers

10, 11, the point S moves away along a line 8 a which is parallel to the axes X X Consequently, the point S has, relative to the

rollers

10, 11, a virtual displacement which is the result of the combination of two movements: namely the movement of S relative to S and the movement of S relative to a.

The machine shown in FIG. 15 by way of example comprises an assembly of means for embodying the aforementioned principle. This machine comprises mainly two

units

101, 102 receiving special supports. These units are disposed on the machine in such manner that the various maintaining, positioning and blister-restraining elements described with reference to FIGS. 7-10 can be suitably placed in position (for reasons of simplicity these elements have not been shown in FIG. 15).

One of the two units, namely 101, is fixed and rigid with the support of the machine. The other unit, 102, is movable and is moved in translation on a straight line parallel to the axes X X of the forming

rollers

10, 11. This displacement can be achieved by a lead-screw system (not shown) driven by a mechanism housed in the support 101. The guiding can be by means of bars 103 also rigid with the unit 101. The unit 102 supports a series of cylindrical rollers 102a, 1021; etc. which are so orientated that the generatrices of the cylinders which are in contact with the folded part 4A]? of the sleeve intersect at a point S These rollers are freely rotative about their respective axes Ya, Yb, Yc etc. The rollers 102a, 102b, 1020, etc., are connected to the unit 102 by suitable mechanisms 102A, 1028, 1020 etc., which permit changes in the position and orientation of these rollers which are necessary owing to the movement of the point S relative to the point a.

The fixed unit 101 supports a series of cylindrical rollers 101a, 101b, 101c etc. which are so orientated that the generatrices of the cylinders which are in contact with the smooth part of the sleeve converge at point S. These rollers are freely rotative on their respective axes Za, Zb, 20, etc. Owing to the particular displacement of the point S, the rollers 101a, 101b, 1010 etc. are connected to the unit 101 by

suitable mechanisms

101A, 101B, C etc. which permit the various orientations and displacements (in the direction of arrow P) which are necessary Owing to the movement of this point. An additional support 7A, which marries up with the inner shape of the sleeve 4A before folding, is connected to the unit 101.

The operation of the machine shown in FlG. is based on the principle illustrated in FIG. 13, the sleevefolding principle remaining that pertaining to cylindrical sleeves.

For purposes of simplification, the guide rollers have been eliminated, these rollers bearing in the hollows of the helical corrugations and permitting the screwing motion of the sleeve in the course of folding.

It will be obvious that the production of parallel corrugations is possible by successive displacements of the forming

rollers

10, 11; that the production of a portion of a conical sleeve with parallel corrugations is also possible in these conditions and that the dimensions of the elements to be folded are only limited by the possibilities of the machine.

The method is clearly also applicable in the production of a bi-conical convex folded sleeve (FIG. 16) or concave folded sleeve (FIG. 17) from a convex bi-conical smooth sleeve 4A or concave bi-conical smooth sleeve 4A the two apices of the two cones moving, in the course of the folding, toward the final positions S 5' these results being obtained by means of machines based on the same principle as the machine shown in FIG. 15.

It must be understood that in all embodiments of the machine according to the invention the elements controlling the rollers and other moving parts can be actuated by means other than hydraulic jacks; for example, these means could be mechanical, electrical or pneumatic devices.

The sleeves employed can be closed or open and have cross-sections other than circular. The corrugations can have perpendicular ribs on the flanks of the corrugations. The helical corrugations can have a single start or a plurality of starts, all these corrugations being formed in one or several runs through the machine with materials of any shape, type and thickness.

Having now described our invention what we claim as new and desire to secure by Letters Patent is:

1. A method for folding corrugations in sheet material, comprising passing the sheet between forming rollers having conjugate profiles and, in the course of folding, constantly containing the blisterwhich is formed at the end of the corrugation in course of formationbetween limits which are fixed relative to the pinching zone of the forming rollers.

2. A method as claimed in claim 1, wherein the blister is contained by pressure-applying elements in contact with the sheet on its both sides, said elements being applied with sufficient pressure to form abutment lines constantly preventing the blister from spreading beyond said lines, the latter being fixed relative to said pinching zone and located on the upstream side of said zone relative to the direction of feed of the sheet.

3. A method as claimed in claim 1, wherein in the case where the folding comprises a series of evenly spaced juxtaposed parallel series of corrugations each corrugation is employed as a guide for the formation of the next adjacent corrugation.

4. A method for folding corrugations in sheet material, comprising passing the sheet between forming rollers having conjugate profiles and, in the course of folding, constantly containing the blister-which is formed at the end of the corrugation in course of formation-between limits which are fixed relative to the pinching zone of the forming rollers, wherein the folding being effected on a sheet in the form of a sleeve and comprising a single helical corrugation.

5. A method as claimed in claim 4, wherein the sleeve is composed of a sheet wound in the form of a cylinder and having two abutting ends welded together, an offset in a direction parallel to the axis of the sleeve which is proportional to the developed length of the profile of the corrugation to be formed being provided between the two welded ends, the first coil of the helix being obtained by making use of the edge of the sleeve as a guide,

the other coils being formed by employing the preceding coil as a guide.

6. A method as claimed in claim 4, wherein in order to obtain a plane folded sheet the sleeve is cut along the buttweld and is developed in a plane.

7. A method as claimed in claim 1, for folding a sleeve having at least one frustum of a cone, the folding result ing in a reduction in the length of the apothem of the frustum of the cone and in an increase in the angle of conicity, said method being such that in the course of the folding the sleeve is constantly supported by support and guide means in contact with the surface of the sleeve, and the position and orientation of these means are modified as a function of the changes in the shape, dimension, position and orientation undergone by the sleeve in the course of said folding, whereby said means constantly perform their sleeve supporting and guiding functions.

8. A folding machine for forming corrugations in sheet material, said machine comprising at least one pair of forming rollers having conjugate profiles, driving means for driving said forming rollers at the same linear speed, and means for carrying and guiding the sheet to be folded, there 'being provided elements for containing the blister which is constantly formed in front of the portion of corrugation which is on the point of being formed, said containing elements being in contact with the sheet to be folded.

9. A machine as claimed in claim 8, wherein said elements comprise a pair of rollers applied against the sheet to be folded immediately on the upstream side of the pinching one of the forming rollers relative to the direction of movement of the sheet.

10. A machine as claimed in claim 9, wherein at least one of the containing rollers is mounted on a movable support which permits selectively moving said containing roller away from the sheet and applied thereagainst.

11. A folding machine for forming corrugations in sheet material, said machine comprising at least one pair of forming rollers having conjugate profiles, driving means for driving said forming rollers at the same linear speed, and means for carrying and guiding the sheet to be folded, there being provided elements for containing the blister which is constantly formed in front of the portion of corrugation which is on the point of being formed, said containing elements being in contact with the sheet to be folded, said sheet being rolled and welded so as to form a sleeve, said machine further comprising a support cylinder on which the sleeve to be folded is axially slida'ble, and means for maintaining and supporting the cylinder and sleeve in the course of their movement of rotation caused by the rotation of the pair of forming rollers.

12. A machine as claimed in claim 8, further comprising a self-guiding roller rigidly coupled to each of the forming rollers, the spacing between each pair of coupled rollers being equal to the pitch of the corrugations, the self-guiding rollers being disposed and orientated in such manner that the preceding corrugation formed is inserted between the two male and female selfguiding rollers.

13. A machine as claimed in claim 12, wherein said forming rollers are rigidly coupled to a plurality of other forming rollers having profiles of increasing diameters whereby each corrugation is formed in a plurality of passages of the sheet material through the machine.

14. A machine as claimed in claim 13, wherein said machine further comprises at least one pair of further forming rollers in which the formed corrugation is inserted so as to precisely position the sheet.

15. A machine as claimed in claim 8, wherein said machine comprises positioning rollers and movable supports for said positioning rollers which permit applying the positioning rollers on the edges of said sheet material.

16. A machine as claimed in claim 8, wherein said machine comprises positioning rollers and movable supports for said positioning rollers which permit applying the positioning rollers on the surface of said sheet material.

17. A machine as claimed in claim 15, wherein the movable supports are combined with actuating means which selectively apply the positioning rollers in an operative position against the sheet material and withdraw them to a position in which they are inoperative.

18. A folding machine as claimed in claim 8 for forming corrugations on sleeves having at least one frustum of a cone wherein the sleeve is carried by support and guide means comprising a first series of cylindrical means mounted on a fixed unit and positioned and orientated in such manner as to be constantly in contact with the smooth uncorrugated part of the sleeve along generatrices whose extensions are concurrent at the moving geometric apex of said smooth part, and a second series of cylindrical means mounted on a movable unit and positioned and orientated in such manner as to be constantly in contact with the folded part of the sleeve along lines of contact which are concurrent at the moving geometric apex of said folded part.

19. A folding machine as claimed in claim 17, where in the movable unit is slidably mounted so as to be movable in translation along a straight line parallel to the axes of the two forming rollers.

20. A folding machine as claimed in claim 18, comprising a lead-screw system for controlling the movement of translation of the movable unit in synchronism with the movement of the forming rollers, and guide rods parallel to the axes of said forming rollers guiding the movable unit.

21. A folding machine as claimed in claim 19, comprising mechanisms for mounting said cylindrical means on their respective units, at one of their ends, said mechanisms being synchronized with the movement of the forming rollers and automatically modifying the position of each of the means on the unit therefor and the orientation of each of said means, so as to achieve constantly contact of said means with the sleeve and the convergence of said means.

22. A machine as claimed in claim 16, wherein the movable supports are combined with actuating means which selectively apply the positioning rollers in an operative position against the sheet material and withdraw them to a position in which they are inoperative.

References Cited UNITED STATES PATENTS 326,516 9/1885 Pierce 72180 819,644 5/ 1906 Platau 72-180 1,860,989 5/ 1932 Brinkm'an 72-96 2,605,810 8/1952 Richardson 72-180 2,701,002 2/1955 Colvin 72-181 RICHARD J. HERBST, Primary Examiner. L, A. LARSON, Assistant Examiner.