EP0374917A2 - Conveyors for signatures - Google Patents

Abstract

A signature conveyor comprises a first conveying means (64) which conveys signatures (40) in sequence to a delivery station (60). At the delivery station (60), the signatures (40) are transferred in sequence to a receiving conveying means (74). A shaping device (126) is positioned at the delivery station (60) in order to reinforce the signatures (40) by shapings (132) being formed in the signatures (40), which shapings extend between their front and their rear end parts (46, 48). Although the shapings (132) are only maintained in the signatures (40) temporarily, the shaping device (126) is mounted sufficiently near to the receiving conveying means (74) for a shaping (132) in a signature (40) to be able to be maintained while the front end part (46) of the signature (40) moves towards the receiving conveying means (74). Thus the shaping device (126) is situated at a distance from the receiving conveying means (74) which is less than the distance between the front and the rear end parts (46, 48) of the signatures (40). <IMAGE>

Description

The invention relates to a device for transporting signatures, in which signatures (or sheets) are successively transferred from one conveyor belt to another.

A known signature transport device has a belt (or belt) transport which conveys signatures one after the other to a delivery station. At the delivery station, the signatures are transferred into pockets of a paddle wheel. The paddle wheel then conveys the signatures on a delivery belt (or belt) transport.

The operating speed of this known signature transport device is limited in that the signatures are transferred from the belt transport into the pockets of the paddle wheel. The signatures consist of one or more sheets of flexible material, which has the tendency to bend outwards due to air resistance or disturbing currents, so that the signatures can open and / or move in an undesired direction while moving from the belt transport means onto the Paddlewheel are transmitted. This uncontrolled transfer of the signatures through the air between the belt transport and the paddle wheel limits the transport speed of the signatures in at least one known signature transport device to approximately 1,200 feet (= 366 m) per minute.

The present invention provides a new, improved signature transport device in which a first Means of transport includes a delivery station at which the signatures are transferred to a second means of transport. In order to increase the speed at which the signatures can move between the means of transport, one or more deformations are formed in the signatures in order to stiffen them. There is thus a deformation device at the delivery station of the first transport means, which forms successive deformations between the front and rear end parts of the signatures.

Since it is desired to have the signatures free from deformations after the transfer from the first to the second transport means, the signatures are deformed in an elastic manner by the deforming device, so that deformations occur temporarily, which disappear again after the signatures are removed from the Have moved the deforming device. In order that the deformations in the signatures are preserved between the means of transport during their transportation at high speed, the deforming device is arranged at a distance from the second means of transport which is less than the distance between the front and rear end parts of a signature. Thus, during the movement of a front part of the signature through the space between the two transport means and its initial contact with the second transport means, a rear part of the signature is in the deforming device.

Accordingly, it is the object of this invention to provide a new and improved signature transport device in which signatures are transferred from a first to a second transport means and in which a deforming device on the first transport means is at a distance from the second transport means which is less than the distance between the front and rear end parts a signature so that its front end part can move to the second means of transport while the signature is still in contact with the deforming device.

• Fig. 1 ist eine schematische Darstellung eines Falzapparats mit einer Signaturtransportvorrichtung, in welcher Signaturen von einem Bandtransport auf ein Schaufelrad übertragen werden;
• Fig. 2 ist eine vergrößerte, fragmentarische schematische Darstellung des Zusammenhangs zwischen einer Verformeinrichtung an einer Auslagestation des Bandtransports und dem Schaufelrad, während eine Signatur in das Schaufelrad bewegt wird;
• Fig. 3 ist eine vergrößerte, etwas schematisierte Draufsicht, welche aufzeigt, wie die Verformeinrichtung Verformungen in einer Signatur bildet;
• Fig. 4 ist eine Darstellung Signatur mit darin gebildeten Verformungen;
• Fig. 5 ist ein vergrößerter, fragmentarischer Querschnitt, welcher die Konstruktion eines Formprägesegments der Verformeinrichtung in Fig. 3 darstellt; und
• Fig. 6 ist eine fragmentarische, schematische Darstellung einer Verformwalze in einem Ausführungsbeispiel der Erfindung, welche eine Vielzahl von Verformungen in einer Signatur bildet.

The above and other objects and features of the present invention will become apparent from the following description and explanations with reference to the accompanying drawings.

• Fig. 1 is a schematic representation of a folder with a signature transport device in which signatures are transferred from a belt transport to a paddle wheel;
• 2 is an enlarged, fragmentary, schematic illustration of the relationship between a deforming device at a belt transport delivery station and the paddlewheel while a signature is being moved into the paddlewheel;
• 3 is an enlarged, somewhat schematic, plan view showing how the deforming device forms deformations in a signature;
• 4 is an illustration of the signature with deformations formed therein;
• Fig. 5 is an enlarged, fragmentary cross section illustrating the construction of a die embossing segment of the deforming device in Fig. 3; and
• 6 is a fragmentary, schematic illustration of a forming roll in one embodiment of the invention, which forms a plurality of deformations in a signature.

The following description relates to a preferred embodiment of the invention.

Folder

A deflection folder 10 (FIG. 1) comprises a signature-forming section 12 and a signature-transporting section 14. The signature-forming device 16 in the signature-forming section 12 can be actuated to pre-fold and cut a sheet material web 18 running in the longitudinal direction. The signature-forming device 16 has funnel rollers 22, which cooperate with a former 19 to form a longitudinal fold in the web 18 in a known manner. Press rolls 24 and 26 press on web 18 to further develop the longitudinal pre-fold in web 18.

The pre-folded web is transported by feed rollers 30 to the cutting cylinders 32 and 34. During each revolution of the cutting cylinders 32, 34, knives cut or separate the web in a direction perpendicular to the pre-fold to form signatures 40 (FIG. 4) in a known manner.

Each signature 40 has a closed or pre-folded edge part (42) (FIG. 4), which is located opposite an open-edged part 44. The signature 40 has a leading end portion 46 and a rear end portion 48 as it moves out of the cutting cylinders 32 and 34. When the signature 40 leaves the cutting cylinders 32 and 34, the majority of their opposite outer side surfaces 52 and 54 are flat.

The signature transport device 14 comprises two display sections, ie a left display section 58 and a right display section 60 (see FIG. 1). The left delivery section 58 includes a first or belt conveyor 64 which accelerates the signatures received from the signature-forming apparatus 12 to separate their front and rear end parts. Deflection rollers 68 and 70 direct every other signature onto the left delivery section 58 and a second transport device or a paddle wheel 74.

In the right delivery section 60 (FIG. 1), a first or belt conveyor 76 interacts with the belt conveyor 64 in order to successively accelerate the signatures 40 received by the cutting cylinders 32 and 34. The deflecting rollers 68 and 70 enable the first or belt transport 76 to convey every second signature in the sequence to a second transport means or paddle wheel 78.

During operation of the folder 10, the deflection rollers 68 and 70 receive a steady stream of signatures from the cutting cylinder 32 and 34. The signatures are accelerated by the interaction between the belt transports 64 and 76 to the signatures before they enter the nip between the deflection rollers 68 and 70 to split a little. Deflection rollers 68 and 70 rotate in a timing relationship with cutting cylinders 32 and 34 and alternately direct the signatures to left and right delivery sections 58 and 60. Thus, if a signature is directed from deflection rolls 68 and 70 to left delivery section 58, then the next signature is directed to the right display section 60.

When the deflection rollers 68 and 70 are in the position as shown in FIG. 1, they are able to deflect a signature onto the left delivery section 58. If the deflection rollers 68 and 70 have been rotated by 180 degrees from the position shown in FIG. 1, then these are in able to deflect a signature onto the right delivery section 60. The manner in which the deflection rollers 68 and 70 cooperate to sequentially direct signatures onto the left and right delivery sections 58 and 60 is known and will not be described further here to avoid proliferation.

The first or belt transport 64 in the left delivery section 58 comprises a plurality of relatively narrow upper belts 82 which are spaced apart and which are in contact with the main part of a side surface (54) of a signature (40). Likewise, a plurality of spaced apart, relatively narrow lower bands 84 are in contact with the major portion of the opposite side surface (52) of a signature 40. The signature 40 is held between the belts 82 and 84 and controlled by them and moved at a relatively high speed.

It should be emphasized that even if only a single band 82 has been shown in FIG. 1, there are a plurality of spaced-apart bands 82, specifically six bands (see FIG. 3), which are associated with the main part of FIG a side surface 54 of a signature (40) is in contact. Likewise, it should be emphasized that, even though only a single band 84 has been shown in FIG. 1, there are six spaced-apart bands 84 (FIG. 3) which contact the major portion of the other side surface 52 of a signature 40 are in positions opposite to where the tapes 82 are in contact with the signatures. The tapes 82 and 84 extend around guide rollers and engage the opposite sides of a signature 40 to convey in a known manner without slippage between the tapes and the signatures.

In the embodiment of the invention shown here, the second transport means 74 is a rotatable paddle wheel. The Paddle wheel 74 receives the signatures 40 from the belt conveyor 64. Thus, the belt conveyor 64 has a delivery station 88 (FIG. 2), where the signatures are transferred from the first or belt conveyor 64 to the second transport means or paddle wheel 74. If desired, the belt conveyor 64 and / or the paddle wheel 74 can be replaced by other known types of transportation means.

The paddle wheel 74 has an all-round row of pockets 92 (FIG. 2), which extend radially outward from a hub 94. The pockets 92 are formed by adjacent blades or wheel elements 96. The wheel members 96 cooperate to form the outer end portions 100 of the pockets 92. These open outer end portions 100 of the pockets 92 move in a circle as indicated by a broken line 104 in FIG. 2. The axis of rotation of the impeller 74 extends perpendicular to the longitudinal axes of the belts 82 and 84.

When the open end portion 100 of a pocket 92 is upward and at the delivery station 88, a signature 40 moves into the pocket, as shown schematically in FIG. 2. After the paddle wheel 74 has rotated approximately 180 degrees, the signature moves out of the pocket under the influence of gravity or a mechanical scraper arm onto a third or delivery belt conveyor 108 (FIG. 1).

When a signature 40 moves into a pocket 92 in the manner shown schematically in FIG. 2, the front end portion 46 of the signature pushes through the open outer end 100 of the pocket. As the paddle wheel 74 continues to rotate clockwise, as shown in Fig. 2, the belt conveyor 64 moves the signature 40 down into a pocket 92 at a speed greater than the speed at which the paddle wheel 74 removes the pocket from the delivery station 88 moved away.

While the bag is being rotated further and the signature 40 moves downward in the bag, its rear end part is released by the belt transport 64 at the delivery station 88. The signature 40 then falls freely down into the pocket 92 under the combined influence of its moment of motion and its gravity. During the free fall of the signature 40 into the pocket 92, the front end portion 46 of the signature touches a closed inner end portion or the bottom 112 of the pocket 92.

After a signature 40 has left the belt conveyor 64 and has been received in a pocket 92, the paddle wheel 74 rotates it to a position opposite the delivery station 88. The signature 40 then falls out of the pocket 92 onto the delivery belt conveyor 108 (Fig. 1), whereupon it is conveyed out of the folder 10.

The belt conveyor 76, the paddle wheel 78 and a delivery belt conveyor 116 in the right delivery section 60 work together in the same manner as described here above for the belt transport 64, the paddle wheel 74 and the delivery belt transport 108 of the left delivery section 58. Thus, signatures 40 move sequentially from a delivery station 120 (FIG. 1) of the belt conveyor 76 into the pockets of a rotatable paddle wheel 78. The signatures 40 are transferred from the paddle wheel 78 to the delivery belt conveyor 116.

The general construction and type of function of the above-mentioned components of the folder 10 are known. Belt transports have been used to transport signatures into paddle wheels. The paddle wheels have also been used to transfer signatures to delivery conveyor belts.

In the illustrated embodiment of the invention, it is preferred to use two belt transports 64 and 76 with two paddle wheels 74 and 78. However, a greater or lesser number of means of transportation could be used if desired. Types of means of transport that differ from the means of transport shown could also be used, if desired. For example, the second transport 74 could have a linear array of pockets. Certainly other known types of signature shaping apparatus 16 could be used if desired.

Corrugated device

According to a feature of the present invention, a deforming device 126 (FIGS. 1, 2 and 3) is located at the delivery station 88. The deforming device 126 stiffens the signatures 40 by forming a deformation 132 (FIG. 4) in each signature. Deformation 132 extends from front end portion 46 to rear end portion 48 of signature 40. Deformation 132 stiffens signature 40 and causes it to remain closed and not sag as it moves from delivery station 88 to paddle wheel 74 (Fig . 1). Without deformation 132, the signature 40 tends to sag and / or open its front end portion 46 as it is moved from the delivery station 88 to the paddle wheel 74.

However, the formation of a deformation 132 in the signatures 40 stiffens them and thereby prevents the signature material from bending, so that the signature 40 tends to remain closed and not to bend as it moves from the delivery station 88 into a pocket 92 of the Paddle wheel 74 moves in. Since the signature 40 remains rigid due to the deformation 132 and does not bend as it moves through the space between the Delivery station 88 and the paddle wheel 74 moves, it can be moved at a relatively high speed from the first or belt transport 64 to the second transport means or paddle wheel 74. In a specific folder, this additional deformation 132 made it possible to increase the transport speed of the signatures 40 from approximately 1,200 feet (= 366 m) per minute to between 1,800 and 2,000 feet (= 549 m and 610 m) per minute.

The exact speed at which a deformed signature 40 can be moved from the first transport means 64 to the second transport means 74 will vary due to many factors. Thus, the speed at which the deformed signature moves between the transport means can fluctuate due to the different thickness and / or flexibility of the material of the signature. However, by forming the deformation 132 in a signature 40, the speed at which it can be moved between the means of transport can be significantly increased. Since many factors can affect the speed at which signatures 40 are fed from the tape conveyor 64 to the paddle wheel 74, it should be understood that the present invention is not limited to any particular signature supply speed.

Although the deformation 132 stiffens the signatures 40 so that they can be sequentially transferred from the belt conveyor 64 to the paddle wheel 74 at a relatively high speed, the signatures should have smooth side surface main parts 52 and 54 when they come out of the folder 10. That is, the deformation 132 temporarily and disappears after the signature 40 has moved into the impeller 74.

So that the deformation 132 disappears again, the signature 40 is elastically bent by the deforming device 126, one that it is folded or deformed. After the signature 40 has completely passed through the deforming device 126, the natural elasticity of the sheet material forming the signature causes it to reform into the original shape. The deformation 132 will therefore disappear after the signature 40 has left the deformation device 126.

The deformation 132 remains in the signature 40 as long as it is in the deformation device 126, in which the material of the signature 40 is bent elastically and the deformation 132 is maintained.

The opening 100 (FIG. 2) to a paddle wheel pocket 92, which is intended to receive a signature 40, is located at a distance from the deforming device 126 that is substantially less than the distance between the front and rear end parts 46 and 48 of the signature 40. Therefore, the signature 40 is still in contact with the deforming device 126 when it enters a pocket 92 of the impeller 74. The deforming device 126 can thus maintain the deformation 132 in the signature 40 and keep it rigid, while the front end part 46 thereof moves through the space between the belt conveyor 64 and the paddle wheel 74.

The controlled delivery of a signature 40 into a paddle wheel pocket 92 can be improved by maintaining the deformation 132 during most of the time that the signature 40 is moving into the pocket. Accordingly, the deforming device 126 is close to the orbit 104 of the outer end or the tips 136 (FIG. 2) of the blade elements 96. This makes it possible for one Signature 40 for the large part of the time in which it is fed from the delivery station 88 to a pocket 92 can remain in contact with the deforming device 126.

When the rear end portion 48 of a signature 40 leaves the deforming device 126, more than 50% of the signature length between the front and rear end portions 46 and 48 of the signature 40 will be accommodated in a pocket 92 of the paddle wheel 74. This means that the deformation 132 is maintained by the deforming means 126 during most of the time a signature 40 is fed into a pocket 92 so that the signature 40 remains relatively stiff and is easy to control.

When the rear end portion 48 of a signature 40 leaves the deforming device 126, the pressure on the signature 40 to form the deformation 132 ends. At this point the deformation 132 in the signature 40 begins to disappear again due to the natural elasticity of the material. Even if there is still a slight deformation 132, this will essentially have disappeared at the time the signature 40 is placed on the delivery belt conveyor 108 (FIG. 1).

The deforming device 126 protrudes between the bands 82 (see FIG. 3) in order to form the deformation 132 in the signature 40. Deformer 126 may be any of the known designs. In the illustrated embodiment of the invention, the shaping device 126 has a shaping roller 140. The shaping roller 140 has an immovable steel carrier 142 with cylindrical band support segments 144. The metal carrier 142 also has cylindrical intermediate segments 146 with a relatively small diameter, which are arranged coaxially between the band support segments 144. The deforming roller 140 rotates about an axis which runs parallel to the axis of rotation of the impeller 74.

A cylindrical outer side surface of each band support segment 144 is in contact with one side of a band 82. The tape support segment 144 presses the opposite side of the tape 82 against the major portion of a side surface 54 of a signature 40 (Fig. 3). The surface speed of the belt support segment 144 and the transport speed of the belt 82 are the same so that there is no slippage between the belt support segment 144 and the belt 82.

The carrier roller 142 of the shaping device 126 is driven in a clock cycle relationship with a belt support roller 150 for the belts 84. The metal belt support roller 150 has cylindrical belt support segments 152 which are in contact with the belts 84. It should be understood that even if the forming roller 140 and the belt support roller 150 in FIG. 3 appear to be perpendicular to one another, they are actually offset vertically from one another, as shown in FIGS. 1 and 2. However, rollers 140 and 150 can be oriented vertically if desired.

The deforming roller 140 and the belt support roller 150 are rotated in a timing relationship with each other at one and the same surface speed by intermeshing gears 156 and 158. The gears 156 and 158 are attached to support bearing end portions 160 and 162 of the rollers 140 and 150 Support bearing end portions 160 and 162 are carried by an end wall 164 of the folder 10. The opposite end portions of the rollers 140 and 150 are rotatably supported by fixed pins 166 and 168 which are connected to a second side wall 170 of the folder 10.

A cylindrical embossing segment 174 for contact with the signature 40 between the belts 82 is protruding on the forming roller 140. The Cylindrical embossing segment 174 has a larger diameter than the support and intermediate segments 144 and 146 of the forming roller 140 and is arranged in a coaxial relationship therewith. Cylindrical embossing segment 174 has a radius that is greater than the radius of band support segment 144 and the thickness of band 82 together. Thus, the embossed segment 174 protrudes beyond the bands 82 in order to bend the signature elastically and to form the deformation 132 in the manner shown in FIG. 3.

In order that the embossing segment 174 can bend the signature 40 elastically to form a temporary deformation 132 in the signature, the outside of the embossing segment 174 consists of a flexible, compensating material which does not fold the signature 40. However, the embossing segment 174 exerts sufficient pressure on the signature 40 to bend it elastically and thus form the deformation 132. Since the signature 40 is deformed as long as it is in contact with the stamping segment 174, the deformation 132 remains in the signature 40 until it has moved out of the grip of the stamping segment.

The embossing segment 174 is arranged on a part of the carrier roller 142 with a relatively small diameter. Thus, the embossing segment 174 is formed on a part of the carrier roller 142 which has the same diameter and the same axial dimension as an intermediate segment 146 of the carrier roller 142.

The die embossing segment 174 has an annular, polymeric body or support ring 180 (FIG. 5) which is attached to the carrier roller 142 and rotates therewith. the support ring 180 has a cylindrical outer surface 182 with a radius which is approximately equal to the entire radius of a band support segment 144 (FIG. 3).

An elastic, flexible crown segment 186 (FIG. 5) is attached to and rotates with the support ring 180 and the deforming roller 140. The crown segment 186 has an outer radius greater than the radius of the belt support segment 144 and the thickness of the belt 82 when together is attached to the surface 182 of the support ring 180. There is sufficient distance between the bands 82 so that the embossing segment 174 can protrude from the bands to form the deformation 132 in the signature 40.

The crown segment 186 comes into contact with the successive signatures 40 to form the deformations 132. The cylindrical crown segment 186 is arranged in a coaxial relationship with the support ring 180. The crown segment 186 is flexible in the radial direction, so that a signature 40 can be deformed in an elastic manner without this deformation remaining in the signature 40.

The resilient crown segment 186 has a cylindrical inner layer 190 which shields and extends coaxially with the support ring 180. The cylindrical inner layer 190 consists of cloth or fabric. The inner layer 190 is attached to the support ring 180 by means of a cylindrical adhesive layer 192.

A cylindrical outer layer 196 (FIG. 5) runs coaxially with the cylindrical inner layer 190 and shields it. The cylindrical outer layer 196 is made of cloth or fabric which, at least to some extent, is compliant. The outer layer 196 is releasably connected to the inner layer 190 by a kind of hook-and-loop fastener 198, which is arranged between these two layers. The hook-and-loop fastener 198 can be released to the Separate the outer layer 196 from the inner layer 190 and replace the outer layer 196 when it is worn by contact with the signatures 40.

The hook-and-loop fastener 198 has a plurality of hooks 202 which are fixedly connected to the inner layer 190 and directed radially outwards. The fastener 198 also has a plurality of loops 204 which are fixedly connected to the outer layer 196 and directed radially inwards. The hooks 202 are releasably connected to the loops 204 to connect the inner and outer layers. The hooks 202 and loops 204 are made of a synthetic material, which causes them to adhere to each other when pressed together.
Although the hooks 202 have been shown projecting outward from the inner layer 190 and the loops 204 have been shown as projecting inward from the outer layer 196, their positions could also be reversed; that is, the hooks could protrude inward from the outer layer 196 and the loops could protrude outward from the inner layer 190 if desired. This type of hook and loop fastener 198 is a well known design and commercially available under the trademark "VELCRO". The hook-and-loop fastener 198 can be compressed, at least to some extent, so that the outer layer 196 yields or under the influence of forces transmitted to the outer layer 196 during the formation of the deformation 132 Inner layer 190 moved.

The crown segment 186 has a cylindrical outer surface 208 which comes into contact with the signature 40 (FIG. 5). This outside 208 is flexible to prevent the deformation 132 formed in the signature 40 from being permanent. In the illustrated embodiment of the invention, the cylindrical outer side 208 is formed by elastically bendable loops 210 which protrude radially outward from the outer layer 196. The loops 210 are of the same nature as the loops 204 of the fastener 198.

The cylindrical outside 208 of the crown segment 186 leaves a minimal mark in the signature 40. However, other types of crown segments can be used if desired, although the nature of the elastic outside 208 described herein is preferred. For example, the embossing segment 174 could be a chrome wheel, a round brush, a round plastic wheel, etc., if desired.

The outside 208 of the crown segment 186 (FIG. 5) moves at a higher surface speed than the signature 40. Therefore, when the deformation 132 is formed, there is slippage or shifted contact between the outside 208 of the crown segment 186 and the main part of a side surface 54 of a signature 40 (Figures 3 and 4). This slip causes a kind of yielding, brushing contact between the crown segment 186 (FIG. 5) on the embossing segment 174 and a signature 40 in order to bend it elastically without permanently deforming it. If desired, the outer surface 208 of the crown segment 186 could move at the same speed as the signature 40.

The nature of the crown segment 186 of the die embossing segment 174 allows the outer layer 196 to be easily separated from the inner layer 190 when the outer layer 196 is worn. The hook-and-loop fastener 198 can thus easily be released to remove the worn outer layer 196 from the inner layer 190. A new outer layer can then be easily reconnected to the inner layer 190 by the fastener 198 mentioned.

Crown segment 186 could also be different, if desired. Other known designs of a deforming device are also contemplated. For example, the deforming device could have a fixed part for elastically deforming the signatures.

Deforming device - second embodiment

3, a single embossing segment 174 forms a single corrugation 132 in a signature 40. However, it may be desirable to form a plurality of deformations in each signature 40 to further stiffen it. In the embodiment of the invention shown in FIG. 6, a plurality of embossed segments are provided for forming a plurality of deformations in each signature 40. Since this embodiment shown in FIG. 6 is essentially the same as that shown in FIGS. 1 to 5, the same reference numbers will be used used to identify like parts, with the additional letter "a" referring to the parts in Figure 6 to avoid confusion.

A shaping device 126a comprises a shaping roller 142a with a plurality of shaping segments 174a. The cylindrical embossing segments 174a project radially outward from cylindrical band support segments 144a further than the thickness of a radial cylindrical band support segment 144a and the thickness of a band 82a. Thus, the shaped embossing segments 174a protrude between the bands 82a which are spaced apart from one another and form a multiplicity of deformations in a signature which run at a distance from one another between their front and rear end parts. Although three stamping segments 174a are shown in FIG. 6, a greater or lesser number of stamping segments can be used if desired.

Each of the stamping segments 174a has the same nature as the stamping segment 174. Thus, each stamping segment 174a has a polymeric support ring, which is fastened to a metal carrier roller 142a. An elastic crown similar to crown 186 in FIG. 5 is connected to each of the support rings. Each of the crowns has an inner and outer layer, releasably connected to one another by hook-and-loop fasteners. The crowns have an outside formed by loops - similar to the loops in FIG. 5.

Conclusion

The present invention provides a new, improved signature transport device 14, in which a first transport means 64 includes a delivery station 88, at which signatures 40 are transferred to a second transport means 74. In order to increase the speed at which the signatures 40 can move between the transport means 64 and 74, one or more deformations 132 are formed in the signatures 40 in order to stiffen them.

Since it is desired to have the signatures 40 free from deformations 132 again after the transfer from the first transport means 64 to the second transport means 74, the deforming device 126 deforms the signatures 40 in an elastic manner and forms temporary deformations which disappear after the signatures have moved out of the deforming device. In order that the deformations 132 in the signatures 40 can be maintained during their movement at high speed between the transport means 64 and 74, the deformation device 126 is arranged at a distance from the second transport means 74 which is less than the distance between the front and rear End part 46 and 48 of a signature 40. Thus, during the movement one front signature part through the space between the two transport means 64 and 74 and during the initial contact of the signature 40 with the second transport means 74 a rear signature part in the handle of the deforming device 126.

The foregoing description of the preferred embodiments of the invention has referred to a known type of deforming device 126 in which a rotatable deforming roll 140 or 140a has been used to form one or more deformations in a signature. However, other types of deformers that do not permanently deform a signature could be used if desired. It is therefore contemplated that the deformations could be formed with one or more fixed guides that press against the signature. Another way to form deformations would be to use air blowers. If desired, opposed bands could be used on the opposite sides of the signatures to form the deformations. Therefore, the claims made by the present invention are not to be construed as being limited to any particular type of deforming device, except where required by the specific wording of a claim.

Claims (16)

1. Folding unit of a web-fed rotary printing press, which has a first transport means (64) for the successive transport of signatures (40), which cooperates with a second transport means (74) for transporting the signatures (40) received by the said first transport means (64), whereby the first means of transport (64) has a delivery part (88) through which the signatures (40) move in succession from said first means of transport (64) to said second means of transport (74), characterized by the following features:
a deformation device (126) for forming deformations (132) which run between the front and rear end parts (46 and 48) of a signature is attached to the delivery part (88) of the first transport means (64), said deformation device (126) is at a distance from said second transport means (74) which is less than the distance between the front and rear end parts (46 and 48) of a signature (40), so that it is possible that the respective front end part (46 ) a signature moves into a pocket (92) of the second transport means (74) while the rear end part (48) is still in contact with the deforming device 126). 2. Device according to claim 1,
characterized by
that the shaping device includes a roller (140) which has an area with a first diameter (146) and an area with a second diameter (144) which is larger than the first diameter, furthermore the second area (144) of the roller ( 140) has an embossing means (174) for the elastic deformation of a respective signature (40). 3. Device according to claim 1,
characterized by
that the deforming device (126) includes means (174) for elastically deforming a respective signature (40), and the deformation is retained as long as the signature (40) is in contact with the deforming device (126), and the deformation from the respective one Signature (40) disappears after it has moved out of the deforming device (126). 4. The device according to claim 1,
characterized by
that the first transport means (64) includes a plurality of bands (82, 84) which are in contact with the opposite sides (54, 52) of a signature (40), and a means for moving said bands to one another to move the signature (40) located therebetween, the deforming device (126) including a shape embossing means (174) for deforming a respective signature (40) while it is located between the said belts (82, 84) and is conveyed by them. 5. The device according to claim 4,
characterized by
that the deforming device (126) has a shaped embossing means (174) for exerting forces on the one side surface of a respective signature (40). 6. The device according to claim 4,
characterized by
that the plurality of bands include first and second spaced bands (82, 84), each band having a side surface for contacting the same side surface of a signature (40) and the means (126) for deforming a respective one Signature (40) includes embossing means (174) for contact with a side surface of a respective signature (40) in positions between which said first and second tapes (82, 84) are in contact with the side surface of the respective signature (40) . 7. The device according to claim 6,
characterized by
that the side faces of said first and second tapes (82, 84) and the side faces (54, 52) of the signatures (40) which come into contact with said first and second tapes (82, 84) successively, during the sequential Move transports through the former (126) at the same speed that the former (126) includes means for moving the die (174) at a speed greater than the speed of movement of the side surfaces of the signatures (40) the deforming device (126), wherein slippage occurs between the embossing means (174) and the side surfaces of the signatures when they come into contact with the embossing means (174) one after the other. 8. The device according to claim 1,
characterized by
that the deforming device (126) includes a base, a material layer (196), the outside of which comes into contact with the respective signatures 40, and a hook-and-loop fastening means (198) for releasably connecting said material layer (196) to the said base, said hook and loop fastener (198) including a plurality of loops (204) and a plurality of hooks (202) connectable to said loops (204) for releasably connecting the material layer (196) to the Base. 9. A device according to claim 8,
characterized by
that said outside of said material layer is formed from a further plurality of loops of the same nature as the plurality of loops (204) connectable to the plurality of hooks (202). 10. Folding unit of a web-fed rotary printing press, characterized by the following features:
a roller is provided which is surrounded by an inner material layer, means for connecting the inner material layer to said roller, a circumferential outer material layer extending around said inner material layer, a surface means (210) connected to said outer material layer sequential contact with the major portion of a side surface of each of the signatures, and a hook-and-loop fastener (198) for releasably connecting said inner and outer layers of material (190, 196) together, said hook-and-loop Fastening means (198) has a plurality of loops (204) located between said inner and outer layers of material and connected to a first one of said inner and outer layers of material, and a plurality of hooks located between said inner and outer outer layer of material and with a second of said inner and outer material layers are connected, and said plurality of hooks are connectable to said plurality of loops to releasably connect said inner and outer material layers. 11. A device according to claim 10,
characterized by
that the surface means (210) from a plurality of loops is of the same nature as the plurality of loops of said hook and loop fastener (198). 12. A device according to claim 10,
characterized by
in that a first means of transport (64) for sequentially conveying signatures and a second means of transport (74) for conveying the signatures obtained from said first means of transport (64) are provided, said first means of transport (64) including a delivery section (88) , through which the signatures move successively from said first transport means (64) to said second transport means (74), said roller (140) is located on the delivery part (88) of said first transport means (64), said molding device (174) sequentially contacts side surfaces of the signatures to form deformations extending between the front and rear end portions of the signatures, said roller (140) is spaced from said second transport means (74) which is less than the distance between the front and rear end portions of the signatures to adjusted, that the front end portion of a respective signature moves in said second transport means (74), while it is still connected to said molding die means (174) is in contact. 13. A device according to claim 10,
characterized by
that the roller has a metallic support having a cylindrical outer surface (208) and an annular body (186) made of polymeric material which shields the cylindrical outer surface of said support, and said first layer of material is fixedly attached to said annular body. 14. Device for the transport of signatures, the folded edge part of which is located opposite the open edge part thereof, and said device comprises the following features:
a first transport means (64) for the sequential transport of the signatures (40), the front end part (46) of the folded edge part (42) and the rear end part (48) of the open edge part (44), a second transport means (74) for Conveying the signatures received by said first means of transport (64), said delivery means having a delivery station (88) through which the signatures (40) are sequential from the first means of transport (64) to the second means of transport (74) move, and a deforming device (126), which is located at the delivery station (88) of said first transport means (64), for embossing deformations next to the open edge part of the signatures, these deformations (132) between the front and rear end parts ( 46, 48), run parallel to the folded edge part (42) of the signatures, and said shaping device (126) is at a distance from said means of transport (7 4), which is smaller than the distance between the front and rear end parts of the signatures, so that the front end part of a respective signature can move towards the second transport means (74) while it is still in contact with the said deforming device, and can be counteracted by the deformation in the signature of the otherwise usual tendency of the front signature end part (46) to bend when it moves from said first means of transport to said second means of transport. 15. The apparatus according to claim 14,
characterized by
that said deforming means (126) includes a base, a layer of material having a cylindrical outside (196) for contact with a respective signature, and a cylindrical body of a hook and loop fastener (198) which is radial with respect to said exterior (196) is inwardly directed to releasably connect said layer of material to said base, said hook and loop fastener (198) having a plurality of loops (204) and a plurality of loops engaging the loops Hook (202) includes to releasably connect the layer of material to the base. 16. The apparatus according to claim 14,
characterized by
that said deforming means (126) comprises a roller (142), a circular inner layer (190) of material extending around said roller, means for connecting said inner layer (190) of said material to said roller (142), a circular outer material layer (196) extending around said inner material layer, a surface means (208) connected to said outer material layer for sequential contact with the main part of a side surface of the respective signatures, and a hook-and-loop fastening means (198), which bounds said circular layer of material for releasably connecting said inner and outer layers of material to each other, said hook and loop fastener (198) comprising a plurality of loops disposed all around between said inner and outer layers of material which are connected to a first of the material layers mentioned ver bound and a plurality of hooks disposed all around between said inner and outer layers of material connected to a second one of said layers of material and said loops and hooks can be pressed into each other to form said inner layer of material (190) and outer layer of material (196 ) to connect with each other.

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