RU2779096C2 - Clamping roller and method for pressing tire layer on reel for tire assembly - Google Patents

Abstract

FIELD: tire production.

SUBSTANCE: invention relates to a clamping roller and a method for pressing a tire layer on a reel for tire assembly in the direction of pressing. The clamping roller consists of a shaft and a set of discs. Each disc consists of inner and outer part. Each inner part has a recess for accommodation of the shaft, while the recess is more than the shaft in the direction of pressing for providing the movement of the disc relatively to the specified shaft in the direction of pressing. The clamping roller includes one or several drives for each disc for separate movement of the disc, wherein one drive is intended for the movement of the corresponding disc relatively to the shaft in the direction of pressing, and the same or another drive is intended for the movement of the corresponding disc relatively to the shaft in the direction of retraction opposite to the direction of pressing.

EFFECT: group of inventions provides for an increase in control of pressure applied by discs to a tire layer on a reel for tire assembly.

31 cl, 11 dwg

Description

BACKGROUND OF THE INVENTION

The invention relates to a pressure roller and a method for pressing a tire ply on a tire assembly drum.

CN 203141856 U describes an apparatus for making tires with a pinch roller, in which the pinch roller is provided with a non-rotating shaft and a plurality of uniformly shaped radial discs which are arranged on said shaft. Each disc consists of an inner and outer part, and on the inner part there is a recess in which the shaft is located. In one direction, the recess has a length greater than the corresponding size of the shaft in the specified direction, while the length of the recess in the specified direction allows you to move the disk relative to the shaft, and other disks in the specified direction. Each disc is moved individually by pistons. The piston rods of said pistons extend and rest against the bottom walls of the recesses or slots on these bottom walls. As a result of the abutment, the corresponding discs are pushed down in relation to the shaft and exert pressure on the tire plies placed on the drum.

The pressure roller is mounted in a movable device which moves relative to the drum between an upper position in which the pressure roller is not adjacent to the tire plies and a stop position in which the pressure roller is adjacent to the tire plies deposited on the drum.

WO 2016/184,446 A1 describes a pressing device with a plurality of discs located on a shaft and a plurality of pneumatic actuators that extend from the top of the shaft and are adjacent to the top wall of the recess. Thus, in contrast to the pressure roller described in CN 203141856 U, the pressure device WO 2016/184 446 A1 ensures that the disks are lifted up, and when the power drives are retracted, the disks can return to the lower position under their own weight.

BRIEF DESCRIPTION OF THE INVENTION

A disadvantage of the known pressure roller and the known pressure device is that the pressure force applied by the discs to the tire ply on the tire building drum can only be actively controlled in one direction. However, in some cases it is necessary to actively and individually control the pressure force of the discs on the tire ply in both directions, i.e. individually retract one or more discs so that they are no longer in contact with the tire ply on the tire building drum, or press one or more discs harder against the tire ply on the tire building drum. In the known pinch roller and pinch device, the actuators are not connected to the insides of the discs and can therefore move the discs only by abutment. In other words, the actuators cannot actively pull the disks in the opposite direction. Thus, the discs can only be steered in one direction, while in the opposite direction the movement of the discs depends on the position of the movable device, and hence the pressure roller as a whole, relative to the tire ply and/or tire building drum. In particular, in the pressure roller CN 203141856 U, the discs return only when an external force is applied, i.e. as a result of pressing the pressure roller against the tire ply. In WO 2016/184446 A1, the discs return under their own weight when the pressing device is no longer in contact with the tire ply and/or the tire building drum.

It is an object of the present invention to provide such a pinch roller and method for pressing a tire ply on a tire building drum that enhances the control of the pressure exerted by the disks on the tire ply on the tire building drum.

According to a first aspect, the invention is a pinch roller for pressing a tire ply on a tire building drum in a pinch direction, wherein the pinch roller is comprised of a shaft defining an axial direction of rotation and a plurality of discs axially stacked on said shaft, where each disk consists of an inner part that does not rotate on the shaft and an outer part that rotates relative to the inner part around the axis of the roller, where each inner part has a recess for receiving a shaft rotating in the axial direction through the corresponding disk, and the size of the recess is larger than the shaft , rotating in the direction of pressing to ensure the movement of the corresponding disk relative to the specified shaft in the direction of pressing, where the pressure roller includes one or more actuators for each disk for individual movement of the corresponding disk in relation to other disks, where one of the actuators provides a change displacement of the respective disk with respect to the shaft in the direction of pressing and where the same or another actuator provides movement of the corresponding disk with respect to the shaft in the direction of retraction, opposite to the direction of pressing, where at least one or more actuators are provided with a connecting element for connecting at least at least one power drive to the inside of the corresponding disk in the pressing direction.

A pinch roller capable of controlling the position of the discs not only in the pressing direction but also in the retracting direction can more precisely control the pressure exerted by the discs on the tire ply on the tire building drum. In particular, for some disks the pressure can be reduced while for other disks it can be increased. Alternatively, one or more discs may even be raised in the retraction direction to a position where they are separated from the tire ply and/or tire building drum. The connection allows the actuator to apply both pushing and pulling force to the disc. Thus, the pressure force exerted by the discs on the tire ply on the tire building drum can be adjusted separately in both directions.

In the first embodiment of the invention, one or more actuators form a bi-directional actuator for alternately moving the respective disk relative to the shaft in the pressing direction and in the retracting direction. Thus, the same drive can be used to move the corresponding disc in both directions.

Preferably, the bi-directional actuator is an air cylinder that connects to a valve block for alternate connection to a pneumatic source and a vacuum source. The resulting pneumatic cylinder can act in both directions depending on the source.

More preferably, the shaft consists of an air passage for connecting a suitable bi-directional actuator to a valve block for alternately connecting to a pneumatic source and a vacuum source. Thus, one air passage can be used to alternately connect a bi-directional actuator to a pneumatic source and a vacuum source. This is especially advantageous since the dimensions of the shaft often limit the number of air channels that can be built into it. The valve block can be conveniently positioned outside the shaft.

In a second exemplary embodiment of the invention, one or more actuators include a first actuator for moving a respective disc relative to the shaft in the pressing direction and a second actuator for moving the respective disc relative to the shaft in the retraction direction. Thus, movement in both directions can be controlled by separate drives. This can be useful, for example, in cases where one drive is not able to provide the forces required for pressing or retracting.

In one particular embodiment, the first and second drives are located in a recess of the respective disc on one side of the shaft in the pressing direction or in the retraction direction, with the first drive pushing the respective disc away from the shaft and the second drive pulling the respective disc towards the shaft. By having both actuators on the same side of the shaft, the shaft size can be maximized in the opposite direction.

In this example, it is preferable that the first actuator is a pneumatic cylinder connected to a pneumatic source, and the second actuator is a pneumatic cylinder connected to a vacuum source. When the actuators are connected to different sources, they can move the corresponding disk in opposite directions despite being located on the same side of the shaft.

In this example, it is also preferred that the shaft includes a compressed air duct for connecting the first drive to the pneumatic source and a vacuum air duct for connecting the second drive to the vacuum source. Thus, due to separate air ducts connected to individual drives, there is no need to provide valve complexes for controlling the flow of compressed air or vacuum.

In an alternative third embodiment of the invention, also including first and second drives, the first and second drives are located in the recess of the respective disc on opposite sides of the shaft in the pressing direction and in the retraction direction, respectively, where the first and second drives push the respective disc away from the shaft or pull the respective disc disc towards the shaft. Thus, both drives can work the same way. By alternating their operation, the corresponding disk can move alternately in the pressing direction and in the retracting direction.

In this alternative embodiment of the invention, it is preferred that the first and second actuators are pneumatic cylinders connected to a pneumatic or vacuum source. Therefore, both pneumatic cylinders can be connected to a pneumatic or vacuum source. The valve can be used to alternate the flow of compressed air or vacuum between the first and second actuators.

In this alternative embodiment, the shaft preferably includes a first air passage for connecting the first actuator to a pneumatic or vacuum source and a second air passage for connecting a second actuator to the same pneumatic or vacuum supply. With separate air passages connected to the same source, any valves can be conveniently placed outside the shaft.

In the fourth embodiment of the invention, one or more drives form an automatic return drive, which is provided with a drive element for moving the corresponding disk in the pressing or retracting direction, and a biasing element for moving the drive element to return it in the pressing or retracting direction. Thus, an automatic return actuator can actively control the movement of the corresponding disk in one of the directions, and in the absence of a driving force, passively return in the other direction. Thus, the structure of an automatic return actuator can be relatively simple.

In a fifth alternative embodiment of the invention, one or more actuators form a bidirectional actuator, which is a mechanical, electrical or electromechanical bidirectional actuator. The movement of the respective disks can, for example, be controlled by several electrically driven linear actuators, as an alternative to the previously described air cylinders.

In a more general embodiment of the invention, at least one or more actuators provide such engagement or attachment to the interior of the respective disc that prevents any drive from disengaging or detaching from the interior of the respective disc in the axial direction. With prior pressure rollers, the piston rods are pressed against the discs only from the inside of the recess. Therefore, the discs can move in the axial direction with respect to the piston rods. Considering that the number of discs in the pressure roller can be quite large, for example more than one hundred, the total tolerance in the axial direction may exceed the width of an individual disc, with the result that said disc, especially when it is located in the center of the pressure roller in the axial direction, may slip, out of alignment with the corresponding piston rod. This may cause unexpected operation or even malfunction of the normal pinch roller. According to the invention, sliding in the axial direction in the pinch roller can be prevented, for example, by limiting the movement in the axial direction or by attaching the drive to the respective disc so that each disc remains in line with the respective drive.

In another embodiment of the invention, the connecting element is provided in the form of a detachable sleeve to allow free attachment of at least one of said drives to the inside of the corresponding disk in the pressing direction. The detachable sleeve is also useful when mounting and/or dismounting the pinch roller.

Preferably, the interior of the respective disk is provided with a mounting element for mounting the connecting element. Desirably, the mounting element is a spline and the connecting element is positioned to engage the spline. The presence of a mounting element on the corresponding disc immediately indicates the location of the drive during mounting. Thanks to the presence of a slotted mounting element, the connecting element can simply be inserted into the slot.

In one embodiment, the mounting members of the immediately adjacent disks are offset relative to each other in an offset direction perpendicular to the pressing direction and the axial direction. By offsetting the mounting elements, the drives can be positioned in positions with the same offset, so that the drives are closer together in the axial direction. The offset may further ensure that said splines are closed or blocked in the axial direction by the interiors of the immediately adjacent disks, thus preventing the connecting element from being pushed out of said spline in the axial direction.

In a subsequent design, each disc has a bisector running parallel to the pressing direction, while the mounting elements of the immediately adjacent discs are located on opposite sides and at the same distance from the bisector. Thus, the mounting elements can be arranged with mirror symmetry.

The embodiment described above is even more advantageous if the disks in close proximity to each other are identical, since then one of the immediately adjacent disks can be mirrored on a bisector with respect to the other immediately adjacent disk. So the disks can be identical. During assembly of the pinch roller, the discs are simply mirrored to obtain an offset mounting position.

In another preferred embodiment, the pressure roller consists of two or more zones, where each zone consists of two or more disks from the total number of disks, where the drives for moving the disks within one of the zones ensure the simultaneous movement of all disks within this zone in the direction of pressing or in the pull direction. Thus, it is possible to reduce the complexity of disk management, in particular when a large number of disks are used.

According to a second aspect, the invention provides a method for pressing a ply of a tire on a tire building drum using a pinch roller according to any of the above embodiments, the method including the steps of:

- the use of one or more drives to move the corresponding disk relative to the shaft in the direction of pressing; and

- the use of the same or another drive, or several drives to move the corresponding disk in relation to the shaft in the direction of retraction.

This method is associated with the practical application of the pressure roller in accordance with the first aspect of the invention. Thus, this method and its embodiments have the same technical advantages as the pinch roller and its respective implementations. Therefore, these benefits will not be repeated further.

In the first exemplary embodiment of the invention, one or more drives form a bi-directional drive, which alternately moves the corresponding disk with respect to the shaft in the pressing direction and in the retracting direction.

In the second and third embodiments of the invention, one or more drives include a first and a second drive, wherein the first drive moves the corresponding disk relative to the shaft in the pressing direction, and the second drive moves the corresponding disk relative to the shaft in the retraction direction.

In a fourth embodiment of the invention, one or more actuators includes an automatic return actuator that consists of a drive element and a bias element, the method including the step of energizing the actuator to move the respective disk in one of the pressing or retraction directions and allowing the bias element return the disk in the other direction after the drive element has stopped.

In another, more general embodiment of the invention, the pinch roller consists of two or more zones, where each zone consists of two or more disks from a plurality of disks, where drives for moving disks within one of the zones move all disks within the specified zone simultaneously in direction of pressing or in the direction of retraction.

This method can be advantageously used, for example, when the width of the tire building drum changes or when the tire building drum is replaced by an alternative drum with a different width. In this case, the method includes the step of moving the disks in one or more zones that are outside or at least partially outside the width of the tire building drum in the retraction direction from the tire building drum and simultaneously moving the disks in one or more zones that are are within the width of the tire building drum, in the pressing direction towards the tire building drum. Therefore, unnecessary contact, collision and/or wear between the retracted discs and the tire ply and/or tire building drum can be prevented.

Additionally or alternatively, the two or more zones may include a central zone and side zones on either side of the central zone in the axial direction, the method including the step of moving the disks in the side zones in the retraction direction while moving the disks in the central zone in the direction of pressing. This can be useful in cases where the tire ply is smaller than the width of the tire building drum or where the centering force should only be applied to the center portion of the tire ply.

In a subsequent execution, the method includes the step of simultaneously moving the entire plurality of discs in the retraction direction. Preferably, the shaft remains stationary during said simultaneous movement. Therefore, the presence of an external holder to lift the pinch roller from the tire building drum, as with a conventional pinch roller, is no longer required.

The previous embodiment of the invention may also be advantageous if the entire plurality of discs simultaneously move in the retraction direction when the leading end, rear end, butt joint, or other known or detected unevenness of the tire ply surface passes under said plurality of discs.

The various aspects and characteristics described and shown in the specification may be applied separately, if possible. These individual aspects, in particular the aspects and characteristics described in the appended dependent claims, may be the subject of divisional patent applications.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be explained on the basis of an embodiment of the invention shown in the accompanying schematic drawings, in which:

in fig. 1 is a front view of a pressure roller with a plurality of discs according to the first embodiment of the invention, with the plurality of discs shown in cross section;

in fig. 2 is a cross-sectional view of a pinch roller according to lines II-II in figure 1, together with a means for holding said pinch roller, a tire ply feed unit and a drum for receiving a ply from the feed unit;

figure 3 shows a cross section of the pressure roller in accordance with the line III-III in figure 1;

figures 4, 5, 6 and 7 show cross sections of alternative pressure rollers in accordance with the second, third, fourth and fifth (unclaimed) embodiment of the invention, respectively;

Figures 8, 9 and 10 show a pinch roller according to Figure 1, where a plurality of disks are divided into a plurality of zones and where the disks are controlled in accordance with said plurality of zones; and

figure 11 shows a perspective view of an alternative connecting element for connecting the discs to the shaft.

DETAILED DESCRIPTION OF THE INVENTION

Figures 1 to 3 show a pressure roller 1 according to a first embodiment of the invention for pressing a tire ply (not shown) on a tire building drum 9 in the pressing direction P as shown in Figure 3. The pressure roller 1 is supported relative to the tire building drum 9 by a holder 7. The tire ply can be fed to the tire building drum 9 from a service device, i. e. from assembly line 8.

The pinch roller 1 consists of a shaft 2 projecting in the axial direction A. The shaft 2 determines the axis of rotation S of the pinch roller 1. As shown in figure 1, the shaft 2 has a substantially rectangular or quadrangular cross section. The shaft 2 holds or consists of a plurality of air passages 21, 22 for operating the pressure roller 1 with pneumatic control. The drawings show only two air channels 21, 22. In practice, the shaft 2 may have more air channels, for example, more than ten or more than twenty, in order to increase the flexibility of controlling the pressure roller 1. The pressure roller 1 consists of a plurality of disks 3 located on one line or mated in the axial direction A on the specified shaft 2. As can be seen in figure 1, each disk 3 consists of an inner part 31, which rests on the specified shaft 2, and an outer part 32, which protrudes around the inner part 31.

Preferably, the inner part 31 rests firmly on the shaft 2. The inner part 31 has a circular contour. In this embodiment of the invention, the inner part 31 has a recess 33 for receiving the shaft 2 in the axial direction A through the corresponding disk 3. The recess 33 has a substantially rectangular or quadrangular cross-section which, in the direction transverse to the pressing direction P, has a width substantially corresponding to the width of the shaft 2 in the same transverse direction. Thus, the shaft 2 can be received between the transverse sides of the recess 33 and fixed. In the pressing direction P, the recess 33 is larger than the shaft 2, so that the corresponding disk 3 can move in the pressing direction P and in the retracting direction R opposite to the said pressing direction P. In particular, the corresponding disk 3 can move along the transverse sides of the shaft 2 in the direction pressing P and in the retracting direction R.

While the inner part 31 of the respective disk 3 rests fixedly on the shaft 2 as described above, the outer part 32 rotates on the inner part 31 about the axis of rotation S. The outer part 32 is in the form of a ring located concentrically around the circular inner part 31. Preferably so that the outer part 32 is connected to the inner part 31 with the possibility of free rotation through a plurality of bearings, preferably known as ball bearings. Due to the mobility of the discs 3 in the pressing direction P and the retracting direction R with respect to the shaft 2, it will become clear that the rotation axis S is not always exactly at the center of the aforementioned rotation. However, in each position of the disks 3, the rotation axis S is within the central region defined by the inner part 31, whereby the rotation of the outer parts 32 can be considered as rotation about the rotation axis S in said central region.

As best seen in figure 1, the pinch roller 1 consists of a plurality of drives 4, one for each disc 3. Each drive 4 provides a separate movement of the respective disc 3 in relation to the other discs 3. In this first embodiment of the invention, each drive 4 is a bi-directional actuator 4 for alternately moving the respective disk 3 relative to the shaft 2 in the pressing direction P and in the retracting direction R. In the following, separate drives will be presented for moving the disks in the pressing direction P and in the retracting direction R, respectively.

As shown in FIG. 1, the actuators 4, according to the first embodiment of the invention, are formed in the form of pneumatic or air cylinders. Each air cylinder consists of a chamber 41, a piston 42 which, under the action of a pressure difference, moves through the chamber 41, and a piston rod 43 which protrudes from the chamber 41 to transmit force to the corresponding disk 3. As previously stated, in this first embodiment of the invention actuators 4 are bi-directional. Therefore, air cylinders are double-acting cylinders which are alternately driven by compressed air and (partial) vacuum.

At the end of the piston rod 43, a connecting element 44 is provided for connecting or mechanically connecting the piston rod 43 to the inner part 31 of the corresponding disk 3. This allows the piston rod 43 to hook on the inner part 31 of the corresponding disk 3 and apply a tension force to the corresponding disk 3 in the direction of retraction R The connection between the piston rod 43 and the inner part 31 further ensures a fixed or substantially fixed position of the corresponding disk 3 in the axial direction A, i.e. the actuator 4 does not lose its engagement with the inner part 31 of the corresponding disk 3 in axial direction A. It will be obvious to the modern specialist that instead of connecting the piston rod 43 to the inner part 31 of the corresponding disk 3 by means of a coupling, the piston rod 43 can be connected to the inner part 31 corresponding disk 3 in another way, such as magnetically, with screws, bolts, or more firmly by gluing or welding.

In this embodiment of the invention, the connecting element 44 is freely connected to the inner part 31 of the corresponding disk 3. This is especially convenient when assembling the pressure roller 1, when each disk 3 is individually mounted on the shaft 3 in the axial direction A and connected to the corresponding drive 4, as well as when dismantling it. To this end, the inner part 31 of the corresponding disk 3 is provided with a mounting element 34 for mounting the connecting element 44. Preferably, the mounting element is a slot 34, in which the connecting element is a turn-and-click mechanism 44, which engages the slot 34 by screwing. For example, the snap-and-turn connector 44 may be a T-shaped end of the piston rod 43 designed to engage with the spline 34.

As can be seen in figure 3, the mounting elements 34 of two directly adjoining disks 3 are offset relative to each other in the direction of displacement T transversely or perpendicular to the pressing direction P and the axial direction A. The mounting element 34 of the disk 3, located at the rear of figure 3, is shown in dotted lines. The advantage of offset mounting elements 34 is that the actuators 4 can be displaced in the same direction of offset T to fit the actuators 4 closer to the shaft 2. The power actuator 4 of the disk 3, located at the rear of figure 3, is shown in phantom. Due to the displacement of the actuators 4, the width of the chambers 41 and pistons 42 of the actuators 4 may exceed the width of the disks 3 in axial direction A, provided that the actuators 4 are adjacent to each other on the shaft 2. Using a wider chamber 41 and piston 42 may result in more force to the piston 42.

Preferably, the mounting elements 44 of two directly adjoining disks 3 are offset relative to each other by the same distance from the center of the disk 3 in the offset direction T. In other words, if each disk 3 has a bisector B that divides the circular shape of the inner part 31 into two equal halves , then the mounting elements 34 of the two directly adjoining disks 3 are located on opposite sides and at the same distance from the bisector B. This means that the interiors 31 of the two adjoining disks 3 are identical or almost identical. When assembling the pressure roller 1, one of the disks 3 is simply mirrored on the bisector B with respect to the other of the two directly adjacent disks 3 to obtain a mirror-symmetrical configuration. Thus, only one type of disk 3 is required for assembly.

Figure 11 shows an alternate disc 503 with an alternate combination of spline 534 and connector 544. Slot 534 extends fully from side to side through interior 531 in axial direction A so that connector 544 at the end of piston rod 543 can fit into slot 534 at axial direction A. Thus, during assembly, the alternative disk 503 can simply be pushed onto the shaft 2 in the axial direction A. In order to limit the movement of the alternative disk 503 relative to the connecting element 544, the positions of the spline 534 are again shifted in the direction of displacement T in the same way as the mounting elements 44 in figure 3. Due to the offset in the offset direction T, the inner parts 531 of the directly adjoining disks 3 block or cover the slot 534 in the axial direction A to prevent the connecting element 544 from falling out of the hitch with the inner part 531 of the corresponding disk 3 in the axial direction A.

As indicated, the shaft 2 consists of a plurality of air channels 21, 22, as shown in figure 1. In the first embodiment of the invention, the chambers 41 of the power drives 4 are connected by air communication with one of the air channels 21, 22 inside the shaft 2 for alternately receiving compressed air or (partial) vacuum. In particular, the air channels 21, 22 are separately connected to an external valve block (not shown in the figure) to alternately connect the chambers 41 of the actuators 4 to a pneumatic source and a vacuum source.

As shown in figure 1, the pinch roller 1 consists of two or more zones Z1-Z5. This example shows five zones. In practice, more zones may be provided, for example more than ten or twenty. Each zone Z1-Z5 consists of two or more disks 3 from a plurality of disks 3. The pressure roller 1 is configured in such a way that the drives 4 associated with the disks 3 within one of the zones Z1-Z5 simultaneously move all the disks 3 within the specified zone Z1-Z5 in the pressing direction P or in the retracting direction R. In particular, the shaft 2 consists of an air channel 21, 22 for each zone Z1-Z5, and all drives 4 and disks 3 within one zone Z1-Z5 are connected by air to by the same air channel 21, 22. When connecting several drives 4 to one air channel 21, 22, fewer air channels 21, 22 are required, which facilitates the placement of these air channels 21, 22 within the cross section of the shaft 2.

The control of the pressure roller 1 in zones Z1-Z5 can be particularly useful in one or more situations, as shown schematically in figures 8, 9 and 10.

Figure 8 shows the situation in which the width W of the tire building drum 9 is replaced by an alternative tire building drum 9 (not shown in the figure) with a different width W. Thus, the pressure roller 1 according to the invention makes it possible to move the discs 3 in one or several zones Z1, Z5, which are completely or partially outside the width W of the tire building drum 9, in the direction of retraction R from the tire building drum 9 and simultaneously move the disks 3 in one or more zones Z2-Z4 that are within the width W of the tire building drum 9, in the retracting direction P towards the tire building drum 9. Thus, the disks 3 in the zones Z1, Z5 located outside the width W can be actively moved away from the tire building drum 9 to avoid collisions and/or unnecessary wear.

Figure 9 shows a situation in which two or more zones Z1-Z5 include a central zone Z3 and side zones Z1-Z2, Z4-Z5 on both sides of the central zone Z3 in the axial direction A. The discs 3 in the side zones Z1-Z2 , Z4 to Z5 can be moved in the retracting direction R, and the discs 3 in the central region Z3 in the pressing direction P. Thus, it is possible to more accurately press a tire ply smaller than the actual width W of the tire building drum 9, preventing unnecessary wear of the discs. 3 outside the central zone Z3 on the surface of the tire building drum 9. The same central zone Z3 can also be used to press only the central portion of the tire ply to impart a centering force to said tire ply.

Figure 10 shows the situation in which all discs 3 of the plurality of discs 3 simultaneously move in the retracting direction R so that the entire plurality of discs 3 rises to a height H. This can be especially useful when it is necessary to lift the discs 3 from the surface of the assembly drum. tires 9, for example, for maintenance or between cycles. In a conventional pinch roller, this would require lifting the entire pinch roller 1, i.e. raise the shaft 2. In the present invention, the shaft 2 can actually remain stationary during the lifting of the disks 3, and the same effect is achieved. Simultaneous movement of all disks 3 in the direction of retraction 3 can also be used to temporarily lift the disks 3 when the front end, rear end, butt joint or other known or detected surface unevenness of the tire ply is about to pass or pass under the said plurality of disks 3 .

It will be clear to the skilled person that if the shaft 2 is large enough to accommodate separate air passages for each individual disc 3, there will be no zones Z1-Z5 and each disc 3 can be controlled individually. This can greatly increase the flexibility of the pressure roller 1, in particular in the situation described above. For example, the positions of the discs 3 can be adjusted individually and closely follow the contour of the tire ply on the drum 9. However, given that a typical pinch roller 1 contains one hundred to two hundred discs 3, it can be understood that both the configuration of the shaft 2 and the control of the pinch roller 1 will also be much more complex. In practice, you can try to find a balance between the flexibility and complexity of the pressure roller 1.

It should be understood that the above description illustrates the operation of the preferred embodiments of the invention, and is not intended to limit the scope of the invention. Based on the above description, a person skilled in the art will obviously be able to see many other options that have not yet been included in the scope of the present invention.

For example, figure 4 shows an alternative pressure roller 101 in accordance with the second embodiment of the invention. This alternative pressure roller 101 includes, for each disc 3, a first drive 104 for moving the respective disc 3 relative to the shaft 102 in the pressing direction P and a second drive 105 for moving the respective disc 3 relative to the shaft 102 in the retraction direction R. In particular, the first drive 104 and the second the drive 105 is located in the recesses 33 of the respective disc 3 on the same side of the shaft 102 in the pressing direction P. Therefore, the first drive 104 pushes the respective disc 3 away from the shaft 102 and the second drive 105 pulls the respective disc 3 in the direction of the shaft 102. one skilled in the art will appreciate that the actuators 104, 105 may be located on the same side of the shaft 102 in the retraction direction R.

In this embodiment, the first actuator 104 and the second actuator 105 are pneumatic or air cylinders. The first drive 104 is the same or substantially the same as the drive 4 in the first embodiment of the invention. The second actuator 105, like the first actuator 104, has a chamber 151, a piston 152, a piston rod 153 and a connecting element 154. The inner part 31 of the disk 3 is provided with an auxiliary mounting element 135 in addition to the mounting element 34 of the first embodiment for mounting the connecting element 154 of the second drive 105.

In contrast to the previously discussed first embodiment of the invention, the air cylinders in the second embodiment may be single acting cylinders. In particular, the first actuator 104 is an air cylinder connected to a pneumatic source, and the second actuator 105 is an air cylinder connected to a vacuum source. To do this, the shaft 102 includes a pneumatic channel 121 to connect the first drive 104 to a pneumatic source and a vacuum channel 122 to connect the second drive 105 to the vacuum source.

Figure 5 shows another alternative pinch roller 201 according to the third embodiment of the invention. This pinch roller 201 differs from the pinch roller 101 in the second embodiment in that its first drive 204 and second drive 205 are located in the recess 33 of the respective disc 3 on opposite sides of the shaft 202 in the pressing direction P and in the retracting direction R, respectively. Therefore, both the first drive 204 and the second drive 205 push the respective disc 3 away from the shaft 202 or pull the respective disc 3 towards the shaft 202.

In this exemplary embodiment of the invention, the first actuator 204 and the second actuator 205 are pneumatic or air cylinders. The first drive 204 is the same or substantially the same as the drive 4 in the first embodiment of the invention. The second actuator 205, like the first actuator 204, has a chamber 251, a piston 252, a piston rod 253 and a connecting element 254. The inner part 31 of the disk 3 has an auxiliary mounting element 235 in addition to the mounting element 35 in the first embodiment for mounting the connecting element 254 the second drive 205 towards the recess 33 opposite the first drive 204.

As in the previous embodiment, the air cylinders may be single-acting cylinders that are connected to either a pneumatic source or a vacuum source. In this embodiment, pinch roller 201 has a shaft 202 that includes a first air passage 221 for connecting a first actuator 204 to a pneumatic or vacuum source and a second air passage 222 for connecting a second actuator 205 to the same pneumatic or vacuum supply. vacuum source. A valve block (not shown in the figures) may be provided on the channels 221, 222 or on the source to alternate the air channels 221, 222 to cause the respective disc 3 to move in the pressing direction P or in the retracting direction R.

Figure 6 shows another alternative pressure roller 301 in accordance with the fourth embodiment of the invention. This pressure roller 301 differs from the previously discussed pressure rollers 1, 101, 201 in that it is equipped with an automatic return actuator 304. This automatic return actuator 304 differs somewhat from the bidirectional actuator 4 of the first embodiment, since it is actively driven only in one direction. To do this, it is provided with a drive element, for example a chamber 41 and a piston 42, which together form an air cylinder, for driving the automatic return actuator 304 in the pressing direction P and a pressing element 306 for the passive return of the automatic return actuator 304 in the retraction direction R. Alternatively, the pusher member 306 biases the auto-return actuator 304 in the pressing direction P, and the drive member 41, 42 is designed to move the auto-return actuator 304 in the retract direction R. The pusher member 306 may be a spring that, depending on required direction of displacement is compressed or stretched to its natural length. If the automatic return actuator 304 is a single acting pneumatic or air cylinder, then a single air passage 321 is provided on the shaft 302 to connect the chamber 41 of said air cylinder to a pneumatic or vacuum source.

The figure 7 shows another alternative pressure roller 401 in accordance with the fifth implementation of the invention, not included in the formula. This pinch roller 401 differs from the previously discussed pinch rollers 1, 101, 201, 301 in that it is equipped with an electromechanical bi-directional drive 404. In particular, said drive 404 includes a linear drive 441, such as a spindle drive, which engages with a linear guide. 442 or is located along it, and this guide protrudes into the recess 33 in the pressing direction P. Said linear actuator 441 can be connected to the electric actuator by means of a power supply connected to said linear actuator 441 through the shaft 402.

LIST OF REFERENCE ITEMS

1 pinch roller

2 shaft

21 first air channel

22 second air channel

3 disk

31 interiors

32 outer part

33 notch

34 mounting element

4 bidirectional drive

41 cameras

42 piston

43 piston rod

44 connector

7 holder

8 conveyor

9 tire building drum

101 alternative pressure roller

102 shaft

121 pneumatic channels

123 vacuum channel

104 first drive

105 second drive

151 cameras

152 piston

153 piston rod

154 connector

135 auxiliary mounting element

201 another alternative pinch roller

202 shaft

221 first air channel

222 second air channel

204 first drive

205 second drive

251 cameras

252 piston

253 piston rod

254 connector

23 5 mounting aid

301 another alternative pinch roller

302 shaft

321 single air channels

304 automatic return actuator

341 drive element

306 clamping element

401 another alternative pinch roller

402 shaft

404 electromechanical drive

441 linear actuator

442 linear guide

503 alternate drive

531 interior

534 mounting element

504 drive

543 piston rod

544 connector

And the axial direction

Bisector

H height

P pressing direction

R retraction direction

S axis of rotation

T displacement direction

W tire building drum width

Z1-Z5 zones.

Claims (33)

1. A pinch roller for pressing a ply of a tire on a tire building drum in a pressing direction, wherein the pinch roller includes a shaft defining an axial rotation axis and a plurality of discs axially aligned on said shaft, each disc being composed of an inner a part that is fixedly supported by a shaft and an outer part that rotates relative to the inner part about an axis of rotation, and where each inner part has a recess for receiving the shaft in the axial direction through the corresponding disk, and the recess is larger than the shaft in the pressing direction to allow the corresponding disk to move along with respect to the specified shaft in the pressing direction, while the pressure roller includes one or more drives for each disk for separately moving the corresponding disk relative to other disks, and one or more drives are designed to move the corresponding disk with respect to the shaft in the pressing direction and that the same or another drive/drives are designed to move the corresponding disk with respect to the shaft in the direction of retraction, opposite to the pressing direction, where at least one or more drives are provided with a connecting element for connecting at least one said drive to the inside of the corresponding disk in pressing direction. 2. The pinch roller according to claim 1, wherein the one or more actuators are bi-directional actuators for alternately moving a respective disc relative to the shaft in the pressing direction and in the retracting direction. 3. The pressure roller of claim 2, wherein the bi-directional actuator is an air cylinder connected to a valve block for alternate connection to a pneumatic source and a vacuum source. 4. The pinch roller of claim 2, wherein the shaft includes an air passage for connecting a suitable bi-directional actuator to a valve block for alternately connecting to a pneumatic source and a vacuum source. 5. The pinch roller according to claim 1, wherein the one or more drives consist of a first drive for moving the respective disc relative to the shaft in the pressing direction and a second actuator for moving the respective disc relative to the shaft in the retraction direction. 6. The pressure roller according to claim 5, in which the first and second drives are located in the recess of the corresponding disk on one side of the shaft in the pressing direction or in the retraction direction, and the first drive pushes the corresponding disk away from the shaft, and the second drive pulls the corresponding disk to the shaft. 7. The pinch roller of claim 6 wherein the first drive is an air cylinder connected to a pneumatic source and where the second drive is an air cylinder connected to a vacuum source. 8. The pinch roller according to claim 7, wherein the shaft includes a pneumatic duct for connecting the first actuator to the pneumatic source and a vacuum air duct for connecting the second actuator to the vacuum source. 9. The pinch roller according to claim 5, wherein the first drive and the second drive are located in a recess of the respective disk on opposite sides of the shaft in the pressing direction and in the retraction direction, respectively, and where the first and second drives are designed to push the respective disk away from the shaft or to pulling the corresponding disk to the shaft. 10. The pinch roller according to claim 9, wherein the first and second actuators are pneumatic cylinders that are connected to a compressed air or vacuum source. 11. The pinch roller of claim 10, wherein the shaft includes a first air passage for connecting the first actuator to a pneumatic or vacuum supply and a second air passage for connecting a second actuator to the same pneumatic or vacuum supply. 12. The pressure roller according to claim. 1, in which one or more actuators form an automatic return actuator, equipped with a drive element designed to move the corresponding disk in one of the pressing or retraction directions, and a pressing element designed to bias the drive element to return to reverse direction of pressing or retraction. 13. The pinch roller of claim 2, wherein the bidirectional actuator is a mechanical, electrical, or electromechanical bidirectional actuator. 14. The pinch roller according to claim 1, wherein at least one or more drives are engaged or connected to the interior of the respective disc, wherein the engagement or attachment prevents at least one drive from being axially torn from the interior of the respective disc. 15. The pressure roller according to claim 1, wherein the connecting element is designed to freely connect at least one said drive with the inside of the corresponding disk in the pressing direction. 16. The pressure roller according to claim 1, wherein the inside of the corresponding disk is provided with a mounting element for mounting the connecting element. 17. The pressure roller according to claim 16, wherein the mounting element is a spline and the connecting element is designed to engage with the spline. 18. The pressure roller according to claim 16, wherein the mounting members of the directly adjacent discs are offset from each other in an offset direction perpendicular to the pressing direction and the axial direction. 19. A pinch roller according to claim 18, wherein each disc has a bisector running parallel to the pressing direction, and the mounting elements of the directly adjacent discs are located on opposite sides and equidistant from the bisector. 20. A pinch roller as claimed in claim 19, wherein the adjacent discs are identical and one of the discs is mirrored at a bisector with respect to the other adjacent disc. 21. The pressure roller according to claim 1, in which the pressure roller consists of two or more zones, each of which contains two or more disks from a plurality of disks, and drives for moving disks within one of the zones are designed to simultaneously move all disks in within the specified zone in the direction of pressing or in the direction of retraction. 22. A method for pressing a tire ply onto a tire building drum using a pinch roller according to claim 1, the method consisting of the following steps: - the use of one or more drives to move the corresponding disk relative to the shaft in the direction of pressing; and - the use of one or more actuators to move the corresponding disk in relation to the shaft in the direction of retraction. 23. The method of claim 22, wherein the one or more actuators form a bi-directional actuator that alternately moves the corresponding disc relative to the shaft in the pressing direction and in the retracting direction. 24. The method of claim 22, wherein the one or more drives include a first and a second drive, the first drive moving a respective disk relative to the shaft in the pressing direction and the second actuator moving the corresponding disk relative to the shaft in the retraction direction. 25. The method according to claim 22, in which one or more drives include an automatic return drive, consisting of a drive and a pressing element, and this method consists in the fact that the drive element moves the corresponding disk in one of the pressing or retraction directions, and the pressing element returns the disc in the other direction of pressing or retraction when the drive element is no longer driven. 26. The method of claim. 22, in which the pinch roller includes two or more zones, each of which contains two or more disks from a plurality of disks, and drives for moving disks within one of the zones simultaneously move all disks within the specified zone in direction of pressing or in the direction of retraction. 27. The method of claim 26, wherein the width of the tire building drum is changed or the tire building drum is replaced with an alternative drum of a different width, the method comprising moving the discs in one or more zones wholly or partly outside the width of the drum to tire building drum, in a pulling direction away from the tire building drum while moving the discs in one or more zones within the width of the tire building drum, in the pressing direction away from the tire building drum. 28. The method according to claim 26, in which two or more zones include a central zone and side zones on both sides of the central zone in the axial direction, while the method consists in moving the disks located in the side zones in the retraction direction while moving discs in the central zone in the pressing direction. 29. The method of claim 22, which includes simultaneously moving all of the disks of the plurality of disks in a retraction direction. 30. The method of claim 29, wherein the shaft remains stationary with respect to the tire building drum while all discs of the plurality of discs move in a retracting direction. 31. The method of claim 29, wherein all discs of the plurality of discs simultaneously move in the retraction direction when a front end, a rear end, a junction, or other known or detected uneven surface of the tire ply passes under said plurality of discs.

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