This application is the U.S. national phase, under 35 U.S.C. 371 of PCT/EP2009/051793, filed Feb. 16, 2009; published as WO 2009/138258 A1 on Nov. 19, 2009, and claiming priority to DE 10 2008 001 796.5, filed May 15, 2008, the disclosures of which are expressly incorporated herein by reference.
The present invention is directed to a reel changer having a holder for supporting a material reel with a winding sleeve. The holder has a support journal and a number of driver elements. These driver elements are arranged to engage an end support of the winding sleeve and act in a direction parallel to a rotational axis of the holder.
Clamping cones for use in holding winding components are quite well known, particularly in the printing industry. In axleless reel support systems, suitable clamping cones are inserted into the sleeves of supported material reels using a motorized mechanism. In this process, clamping jaws or driver elements are then pressed into the sleeve material, thereby producing a positive connection, and a frictional connection between the clamping cone and the winding sleeve. Such a connection ensures an optimal transmission of torque from the drive of the winding component to the material reel.
A reel changer for a web-fed rotary printing press, which reel changer has a drive with at least one electric motor, is known from EP 17 08 942 B1. The electric motor drives a material reel on which a web of material is wound, while that reel is being held on a holder in the reel changer. The rotor of the electric motor, which may be embodied as a synchronous motor, has poles comprising permanent magnets. A drive shaft of the synchronous motor can be engaged with the material reel to transmit torque directly to the material reel. For this purpose, driver elements on the drive shaft are especially used, which driver elements are usable to transmit torque to the material reel through a positive and frictional connection.
Driver elements which function axially are also known. Such drive elements may be engaging with the winding sleeve at an end surface of the winding sleeve.
For example, DE 26 12 375 A1 describes cutting edges, which cutting edges are arranged along an outwardly extending flange of the supporting sleeve and on the reel side. These cutting edges ensure that, for example, when there is a change in direction of torque, no slippage will occur between the winding sleeve and the supporting sleeve.
Different winding sleeves, having different material properties, are used for different types and widths of material reels. Sleeve materials can also have different hardnesses. When harder sleeve types are being used, the available uploading force may not be sufficient to force the cone and the end-surface driver all the way into the winding sleeve. Therefore, a complete uploading process and the requisite torque transmission can no longer be ensured.
To make full use of machinery such as is typically used in the printing industry, it is sometimes necessary to process material reels having different configurations in a single production run of the machinery, or in various successive production runs of the machinery. This is especially the case with smaller web-processing systems or with smaller printing establishments. Until now, in order for different types of winding sleeves to be processed, different reel changers have had to be provided within one system. Alternatively, a time-consuming reconfiguration of the sole reel changer has had to be performed, thus resulting in long down times and increased production costs. One example of this would be in the processing of winding sleeves having different hardnesses.
DE 102 24 839 A1 discloses a mandrel for a reel changer. A holding element engages in the inner surface of a sleeve of a material reel and driver elements engage in the end surface of the sleeve of the material reel. Such driver elements extend through a movable switching ring.
The object of the present invention is to enable material reels having winding sleeves of different hardnesses to be loaded into a reel changer, and without a costly reconfiguration of the reel changer being required for this purpose.
The problem is solved in accordance with the present invention by the provision of a reel changer having a holder for use in supporting a material reel with a winding sleeve. The holder includes a support journal and a number of driver elements. These driver elements are arranged to engage an end surface of the winding sleeve. The number of driver elements which engage the sleeve's end surface can be varied.
The benefits to be achieved by the present invention consist especially in that different types of material reels with sleeve materials having different hardnesses can be uploaded in a simple manner, using a single reel changer. This can be accomplished without requiring additional time and without requiring costly reconfiguration of the reel changer. The solution, in accordance with the present invention, is easy to produce and easy to manipulate.
A holder, which is preferably provided as a clamping cone, of a reel changer, includes a support journal, which preferably tapers toward its unattached end, and is preferably also provided with a sleeve mounting surface, against which an end surface of a winding sleeve rests, as the winding sleeve is being uploaded. On the sleeve mounting surface, a plurality of driver elements are provided. These driver elements are forced into the sleeve material at the end surface of the winding sleeve and contribute to torque transmission to the winding sleeve.
The support journal can also have radially projecting driver elements or clamping jaws. These are typically radially adjustable and act on the inner surface of the winding sleeve.
At least one of the driver elements which is provided on the sleeve mounting surface can be retracted at least partially into the sleeve mounting surface. Depending upon the sleeve material that is used and upon its hardness, the number of driver elements to be used can be varied. Preferably, the one or more of the retractable driver elements can be retracted completely into the sleeve mounting surface.
When a winding sleeve, which is made of a soft material, is used, more of the driver elements, which are provided on the sleeve mounting surface, should be used than would be necessary in connection with a winding sleeve which is made of a hard material. The driver elements are preferably arranged on the sleeve mounting surface in a circular pattern and are located to be receivable in an end surface area of the winding sleeve of the material reel which is to be uploaded onto the reel changer. Preferably, a total of six driver elements are provided. The area of each such driver element that acts on the end surface area of the winding sleeve is preferably embodied as having flat, sharp cutting edges, which cutting edges are able to penetrate easily into the winding sleeve. Alternatively, the driver elements can be embodied as conical, cylindrical, or pyramidal in shape. The individual driver elements can also be differently embodied. In particular, the retractable driver elements can be adapted to be insertable into harder winding sleeves.
In one preferred embodiment of the present invention, half of the total number of driver elements provided are retractable. Preferably every second such driver element is retractable.
It is also possible, in accordance with the present invention, for the driver elements to be retracted in groups or individually, thereby allowing multiple graduated stages of driver elements for use with sleeve materials which may vary in sleeve hardness.
In one preferred embodiment of the present invention, the one or more retractable driver elements are axially displaceable and are flexibly mounted in a body of the clamping cone. Rather than having a direct mounting in the clamping cone, the one or more retractable driver elements could also be mounted in a sleeve, which sleeve is located on the bearing side of the clamping cone. The retractable driver elements are preferably flattened at their end which is located in the body of the clamping cone. The flattened end of each such retractable driver element is guided by at least one guide edge, thereby securing the retractable driver elements against rotation within the body. The guide edge can be located either in the body or on another component. This embodiment is particularly advantageous for retractable driver elements that are embodied as having flat cutting edges in their area that acts on the winding sleeve.
The status of the one or more of the retractable driver elements can be switched between “ACTIVE” and “PASSIVE.”
In the active status, the axial displacement of the one or more retractable driver elements is blocked. The one or more of the retractable driver elements therefore projects out of the sleeve mounting surface. During uploading of a winding sleeve, this active status drive element or elements is pressed into the end surface of the winding sleeve. In the passive status, the driver element or elements yields, typically axially, to the pushed on winding sleeve, since it is being retracted against a spring force into the sleeve mounting surface. Once the empty winding sleeve has been stripped off, the retractable driver element, which is in its passive status, is moved back to its original position by the spring.
The switch between “ACTIVE” and “PASSIVE” is achieved by the use of a rotatable switching element. This rotatable switching element, in the preferred embodiment, is embodied as a rotatable switching ring. It will be described in greater detail in the description of the preferred embodiment.
The surface of the rotatable switching ring which faces the driver elements forms a blocking surface, which blocking surface blocks the axial movement of the retractable driver element. The rotatable switching ring also has an opening, which, in the passive status, is positioned in such a way that the retractable driver element is able to pass through this opening in the axial direction of the clamping cone.
The clamping cone can be driven either directly or indirectly in the reel changer. For direct driving, the clamping cone can be embodied as forming a single piece with the rotor of the drive motor. For indirect driving, the clamping cone can be driven by a drive assembly such as a toothed belt, for example.
A reel changer in accordance with the present invention is provided particularly for a web-fed rotary printing press and it comprises essentially a drive unit for rotationally driving a material reel which has been wound onto a winding sleeve, which winding sleeve can be loaded into the reel changer. A clamping cone, which can be driven by the drive unit, is used to upload the material reel.
A preferred embodiment of the present invention is shown in the set of drawings and will be specified in greater detail in what follows.
The drawings show:
The clamping cone 01 is attached to a rotatable mounted shaft 02, which can be driven or which can be mounted so as to freely rotate in the roll stand. In the depicted embodiment, the body of the clamping cone 01 is configured to form a single piece with the shaft 02.
The clamping cone 01 comprises a support journal 03, preferably a support journal 03 having a conical shape and which tapers toward its unattached end. A sleeve mounting surface 04 of an axially shiftable switching ring 10 preferably adjoins the support journal 03, and extends outward, transversely to a longitudinal axis 05 of the cone. In a starting position, which is not specifically depicted, and in which no material reel is loaded onto the reel changer, cutting edges of a plurality of spaced driver elements 06; 07, which are positioned on the clamping cone, are retracted below the sleeve mounting surface 04 of the switching ring 10. This is typically done to prevent accidents. During uploading of a material reel, the axially shiftable switching ring 10 is shifted axially, and essentially is moved parallel with a direction of the rotational axis of the holder 01. As a result of this axial shifting of the switching ring 10, the cutting edges of the driver elements 06; 07 now project out of the sleeve mounting surface 04 of the axially shiftable switching ring 10, as seen in
During the uploading process, the driver elements 06; 07 are forced into an end surface of a winding sleeve. A primary purpose of these driver elements 06; 07 is to improve torque transmission between the clamping cone 01 and a winding sleeve that is loaded onto a reel changer of which the clamping cone 01 is a part.
The support journal 03 also comprises radial, conically configured driver elements 08, which are pressed into the inner wall of the winding sleeve during uploading. Radial driver elements 08 can also be embodied as radially displaceable clamping jaws.
Each one of the retractable driver elements 07 is seated in an associated axially aligned, continuous bored hole 16, as may be seen in
A rotatable switching element, such as, for example, a rotatable switching ring 09, is rotatably arranged on the shaft 02. The rotatable switching ring 09 has one opening 11 for each retractable driver element 07, each which opening 11 ensures the release or the switch-over of the associated retractable driver element 07 from the active status shown, as depicted in
In this passive status shown in
The driver element 07 is retracted by an axial displacement of that driver element 07 when an opening 11 in the rotatable switching ring 09 is located opposite the bearing-side opening of the continuous bored hole 16, as is depicted in
The rotatable switching ring 09 can be fixed in the respectively required position; i.e., in the active status or in the passive status by the use of a locking pin, which is not specifically shown. A stop pin 12 is provided and is usable to limit the rotational movement of the rotatable switching ring 09. The stop pin 12 cooperates with an indentation 13 in the rotatable switching ring 09.
In
The longitudinal axis 05 of the clamping cone 01 is also the rotational axis of the shaft 02.
In the preferred embodiment of the present invention, which is shown in the drawings, the body 14 of the clamping cone 01 is embodied as forming a single piece with the shaft 02. However, this body 14 of the clamping cone 01 may also be embodied as a separate part or as a sleeve. In the body 14, a continuous bored hole 16 extending axially is provided for each retractable driver element 07 and in which bored hole 16, each such retractable driver element 07 is seated and is guided so as to be displaceable axially.
At the shaft end or bearing end of the bored hole 16, the rotatable switching ring 09 is located. As has been discussed above, depending upon the rotational position of this rotatable switching ring 09, it can either block or allow the axial movement of the retractable driver element 07. The blocked position of the retractable driver element 07 is shown in
When a winding sleeve 26, that is to be uploaded onto the clamping cone 01, acts on the retractable driver element 07 on the cone side, that retractable driver element 07 yields axially and its end, opposite to its sleeve engaging end, can shift through the opening 11 in the rotatable switching ring 09. The pointed end of the retractable driver element 07 is thereby retracted into the sleeve mounting surface 04. This passive position of the retractable diver element 07 is depicted in
In the clamping cone 01, three retractable driver elements 07, alternating with fixed driver elements 06, can preferably be arranged in a circular pattern These three retractable driver elements 07 can be evenly spaced around the sleeve mounting surface 04.
The support journal 03, with the radial driver elements 08, is produced from the shaft 02 of the motor 19 using correspondingly appropriate processing methods. This eliminates the need for a separate cone between winding sleeve and drive shaft.
The synchronous motor 19 is embodied as a type of field-weakening synchronous motor 19, which can be operated with field weakening up to a ratio of 1:10. The synchronous motor 19 is equipped with poles 21 and an electric excitation 23, in a generally known manner. Particularly, the rotor 18 of the synchronous motor 19 has poles 21 comprising permanent magnets, and the stator 22 of the synchronous motor 19 has an electric excitation 23. The permanent magnets are preferably embodied as rare earth materials.
The retractable driver elements 07 are not shown in the depiction of the present invention shown in
In another embodiment of the present invention, the clamping cone 01 is driven indirectly by the use of a preferably position-controlled electric motor. This is preferably achieved by the use of a toothed belt.
In a first operating status as depicted in
In a second operating status, as depicted in
A second number of active driver elements 06; 07, which engage in the end surface 27 of the second winding sleeve 26, are arranged on the holder of the second winding sleeve. This second number of active driver elements 06; 07, as depicted in
While preferred embodiments of a reel changer having a holder for supporting a material reel with a winding sleeve have been disclosed fully and completely hereinabove, it will be apparent to one of skill in the art that various changes and modifications to, for example the structure of the reel changer, the specific structure of the drive motor, the materials used for the material reel and the like, could be made without departing from the true spirit and scope of the present invention which is accordingly to be limited only by the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
10 2008 001 796 | May 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2009/051793 | 2/16/2009 | WO | 00 | 10/29/2010 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2009/138258 | 11/19/2009 | WO | A |
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Number | Date | Country | |
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20110042505 A1 | Feb 2011 | US |