DE19854735B4 - Method for producing a sleeve of thermally deformable material - Google Patents

Abstract

A sleeve (1) made of a thermally deformable material, used for example in the printing industry, consists of a tubular base member with a cylindrical outer circumference. The latter has a constant radius and a cylindrical inner diameter which reduces conically in the axial direction.

Description

The The invention relates to a method for manufacturing a sleeve thermally deformable material according to the preamble of the claim 1.

In The printing industry will be mainly two Processes that work with rotary printing forms distinguished. For gravure printing mainly metallic cylinders are used, on their surface a functional profile is introduced. Usually, steel will roll galvanically coated with a copper layer, in which then a functional profile is introduced.

In flexographic printing, sleeves are often used which are produced by electroplating (for example nickel sleeves) or consist of fiber-reinforced thermosetting materials, as used in the art DE 27 00 118 A1 are addressed. Again, located on the outer surface of the sleeves, the functional profile. The sleeves are usually mounted pneumatically on metallic roll cores.

In all other technical fields are essentially metallic Cylinder with a technical surface, for example a PTFE coating, metallic sleeves or hollow cylinder with a technical surface or wound, fiber-reinforced thermosetting sleeves with a technical surface used. The technical sleeves can Pneumatically mounted on roll cores, used as pipes or as semi-finished products for the cylinder production can be used.

The non-metallic cores as mentioned above, by winding a strip material around a production core made around. This procedure is both temporally as well as technically extremely elaborate, on the other hand that leads Winding method that on the abutting edges or the overlapping edges the strip material creates unwanted steps or irregularities, the the surface the pressure sleeves make uneven, which in particular problems with fine printing structures leads. Especially for very high quality surfaces For this reason, it is more costly surface treatments perform, about the qualitative claims to fulfill.

From the DE 292737 A a method according to the preamble of claim 1 is known. Here, glass tubes are melted down on certain shaped production cores. While a dimensionally accurate interior surface can be created, the exterior surface usually exhibits imperfections.

It is therefore an object of the present invention, a method for making a sleeve to disposal to ask, whose surface and overall quality highest Requirements are sufficient and which can be quickly and easily placed on a carrier core.

The The object is achieved by a method according to claim 1.

at the production process according to the invention is used as a raw material thermally deformable material in the form of a Pipe or tube used. These pipes or hoses become under heat mounted on a production core or postponed, this Manufacturing core tapering in an axial direction conically cylindrical outer circumference having. The mounting on the production core is expediently from the rejuvenated Side of the manufacturing core instead. After mounting you leave the thermally deformable pipes or hoses or the entire system cooling down, so that the thermally deformable material consolidated. The now solidified material has the desired shape in a simple and fast way assumed, with an extremely smooth surface that meets the highest standards produced has been. The thus produced and consolidated sleeve is removed after cooling from the manufacturing core.

The Heat when Applying the material is over fed to the production core, wherein the manufacturing core is heated by an upstream heating process can be. However, the manufacturing core is also preferred during the Sliding the thermally deformable material heat supplied. Thereby becomes a particularly uniform and smoother Process allows.

The Sliding the tubular Semifinished product on the production core is preferred with a pressing device, in particular an automatically operated mechanical pusher, performed while the finished sleeve with the help of a scraper after the consolidation of the manufacturing core is stripped off. These operations will be advantageously carried out automatically.

The Size of power, the for the friction between the finished sleeve and responsible for the use carrier core may be through the controllable process parameters be significantly influenced in the production, in particular the temperature, so that the Manufacturing core also as a carrier core can serve.

In a preferred method, the production core is heated by means of a heat transfer fluid or a heat transport gas or cooled. The liquid or gas is pumped through passages or openings in cavities of the production core and removed again. As a result, on the one hand a very precise control of the temperature, on the other hand a rapid change of temperature, ie in particular a change from heating the manufacturing core for cooling the manufacturing core, after the corresponding molding process is completed, allows.

The according to the inventive method manufactured sleeve consists of a substantially tubular, one-piece body, whereby a smooth and qualitatively flawless surface is ensured what especially with regard to the functional profiles to be introduced on the surface is of high importance. The sleeve has a cylindrical outer periphery with a substantially constant radius on what, in terms of the use in the printing industry is important while the internal structure of the Sleeve one in an axial direction, conically tapering cylindrical circumference having. As a result, the assembly or the attachment to a corresponding carrier core with a conically extending outer surface much easier. The production line can adapt to changing requirements and fast Tasks adapted so that the flexibility elevated becomes.

The Sleeve exists made of a thermoplastic material, which ensures a very cost-effective manufacturing process which at the same time the characteristic properties of the Materials, especially light weight with sufficient stability used can be. Depending on the application area can Also composites are used, causing the sleeve on special applications can be adapted in which, for example an even higher one Strength is required or certain materials due the materials to be processed or printed on not used should be.

On the sleeve surface is a functional profile introduced or it is an additional Applied functional layer. The additional functional layer can made of PU, PTFE, copper or other suitable materials. The functional layer can be connected to the sleeve by all common methods it is possible, in particular, glue the functional layers to the sleeve surface.

The Sleeve points prefers on its inside fastening or locking devices, thus a secure attachment and positioning on the carrier core while the pressure application is ensured. Such attachment or Locking devices can have different structures, so that a positive connection between sleeve and carrier core is ensured. These structures are preferably of the same Material like the sleeve and formed integrally therewith so that an exact position and sufficient stability ensures the structural elements is.

at an embodiment the sleeve is made a rigid material so that they has a particularly stable structure with regard to the pressure application.

Especially In this case, it is advantageous to have an elastic layer on the inside to provide the sleeve. The stretch layer is compressible and ensures a particularly good frictional connection between the complex sleeve / stretch layer and the carrier core. The stretch layer may be electrically conductive, for example by introducing conductive Allows particles becomes.

The Stretching layer consists of a compressible material, preferably become foams, elastic Materials with a gaseous Filling, to Example expanded polystyrene beads, or elastic materials used with a structuring, the structuring similar to the gaseous filling Volume available represents, be displaced into the material can, as soon as the sleeve is pushed becomes, whereby a special yielding and elasticity and a increased compressibility to disposal is provided.

The Stretch layer takes over usually several essential functions: on the one hand it provides through the energy stored by the compression in it is for the for a frictional Connection necessary force or the necessary pressure between Stretch layer and carrier core, on the other hand she takes care of a uniform distribution of Pressure, especially when mounting or removing the sleeve to or from the carrier core damage avoids. Furthermore, the stretch layer may become necessary if the sleeve is pneumatic from the carrier core, For example, by blowing compressed air between the outer layer of the carrier core and the inner layer of the sleeve or the stretch layer is removed. Finally, the stretch layer is the same also any existing bumps on the inside of the tubular body.

In the expansion layer, a groove is preferably introduced which extends over at least a portion of the radial extent of the expansion layer, preferably less than 50% of the radial extent of the expansion layer. The groove creates volume into which additional material of the expansion layer displaced can be so that the compressibility of the stretch layer is increased. Furthermore, the groove, as well as any structures provided on the inside of the sleeve, can be used as a fitting and fitting aid when the sleeve is placed on the carrier core. It can only be provided a groove, it is also possible to distribute different, preferably extending in the axial direction grooves over the entire inner circumference of the sleeve.

Further should be noted that a such stretch layer not only on the inner portion of the sleeve directly can be attached, but also can be attached to the carrier core, which in the end leads to comparable results.

Next the at least one groove can also Structures are provided on the inside of the sleeve, the either as a joining and fitting assistance serve, but also as fastening and locking devices for a safe Fixing the sleeve at the carrier core to care.

Next The possibility, as raw material thermally deformable pipes or hoses as semi-finished products The thermally deformable material can also be used directly applied from an extruder in tube or tube form on the production core become. In this case, almost none heat be applied through the manufacturing core, since the material already has a sufficient temperature. Nevertheless, a heat supply over the Manufacturing core be useful to z. B. the consolidation process in time to stretch, causing the caused by temperature differences Loads of material are lowered. The cooling can then be in the above described manner performed become.

One carrier core for the Use of a shell described above has one of the internal structure of Sleeve corresponding, in an axial direction, conically tapered cylindrical outer periphery on to allow a precise interaction between the carrier core and sleeve. The carrier core can with corresponding counter-elements to those described above Be provided structures on the inside of the sleeve, so that a frictional and / or a form-fitting Connection is realized.

Further indicates the carrier core preferably at least one is substantially in the radial direction outward through the carrier core extending channel through which advantageously from outside of the carrier core a gas, preferably compressed air, or also a liquid between the carrier core and the sleeve pressed can be to demolding the sleeve of the carrier core to facilitate.

As already mentioned above, can the carrier core Also include an expansion layer which is attached to its outer structures. The effects are analogous to the stretched layer attached to the sleeve. Also the preferred material does not differ from the material of one on the sleeve attached stretch layer. Furthermore the stretch layer can also be provided here with a groove.

Of the The present invention is characterized by the appended Drawings clarifies in which

1 schematically illustrates an embodiment of a sleeve in cross-section, which is located on a carrier core;

2 a schematic cross-sectional view of an embodiment of a sleeve to be manufactured and an embodiment of a manufacturing core during the manufacturing process shows.

3 in Part A schematically shows a tubular semifinished product in cross-section before and in part B after sliding onto an embodiment of a manufacturing core according to the invention, and in part C schematically shows in cross-section an embodiment of a sleeve according to the invention in use on a carrier core.

1 shows an embodiment of a sleeve 1 which has a cylindrical outer circumference of substantially constant radius and a rightward tapered cylindrical inner circumference. The sleeve is made of thermoplastic material and has an average wall thickness of 10 mm.

Installed inside, the sleeve has an elastic layer 3 on, which consists of an elastomeric material and has a wall thickness of 1 mm. Grooves are introduced into the stretch layer 4 (Only two seen), which extend in the axial direction substantially over the entire region of the sleeve, while they have excluded only about 25% of the thickness of the elastic layer in the radial direction. The grooves are here attached to the side of the sleeve, whereby a clean and uninterrupted inner surface of the expansion layer is ensured, resulting in a particularly simple sliding of the sleeve on the carrier core. It is of course also conceivable, the grooves 4 on the opposite side of the stretch layer 3 , so open to the interior, to install.

The stretch layer 3 is by means of a conventional adhesive on the sleeve 1 , but better at the carrier core, as related to 3C described, attached. The stretch layer can too be self-adhesive. In 1 is also the hollow carrier core 2 can be seen, which has a left-tapered cylindrical outer structure. The cylinder is optionally made of steel and has a thickness of 30 to 500 mm. The carrier core 2 has a channel 5 on, extending in the radial direction from the inside out through the carrier core 2 extends. There are other channels mounted in the carrier core, which are not apparent in this cross-sectional drawing.

The interior of the carrier core can be pressurized by means of gas or a liquid, whereby the gas or the liquid through the channels 5 penetrates to the outside and between carrier core 2 and sleeve 1 or stretch layer 3 pushes and the sleeve 1 or stretch layer 3 slightly lifts off the carrier core or reduces the contact pressure, whereby a slight stripping of the sleeve is facilitated by the carrier core.

2 shows schematically the production of a sleeve of a tubular semi-finished product, a tube 9 , The pipe 9 made of thermoplastic material has a wall thickness of 10 mm and comes with an automatically operated metal plate 10 , which serves as Aufpreßvorrichtung, on the production core 6 pushed. The manufacturing core 6 It is made of steel and has a cylindrical conical outer structure that tapers to the left. By pushing the tube 9 on the heated production core 6 the pipe fits 9 the desired shape.

The manufacturing core 6 has two openings at one end 7 on, giving access to a cavity 8th open up inside the manufacturing core 6 located. Through these openings 7 a heat transfer fluid is pumped, which is the production core 6 keeps at the desired temperature. For a later cooling, while the thermoplastic material of the tube 9 is consolidated, a cooling fluid is also through the two openings 7 and the cavity 8th of the manufacturing core 6 pumped.

After consolidation, it will be out of the pipe 9 formed sleeve 1 with the help of a scraper 11 automatically from the manufacturing core 6 stripped.

The now completed sleeve can subsequently optionally with a surface structuring or a functional layer can be provided, further, an elastic layer be attached.

3 shows for clarity the tubular semi-finished product 9 in original condition, after sliding onto a production core 6 and the finished sleeve 1 on a carrier core for pressure application.

3A schematically shows a cross section through a tubular semi-finished product 9 which has a wall thickness of 10 mm. The inner diameter d1 is constant in the ground state before processing over the entire length of the semifinished product.

3B schematically shows a cross section through a on a production core 6 mounted semi-finished product 9 , By pushing or pulling the semifinished product 9 on the carrier core fits, as already described above, the tube 9 the desired shape and forms the sleeve 1 , The outer diameter d2 of the manufacturing core 6 is different due to the conical shape depending on the sectional area, but always has a value which is greater than or at least equal to the original inner diameter d1 of the semi-finished product to a defined shapes of the tube 9 sure.

The manufacturing core 6 has a longitudinal groove 15 on, which is an integrally formed fastening device 16 on the inside of the tube 9 or the sleeve to be produced 1 ausformt.

In 3C is the finished sleeve 1 shown on a carrier core 20 mounted for printing. The sleeve 1 has an integrally formed fastening device in the form of a web 16 up in a groove 17 engages the carrier core. This is a secure positioning both during winding of the sleeve 1 on the carrier core 20 as well as during printing and labor.

The carrier core 20 has an elastomeric coating acting as a stretch layer 21 which, in this embodiment, directly on the carrier core 20 is attached. The stretch layer 21 extends substantially over the entire outer region of the carrier core 20 and is only in the area of the groove 17 interrupted to secure engagement of the bridge 15 to ensure.

Similar to the in 1 illustrated embodiment, the stretch layer 21 longitudinally extending grooves 4 on, at regular intervals around the outer circumference of the stretch layer 21 are distributed. The stretch layer 21 here is essentially analogous to that in 1 formed expansion layer, except that they are in this embodiment directly to the carrier core 20 and not on the sleeve 1 is attached.

The features of the invention disclosed in the above description, in the drawing and in the claims can be used individually as well as also be essential in any combination for the realization of the invention.

Claims (6)

Method for producing a sleeve ( 1 ) of thermally deformable material, in particular for use as a technical sleeve ( 1 ) in the printing industry, in which the thermally deformable material in the form of a tube or a thermally deformable tube ( 9 ) on a manufacturing core ( 6 ) is pulled or pushed, the production core ( 6 ) having a cylindrical outer periphery conically tapering in an axial direction, is heated, and thereafter the thermally deformable material of the pipe or tube is cooled, whereby it consolidates and the sleeve ( 1 ) is formed, and the sleeve ( 1 ) from the manufacturing core ( 6 ) is removed, characterized in that the heat by an upstream heating process of the manufacturing core ( 6 ), the thermoformable tube or the thermoformable tube ( 9 ) by means of a pressing device ( 10 ) on the production core ( 6 ) is pushed and the sleeve ( 1 ) after consolidation by means of a scraper ( 11 ) from the manufacturing core ( 6 ) is stripped off. Method according to Claim 1, characterized in that the production core ( 6 ) by means of a transport liquid or a transport gas, which by accesses ( 7 ) inside the manufacturing core ( 6 ) at least one cavity ( 8th ) and is discharged from this, heated or cooled. Method according to Claim 1 or 2, characterized in that the thermoformable tube or the thermally deformable material ( 9 ) directly from an extruder to the production core ( 6 ). Method according to one of claims 1 to 3, characterized in that on the production core ( 6 ) structures are formed and integral structures on the inner portion of the sleeve ( 1 ) are formed. Method according to one of claims 1 to 4, characterized that this thermally deformable material consists of composite materials. A method according to claim 4, characterized in that the integrally formed structures comprise fastening or locking devices ( 16 ) are.