DE102011122902A1 - A tool for producing a microstructured outer surface layer on a substrate surface - Google Patents

Abstract

Tool (2) for producing a layer with a microstructured outer surface on a substrate surface, comprising an elastic matrix web (10) with a negative of the microstructure to be produced, a surface-movable elastic pressure roller (4) and at least one guide element (18, 20, 26) for guiding the elastic die path (10) relative to the pressure roller (4), wherein the pressure roller (4) and the die path (10) are arranged such that when the pressure roller (4) moves over the substrate surface, the negative on the die path (10 ) is directed to the substrate surface. As a result, a particularly high tracking accuracy and guidance precision of the die track (10) can be achieved.

Description

TECHNICAL AREA

The invention relates to a tool for producing a layer having a microstructured outer surface on a substrate surface.

BACKGROUND OF THE INVENTION

It has long been known to provide surfaces with a microstructured coating to achieve various benefits, such as reducing fouling sensitivity, reducing drag, or other effects. In particular, the equipment of surfaces umströmter body with so-called "riblets" can lead to a significant reduction in flow resistance, which results in an increase in efficiency especially for vehicles of any kind and other inflicted bodies, such as leaves of wind turbines.

Equipping a surface of a vehicle with a microstructure may be performed by various application, bonding and embossing methods. From the DE 10 2006 004 644 B4 discloses a tool for forming a microstructured outer surface layer on a substrate surface, in which a web of elastic matrix is pressed with a negative of a microstructure to be formed by means of a movable elastic pressure roller, so that the material to be pressed between the substrate surface and the die can be positioned and cured, for example, using a radiation source. It is disclosed to use a pressure roller and at least one guide roller.

SUMMARY OF THE INVENTION

The application of a coating material to be cured onto a substrate surface by means of a roller which is moved over the substrate surface may have a number of disadvantages, in particular in the treatment of larger surfaces. A material to be applied with the aid of such a tool can be easily conveyed and metered so that, when the coating material is pressed onto the substrate surface, it can be assumed that the coating substance swells out laterally from the intermediate space between the substrate surface and the die or from the edges of the die web are not in contact with the substrate surface, dripping down. Furthermore, it is to be expected that, in particular for larger and not completely planar shaped substrate surfaces, a lateral relative movement of the die to the pressure roller can be established, so that the microstructure is applied incorrectly.

The object of the invention is therefore to propose a tool for producing a layer with a microstructured outer surface on a substrate surface, which provides a particularly high precision of the microstructured layer and at the same time the risk of contamination or the escape of excess coating material edge of a desired extent of the microstructured layer prevented.

The object is achieved by a tool having the features of the independent claim 1. Advantageous developments and embodiments can be taken from the subclaims and the following description.

The tool for producing a microstructured outer surface layer on a substrate surface comprises an elastic die trajectory having a negative of the microstructure to be formed, a surface movable elastic pressure roller and at least one guide element for guiding the elastic die trajectory relative to the pressure roller, the pressure roller and the die path are arranged in such a way that during the process of the roller over the substrate surface the negative is directed on the die path to the substrate surface.

That from the DE 10 2006 004 644 B4 Accordingly, the known tool is modified in such a way that the mold path is prevented from moving relative to the substrate surface by a relative movement in the lateral direction to the pressure roller. The guide element is preferably designed in such a way that a limited free running cross section is provided along the pressure roller along the die path through which the die path can be moved. The dimensions of this running cross-section are adapted to the width of the die path, so that the die path can not break laterally from a predetermined movement. In particular, in the coating of larger substrate surfaces, which are not completely flat and approximately curved in space, it can be ensured that the die path always follows exactly the movement of the pressure roller on the substrate surface and thus the applied coating material follows the exact geometrical requirements.

In an advantageous embodiment, the guide element is designed as a guide body, on which the die path slides and which are arranged along an axis of rotation of the pressure roller on both sides of the tool extending frame elements. Such frame members form with the guide bodies a frame which is rigidly secured to the tool, such as a tool frame. The guide bodies are intended to provide a make direct contact with the matrix path and limit their lateral mobility.

In an advantageous embodiment, the tool has a doffer roll and a deflection roll which, together with the pressure roll, provide a closed trajectory for the die trajectory. The at least one guide element can extend over several regions of the tool in order to guide the die path corresponding to the pressure roller and in addition to the doffer roller and the guide roller. The doffer roll is intended to remove the matrix web from the at least partially dried riblet application again.

In an advantageous embodiment, the doffer roller is arranged behind the pressure roller in the direction of travel of the die path. A section of the die path runs between the pressure roller and the doffer roller and thereby touches the substrate surface. In order to guide this section relative to the pressure roller and the doffer roller, the at least one guide element is preferably spaced from the side of this section facing the substrate surface, wherein the guide element extends approximately laterally next to the pressure roller and the doffer roller or wherein the guide body is in an area laterally of Extend the pressure roller and the doffer roller into it.

In an advantageous embodiment, the guide bodies are arranged by holding means on the frame members, wherein the holding means are adapted to set a distance between the frame members and the guide bodies. As a result, a fine adjustment of the guidance of the matrix path is achieved.

An advantageous embodiment has channel body with a gutter, which extend at least partially to edges of the die path. The drainage channels collect excess coating material that would drain or drip from the edges of the stencil sheet onto the substrate surface. This prevents contamination of the substrate surface or of the microstructured coating. Preferably, the coating material remains in the gutters or is discharged into an additional container which is connected to the gutters. The gutters may further each be connected to a container which is located directly on the gutter body.

An advantageous embodiment of the invention has a metering device which is set up to adjust the layer thickness of the coating material applied to the matrix. The metering device preferably follows directly onto a pickup roller or a device for applying a coating material.

In an advantageous embodiment, the metering device is designed as a doctor blade or a metering doctor blade, which is arranged at a selectable distance from the die path. Squeegees are particularly effective means for homogeneously adjusting the layer thickness of a fabric on a movable web. A squeegee can be made of various materials, such as metal or plastic and have different shapes, such as rounded, rectangular or square.

In a particularly advantageous embodiment, a pressing means is arranged on a side of the die path opposite the doctor blade, which is adapted to precisely guide the die path to the doctor blade, so that the doctor blade can set a particularly precise layer thickness. The pressure means may be embodied as a further guide body whose width preferably corresponds to the width of the die path. The pressure means may be coated with a particularly lubricious fabric so that the stencil sheet can easily slide over it. The material is referred to the material of the guide body here.

The squeegee and the pressure means may be resiliently mounted, so that always sufficient contact with the die path is made, even if it moves when using the tool.

In an advantageous embodiment, the tool has an application device which applies the coating material to the die path. The application device is preferably arranged between the doffer roller and the deflection roller in order to provide the coating material with sufficient time to achieve complete wetting of the matrix path.

In an advantageous embodiment, the squeegee is arranged in the direction of the die path directly after the applicator to remove as soon as possible after application, possibly superfluous coating material from the die path and to prevent dripping.

In an advantageous embodiment, a second rake is arranged in the running direction between the guide roller and the pressure roller, so that any remaining excess coating material can be removed.

In an advantageous embodiment, the tool has scrapers which communicate with the channel bodies and are positioned on the tool so as to contact the edges of the matrix path. The scrapers can direct the coating material into the gutters, which are located laterally on the die path. Thus, even smaller excess amounts of the coating material can be derived, which indeed wet the edge outer sides of the matrix sheet, but would not drip off by itself.

In an advantageous embodiment, the channel body are arranged on the guide bodies, so that the guide body itself are the scrapers. This makes the tool more compact and easier.

In an advantageous embodiment, the deflection roller has a guide groove whose width is adapted to the width of the elastic die track. By means of this guide groove, a guidance of the die path can already be achieved by the deflection roller, so that a very precise guidance of the die path is achieved together with the guide bodies or other suitable guide elements.

An advantageous embodiment of the tool has a tool frame, on which at least one first latching element is arranged, which corresponds with at least one second latching element on a frame element such that the frame element can be fastened to the tool via a releasable latching connection. The guide element can be attached from the outside or from the inside by means of latching connection to the tool frame. This allows for the necessary replacement of a template path a quick and easy removal of the guide element to increase the operational readiness of the tool.

BRIEF DESCRIPTION OF THE DRAWINGS

Other features, advantages and applications of the invention will become apparent from the following description of the embodiments and the figures. All the described and / or illustrated features alone and in any combination form the subject matter of the invention, regardless of their composition in the individual claims and their back references. In the figures, the same reference numerals for identical or similar objects.

1 shows a schematic side view of a tool.

2 shows a detail of a rear view of the tool.

3 shows a detail of a plan view of the tool.

4 shows a modified embodiment of a tool in a schematic side view.

5 shows a partial sectional view of the tool 2 ,

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

1 shows a tool 2 in a schematic side view. The tool 2 has a pressure roller 4 , a doffer roll 6 and a guide roller 8th on, which is a movable, elastic matrix sheet 10 lead on a closed circle. The matrix railway 10 extends around all three rollers 4 . 6 and 8th and can be moved like a belt by rolling the individual rollers. A tool frame 34 , which by way of example and not necessarily has the shape of an inverted T, is adapted to the rollers 4 - 8th rotatably store, other components to hold and the tool 2 on a robot arm or any other means of movement to lead. It is advantageous if the tool frame 34 allows above a rotatable about a vertical axis storage on a moving means, so that during a job operation, a changing direction of movement is possible and the tool 2 only a constant running direction of the die path 10 experiences.

The tool 2 is moved in the direction of the arrow on a substrate surface (not shown). The matrix railway 10 thus moves clockwise and gets in a rolling motion of the pressure roller 4 on the substrate surface between the pressure roller 4 and substrate surface. One on a negative side of the die path 10 adhesive coating material, the die path 10 completely wetted, gets between the matrix path 10 and the substrate surface, thereby being delivered to the substrate surface.

The negative side of the matrix path 10 is on one of the rollers 4 . 6 and 8th opposite side of the mold path 10 , The coating material to be dispensed onto the substrate surface may be in an area between the doffer roller 6 and the guide roller 8th and alternatively or additionally between the guide roller 8th and the pressure roller 4 on the matrix path 10 be applied. This can be done, for example, by an applicator 12 take the form of a dispensing nozzle or other suitable devices. A The selected layer thickness can be set by means of a metering doctor blade, which is preferably located between the pickup roller 6 and the guide roller 8th in the direction of the die path directly after the applicator 12 is located as in 4 shown in more detail.

In a region between the pressure roller 4 and the doffer roller 6 At least a partial curing of the coating material can take place, for example by irradiation with a radiation source S, which is located in the interior of the tool 2 located. The matrix railway 10 could be at least partially translucent for this purpose, so that the rays emitted by the radiation source can reach the coating material.

Since the coating material can usually be a liquid or at least pasty coating material which opens onto the negative side of the matrix web 10 is applied, there is a risk that the coating material is not on the die path 10 remains, but laterally at the edges of the matrix path 10 drains or drips, causing an uncontrolled release on the substrate surface. Furthermore, during a movement of the tool 2 on the substrate surface due to the pressing force of the pressure roller 4 and the movement of the tool 2 readily occur that the die path 10 laterally on the rollers 4 . 6 and 8th slips or drifts. This drift leads to an imprecise delivery of the coating material, which is completely undesirable, especially in the case of a microstructure.

For this reason, the tool according to the invention 2 on both sides preferably on a guide frame, which for example consists of a first frame member 14, a second frame member 16 and two guiding bodies 18 and 20 composed of fixed to the axes of rotation of the rolls 4 . 6 and 8th are arranged. By way of example, the two frame elements extend 14 and 16 parallel to a distance between the pressure roller 4 and the doffer roller 6 is formed. Such a guide frame may be separate from the tool frame 34 be present, on the other hand, in an alternative embodiment, the actual function of the tool frame 34 for holding the rollers 4 . 6 and 8th fulfill. However, the frame elements are preferred 14 and 16 via one or more releasable latching or clip connections with the tool frame 34 connectable, allowing for replacement of the die path 10 no complex disassembly work of the guide body 18 and 20 must be performed. An exemplary representation of such a latching connection is in 5 shown.

The guide body 18 and 20 are intended, a lateral movement of the matrix path 10 and thus a drift on the rollers and in particular the pressure roller 4 to prevent. Therefore, it is necessary that they are provided with a lubricious coating, for which in particular a layer of polytetrafluoroethylene (also known as "Teflon") is available. The actual material of this guide body 18 and 20 could be a common material for making a non-weight limited tool. The frame elements 14 and 16 could be made of steel and only the guide body 18 and 20 have a corresponding coating.

In 2 will the in 1 with "A" marked top view of a detail above the doffer roller 6 shown. Here are the leaders 18 two sides next to the matrix path 10 shown on the width of the template path 10 are aligned. A fine adjustment of the lateral position of the guide body 18 becomes exemplary for leadership body 18 and 20 further below in 5 shown in section at the section marked CC. Due to the fine adjustment, manufacturing deviations can occur during the production of a matrix sheet 10 or the tool 2 to be balanced in itself. It is preferably a distance of 10 microns to 1 cm between the guide bodies 18 respectively. 20 and the adjacent edge of the template path 10 train. This can be done by adjusting a holding means 22 the distance "d" between the guide body 18 and the frame element 14 be varied.

It can also be seen that to receive excess coating material slightly above the doffer roll 6 on both sides one through a gutter body 24 trained gutter is arranged, wherein the gutter body 24 as a sheet with a series of bends for forming a channel shape or as a plastic component, the inclusion of the coating material can be carried out. By integrating a gutter body 24 will cause contamination of the substrate surface by avoiding dripping edges of the stencil sheet 10 largely prevented. In the illustration shown, both are between the pickup roller 6 and the guide roller 8th arranged guide body 18 each with a gutter body 24 connected. The gutter body 24 However, they could also be considered separate and from the guide bodies 18 be realized separate components. Furthermore, it is conceivable, even the side between the guide roller 8th and the pressure roller 4 with gutters 24 equip.

Exemplary, the channel body 24 one each laterally and longitudinally extending, trough or cup-like receptacle 25 on, in which excess coating material can collect. By removing the gutter body 24 can the respective receptacle 25 be emptied.

To assist in picking up excess coating material are the guide bodies 18 Beveled, with the thus formed and in 2 and 5 apparent slope 17 largely from the matrix railway 10 to the respective adjacent channel body 24 extends. In a connection area between the die path 10 and the guide body 18 can be a paragraph 19 be formed with a height of 5 microns to 1 cm relative to the die path, whose height is particularly preferably in a range of 10 .mu.m to 100 .mu.m.

In the 3 shown side view of an upper part of the tool 2 with a guide roller 8th makes it clear that the guide roller 8th a guide groove 26 may have, whose width with the width of the die path 10 corresponds. The combination of this guide groove 26 and the guiding bodies 18 and 20 This allows a particularly advantageous and precise guidance of the die path 10 cause. The depth of the guide groove should be in a range of 10 μm to 1 cm, and more preferably in a range of 10% to 200% of the thickness of the template web 10 , The width of the groove should preferably exceed the width of the die path by 500 μm to 1 mm in order to control the movement between the guide roller 8th and the template path 10 not to complicate, but as closely as possible be designed, otherwise the die would perform too much lateral movement. The guide groove 26 in the guide roller 8th thus represents a movable guide element.

In 4 becomes a simplified page display of a tool 28 shown in addition to the tool 2 out 1 two more dosing knives 32 and 33 and one on one of the doctor blades 32 arranged opposite side of the die path pressure means 30 having. In this way, an exact dosage of the coating material by accurately guiding the matrix path 10 behind the metering blade 32 be performed, resulting in a precisely set layer thickness.

5 makes a cut at the cut line marked CC 2 an exemplary arrangement of the gutter body 24 with a guide body 18 , two holding means elements 21 and 23 , a tool frame 34 and a frame member 14 on the tool frame 34 is a first locking element 36 arranged, with a second locking element 38 on the frame element 14 is designed correspondingly, so that these elements can undergo a snap or clip connection. The embodiment shown should not be construed as a limitation, but all conceivable locking elements are used, the one locking connection between the tool frame 34 and a frame member 14 can produce. By a latching connection frame elements 14 and 16 and thus the guide body 18 and 20 very easy on the tool 2 or 28 are attached and removed again.

For fine adjustment of the marked "d" distance of a holder of the guide body 18 on the frame element 14 with the help of the two holding means elements 21 and 23 can one at both holding means elements 21 and 23 arranged locking means 22 can be used, which allows the resulting holding means an adjustable, variable extension. The locking device 22 may be about a bolt or a screw in at least one of the two holding means elements 21 . 23 is screwed in and their distance from each other can change. Between the two holding means elements 21 . 23 could be arranged a coil spring or a similar element, which provides for a continuous spacing on the frame member 14 can thus a positionally variable mounting of the guide body 18 respectively. The holder of all other guide bodies or frame elements is accordingly.

In addition, it should be noted that "having" does not exclude other elements or steps and "a" or "one" does not exclude a multitude. It should also be appreciated that features described with reference to any of the above embodiments may also be used in combination with other features of other embodiments described above. Reference signs in the claims are not to be considered as limitations.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102006004644 B4 [0003, 0008]

Claims (13)

Tool ( 2 . 28 ) for producing a layer with a microstructured outer surface on a substrate surface, comprising - an elastic matrix web ( 10 ) with a negative of the microstructure to be produced, - an elastic pressure roller movable over a surface ( 4 ) and - at least one guide element ( 18 . 20 . 26 ) for guiding the elastic matrix web ( 10 ) relative to the pressure roller ( 4 ), wherein the pressure roller ( 4 ) and the template path ( 10 ) are arranged such that in the process of the pressure roller ( 4 ) over the substrate surface, the negative on the matrix sheet ( 10 ) is directed to the substrate surface. Tool ( 2 . 28 ) according to claim 1, wherein the guide element ( 18 . 20 . 26 ) as a guiding body ( 18 . 20 ) is executed, on which the die path ( 10 ) slides on and along an axis of rotation of the pressure roller ( 4 ) on both sides of the tool ( 2 . 28 ) running frame elements ( 14 . 16 ) are arranged. Tool ( 2 . 28 ) according to claim 1 or 2, further comprising - a doffer roll ( 6 ) and - a deflection roller ( 8th ), wherein the doffer roller ( 6 ) and the guide roller ( 8th ) together with the pressure roller ( 4 ) a closed trajectory for the matrix path ( 10 ) provide. Tool ( 2 . 28 ) according to one of the preceding claims, wherein the doffer roller ( 6 ) in the direction of the template path ( 10 ) behind the pressure roller ( 4 ) is arranged. Tool ( 2 . 28 ) according to claim 2, wherein the guide bodies ( 18 . 20 ) by holding means ( 21 . 22 . 23 ) on the frame elements ( 14 . 16 ) are arranged and wherein the retaining means ( 21 . 22 . 23 ) are arranged to set a distance between the frame elements ( 14 . 16 ) and the guiding bodies ( 18 . 20 ). Tool ( 2 . 28 ) according to one of the preceding claims, further comprising channel body ( 24 ) with a gutter, which at least partially to edges of the template web ( 10 ). Tool ( 2 . 28 ) according to claim 6, further comprising scrapers which are connected to the channel bodies ( 24 ) and thus on the tool ( 2 . 28 ) are positioned with the edges of the die path ( 10 ) are in contact. Tool ( 2 . 28 ) according to claims 2 and 7, wherein the gutters ( 24 ) on guide bodies ( 18 . 20 ) are arranged and the guide body ( 18 . 20 ) are the scrapers. Tool ( 2 . 28 ) according to claim 3, wherein the deflection roller ( 8th ) a guide groove ( 24 ) whose width is equal to the width of the elastic matrix web ( 10 ) is adjusted. Tool ( 2 . 28 ) according to one of the preceding claims, further comprising a tool frame ( 34 ), on which at least one first latching element ( 36 ) is arranged, which with at least one second latching element ( 38 ) on a frame element ( 14 . 16 ) corresponds such that the frame element ( 14 . 16 ) via a releasable latching connection on the tool ( 2 . 28 ) is attachable. Tool ( 2 . 28 ) according to one of the preceding claims, further comprising a metering device ( 32 ) for adjusting the layer thickness of the coating material on the die path ( 10 ). Tool ( 2 . 28 ) according to claim 11, wherein the metering device ( 32 ) is a metering blade. Tool ( 2 . 28 ) according to claim 12, further comprising on one of the metering doctor blade ( 32 ) opposite side of the template path ( 10 ) arranged pressure means ( 30 ), which is adapted to the die path ( 10 ) to the metering device ( 32 ) to lead precisely.

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