Title of Invention	"ROLL-PATTERNED STRIP METAL STRIP OR SHEET FOR WINDOW COVERING ASSEMBLIES"
Abstract	A decorative roll-patterned metal strip or sheet, preferably aluminium strip or sheet, having: a thickness of about 0.05 -1.0 mm, preferably about 0.1 - 0.8 mm, with a surface having a plurality of indentations of a depth of about .001 - 0.05 mm, preferably about 0.02 -0.035 mm, and optionally having a layer of a paint of a thickness of about 3 - 30 microns, preferably about 10-15 microns, on the surface and within its indentations, the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of about 1: 5 to about 1: 100.

Title of Invention

"ROLL-PATTERNED STRIP METAL STRIP OR SHEET FOR WINDOW COVERING ASSEMBLIES"

Abstract

A decorative roll-patterned metal strip or sheet, preferably aluminium strip or sheet, having: a thickness of about 0.05 -1.0 mm, preferably about 0.1 - 0.8 mm, with a surface having a plurality of indentations of a depth of about .001 - 0.05 mm, preferably about 0.02 -0.035 mm, and optionally having a layer of a paint of a thickness of about 3 - 30 microns, preferably about 10-15 microns, on the surface and within its indentations, the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of about 1: 5 to about 1: 100.

Full Text	The present invention relates to roll-patterned metal strip or sheet, preferably aluminium strip or sheet and a process for making the strip. This invention relates to a process of roll-patterning and then painting a surface of a metal strip or sheet, particularly an aluminium strip or sheet used to form vanes or head or bottom rails for window covering assemblies, such as Venetian blinds, or to form architectural panels for ceilings or wall coverings. This invention particularly relates to a painted metal strip or sheet with a decorative pattern on at least one surface, made by the process, and to a window covering assemblies and architectural panels made from the strip or sheet. Elongated vanes or slats of the type used in horizontal and vertical blinds are well known and commercially available. Such slats are formed, for example, by continuous casting of aluminium strips or sheets, subsequent milling and, if necessary, cutting to width to provide coils of aluminium strips having the desired thickness and width. Subsequently, the strips or sheets are painted (optional), then roll-formed and cut into slats of the desired length. Likewise, it is well known to roll-form and cut such strips or sheets into head and bottom rails and architectural panels. Since window coverings and architectural products are frequently decorative, different colours and laminated or painted patterns are often provided on their exterior surfaces, particularly on the visible surfaces of slats and head and bottom rails of window coverings. In this regard, coiled strip, used to make blind slats, is normally covered with paint or lacquer in a coil-coating process in order to give it a decorative pattern before it is roll-formed into slats. A pattern can then be rolled into the painted strip surface, so that the resulting indentations in the strip surfacejjjve it a fabric-like appearance. An example of a process and apparatus for providing such a pattern in a painted strip surface for foldable metal drape panels for vertical blinds is described in US patent 4,362,039 (Toti). In the process of his patent, a rotary die is used to produce continuous patterns of scribe lines in painted surfaces of stripsyThe scribe lines assist in subsequently forming a preselected cross-sectional profile of the metal drape panels. Another rotary die is used for subsequently forming patterns of embossments in the strips between the scribe lines, in order to begin to stretch and work the metal between the scribe lines, so as to make it easier thereafter to form a weave pattern. Two additional rotary cutting die stations then cut the male and female hinges of the drape panel, and then, a rotary weave die station produces weave patterns between the scribe lines. The weave patterns comprise relatively deep cuts which slice through the metal at the edges of the pattern and provide a raised area which imitates the ins and outs of woven threads of cloth. Unfortunately, these cuts tend to damage the paint on the strip surface and can result in premature corrosion of the metal. US patent 4,499,938 (Toti) also describes a process and apparatus for making a metal blind slat by providing a relatively deeply embossed rib pattern in a painted strip material. The depth of the pattern is described as 0.015 inch ( 0.381 mm) in a strip of 0.008 - 0.010 inch (0.20 - 0.254 mm) thickness. This means that the depth of the pattern is more than the thickness of the strip., and so, the strip has been corrugated. Unfortunately, such an embossed pattern also inevitably tends to damage the paint on the strip and produce premature corrosion of the metal. In accordance with this invention, a decorative roll-patterned metal strip or sheet, preferably an aluminium strip or sheet, is provided that has a thickness of about 0.05 -1.0 mm, preferably about 0.1 - 0.8 mm, with a surface having a plurality of indentations of a depth of about 0.00l - 0.05 mm, preferably about 0.02 - 0.035 mm, and optionally having a layer of a paint of a thickness of about 3-30 microns, preferably about 10-15 microns, on the surface and within its indentations; the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of about 1: 5 to about 1: 100. Preferably, the indentations form a pattern which covers substantially the entire surface of the strip or sheet and which is visible to the naked eye, even though the paint is within and atop the indentations. Also in accordance with this invention, a process is provided for making the desesafc^e roll-patterned metal strip, comprising the steps of: - cold-rolling a metal strip or sheet, preferably an aluminum strip or sheet, at a temperature of about 40 - 175*C to reduce the thickness of the strip or sheet by about 15-40 %, preferably about 20 - 30 %, to about 0.05 - 1.0 mm, preferably about 0.1 - 0.8 mm, using a milling roll with a surface pattern thereon, to form a roll-patterned strip or sheet having, in a surface, a plurality of indentations corresponding to the surface pattern of the milling roll and with a depth of aboutO.OOl - 0.05 mm, preferably 0.02 -0.035 mm; the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of about 1: 5 to about 1: 100; and then optionally - painting the surface of the roll-patterned strip or sheet with a thickness of about 3-30 microns, preferably about 10-15 microns, of paint on the surface and within its indentations. Preferably, the cold-rolling step using the milling roll with the surface pattern is carried out in a last stand of a multi-stand cold-roll mill, and only the last stand has at least one of its milling rolls with the surface pattern. Subsequent painting of the strip or sheet is preferably carried out in a separate machine for coil-coating. Further in accordance with this invention are provided vanes and head and bottom rails for window covering assemblies, such as Venetian blinds, and architectural panels for ceilings or wall coverings made from the decorative roll-patterned strip or sheet of the invention. Therefore, the present invention relates to a roll-patterned metal strip or sheet for use in window covering assemblies, having: a thickness of 0.05 -1.0 mm, with a surface having a plurality of indentations of a depth of 0.001 -0.05 mm, and optionally having a layer of a paint of a thickness of 3 - 30 microns, on the surface and within its indentations; the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of 1: 5 to 1: 100. The invention further relates to a process for making the strip as described hereinabove, comprising the steps of: cold-rolling a metal strip or sheet, preferably an aluminum strip or sheet, at a temperature of 40 - 175°C to reduce the thickness of the strip or sheet by 15 -40 %, preferably 20-30 %, to 0.05-1.0 mm, preferably 0.1 -0.8 mm, using a milling roll with a surface pattern thereon, to form a roll-patterned strip or sheet having, in a surface, a plurality of indentations corresponding to the surface pattern of the milling roll and with a depth of 0.001-0.05 mm, preferably 0.02-0.035 mm; the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of 1: 5 to 1: 100; and then optionally painting the surface of the roll-patterned strip or sheet with a thickness of 3 -30 microns, preferably 10-15 microns, of paint on the surface and within its indentations. BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS Further aspects of the invention will be apparent from the detailed description below of particular embodiments and the drawings thereof, in which: Figure 1 shows a multi-stand cold roll mill, in which the last mill stand is a cold pattern-rolling mill stand in accordance with the invention. -Figure 2 is a schematic top view of the rolling mill of Figure 1, showing the roll-patterned strip leaving the last mill stand. -Figures 3 A - 3C are schematic views of the last two stands of the rolling mill of Figure 1, showing the use of different patterning roll(s) at the last mill stand. - Figure 4 is a schematic cross-section of a strip of the invention, which is roll-patterned on both sides. -Figures 5 A - 5E show different examples of roll-patterns of the invention. Figure 1 shows a five-stand cold roll reducing mill 1 for milling and roll-patterning a strip or sheet, such as an aluminium strip 2, in accordance with this invention. The strip 2 enters the mill 1 still in a ductile state following conventional heating and quenching steps. The five stands 3,5, 7, 9 and 11 of the mill 1 sequentially reduce the thickness of the aluminium strip 2 in a conventional manner by simultaneously pressing with opposed top and bottom, steel, milling or working rolls, generally 13 and 15, on the top and bottom surfaces 17 and 19 of the strip 2. However, the last stand 11 has one or both of its top and bottom, milling rolls 13A and 15A with patterned surfaces in contact with the strip 2 to provide roll-patterned indentations 21 in one or both of the adjacent surfaces 17 and 19 of the strip 2. During the cold rolling steps in stands 3-11, the temperature of the strip 2 is generally 40 -175ºC, preferably 75 - 120ºC. The thickness of the strip 2 is preferably reduced in the last stand 11 by 15 - 40 %, preferably 20 -30%, to a thickness of 0.05 -1.0 mm, preferably 0.1 - 0.8 mm., especially 0.1 - 0.3 mm for making slats and 0.4 -0.7 for making head or bottom rails. At the same time, the top surface 17, the bottom surface 19 or both of the strip 2 are roll-patterned by the patterned surface of the adjacent top and/or bottom, milling rolls 13A and 15A of the last stand 11 as shown in Figures 3A -3C. Preferably, the strip 2 is still in a ductile state when it reaches the last cold roll stand 11 so that it is easier to roll-pattern the surface of the strip to provide a plurality of indentations 21 therein to a depth of OOl -0.05mm, preferably 0.02 - 0.035 mm, with the ratio of the depth of the indentations 21 to the thickness of the strip 2 being in the range of 1: 5 to 1: 100. By the term "depth of indentations" is meant the depth of the indentations 21 in the strip 2 relative to the mean thickness of the strip 2 after roll-pressing in accordance with this invention. Preferably, the ratio of the depth of the indentations 21 to the thickness of the roll-patterned strip 2 is no more than 1:10, particularly no more than 1: 16, and no less than 1: 50, particularly no less than 1 : 40. The roll-patterning of this invention does not corrugate the strip 2 but takes place only on its surface, so that the so-formed indentations 21 are accommodated entirely within the thickness of the strip. In accordance with the invention, a pattern C on the surface of either the top or bottom, milling roll ISA or ISA of the last stand 11 can be rolled only into the adjacent top or bottom surface 17 or 19 of the strip 2 (Figure 3A). This is often preferred for a strip 2 that is later to be roll-formed in a conventional manner into head or bottom rails for window covering assemblies or into architectural panels. Likewise, a pattern C on the surface of both the top and bottom, milling rolls 13A and 15A of the last stand 11 can be rolled simultaneously into both the adjacent top and bottom surfaces 17 and 19 of the strip 2 (Figure 3B). This is often preferred for a strip 2 that is later to be roll-formed into horizontal or vertical slats for window covering assemblies which have both sides visible in use. Similarly, a pattern C on the surface of top milling roll 13A of the last stand 11 can be rolled into the adjacent top surface 17 of the strip 2, and a different pattern D on the surface of the bottom milling roll ISA of the last stand 11 can simultaneously be rolled into the adjacent bottom surface 19 of the strip 2 (Figure 3C). Figure 2 shows the five-stand cold roll reducing mill 1 from above. The strip 2 enters at stand 3 and is milled through stands 3-11. The last stand 11 is the cold mill stand with one or two patterned milling rolls 13A and/or 15A. Strip 2 exits stand 11 with pattern C from the patterned rolls on its surface and is then led to roll-up stand 23. Figure 3 A shows cold mill stand 9 and its pair of conventional milling rolls 13 and 15 and cold mill stand 11 and its pair of a top milling roll 13A with pattern C on its surface and a conventional bottom milling roll 15. The thickness of strip 2 is reduced in stand 11, and it exits stand 11 with the pattern C on its top surface 17. Likewise, Figure 3B shows cold mill stand 9 and its pair of conventional milling rolls 13 and 15 and cold mill stand 11 and its pair of a top milling roll 13A and bottom milling roll 15A, both with pattern C on their surfaces. The thickness of strip 2 is reduced in stand 11, and it exits stand 11 with the pattern C on its top and bottom surfaces 17 and 19. Likewise, Figure 3C shows cold mill stand 9 and its pair of conventional milling rolls 13 and 15 and cold mill stand 11 and its pair of a top milling roll 13A with pattern C on its surface and a bottom milling roll 15A with pattern D on its surface. The thickness of strip 2 is reduced in stand 11, and it exits stand 11 with the pattern C on its top surface 17 and the pattern D on its bottom surface 19. Figure 4 is a cross-section of a roll-patterned strip 2 of this invention as made, for example, in the mill stand 11 of Figure 3 A. Figure 4 shows that the cold roll-patterning process, carried out in mill stand 11, does not corrugate the strip 2. Strip 2, has pattern C on the top surface 17 and a different pattern D on the bottom surface 19. The depth of the indentations 21 of each roll-pattern C and D is between 0.001 and 0.05 mm and preferably between 0.02 and 0.035 mm. As a result, each surface 17 and 19 can be painted, using conventional coating rollers and heat-curing techniques of coil-coating processes, without losing the appearance of its roll-pattern C or D. Figures 5 A -5E show examples of some of the different roll-patterns that can be provided on the surface(s) of strip 2. In fact, there is an endless variety of possible patterns. Changing the pattern simply entails putting in a differently patterned milling roll 13A or 15A in the last stand 11 of the cold rolling multi-stand mill 1. Figure 5A shows a lattice-like pattern. Figure 5B shows a fish-grate wavy like pattern. Figures 5C and 5E show lettering patterns. Figure 5D shows a figurine-like pattern. After roll-patterning, the strip 2 can be rolled up in a conventional manner on roll 23 and allowed to cool. The roll-patterned surface(s) 17 and or 19 of the strip 2 can then be painted in a conventional manner with a thickness of 3 - 30 microns, preferably 10-15 microns, of paint on the surface(s) and within the indentations 21. In this regard, each roll-patterned surface 17 and/or 19 of the strip 2 can be passed over a conventional paint applicator roller as described in the patent publications: EP 0070 705 and U.S. 3068119. Finally, the painted strip 2 can be roll-formed in a conventional manner to form elongated horizontal or vertical slats or head or bottom rails for window covering assemblies, such as Venetian blinds, or to form architectural panels for ceilings or wall coverings. In this regard, the painted and roll-patterned 2 can be passed between conventional forming rolls as described in the patent publications: U.S. 4 173 879, U.S. 4 145 905, U.S. 3 26724, U.S. 2 692 003, U.S. 2518 846, U.S. 2 471 490, U.S. 2 346 990 and, U.S.2313 111. This invention is, of course, not limited to the above-described embodiments which may be modified without departing from the scope of the invention or sacrificing all of its advantages. In this regard, the terms in the foregoing description and the following claims, such as "horizontal", "vertical", "top" and "bottom", have been used only as relative terms to describe the relationships of the various elements of the cold roll reducing mill 1 of the invention. WE CLAIM: 1. A roll-patterned metal strip or sheet for use in window covering assemblies, having: a thickness of 0.05 -1.0 mm, with a surface having a plurality of indentations of a depth of 0.001 -0.05 mm, and optionally having a layer of a paint of a thickness of 3 - 30 microns, on the surface and within its indentations; the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of 1: 5 to 1: 100. 2. The strip or sheet as claimed in claim 1, wherein the indentations form a pattern which covers the entire surface of the strip or sheet. 3. A roll-patterned metal strip or sheet substantially as herein described with reference to the accompanying drawings.

Full Text

The present invention relates to roll-patterned metal strip or sheet, preferably aluminium strip or sheet and a process for making the strip.
This invention relates to a process of roll-patterning and then painting a surface of a metal strip or sheet, particularly an aluminium strip or sheet used to form vanes or head or bottom rails for window covering assemblies, such as Venetian blinds, or to form architectural panels for ceilings or wall coverings. This invention particularly relates to a painted metal strip or sheet with a decorative pattern on at least one surface, made by the process, and to a window covering assemblies and architectural panels made from the strip or sheet.
Elongated vanes or slats of the type used in horizontal and vertical blinds are well known and commercially available. Such slats are formed, for example, by continuous casting of aluminium strips or sheets, subsequent milling and, if necessary, cutting to width to provide coils of aluminium strips having the desired thickness and width. Subsequently, the strips or sheets are painted (optional), then roll-formed and cut into slats of the desired length. Likewise, it is well known to roll-form and cut such strips or sheets into head and bottom rails and architectural panels.
Since window coverings and architectural products are frequently

decorative, different colours and laminated or painted patterns are often provided on their exterior surfaces, particularly on the visible surfaces of slats and head and bottom rails of window coverings. In this regard, coiled strip, used to make blind slats, is normally covered with paint or lacquer in a coil-coating process in order to give it a decorative pattern before it is roll-formed into slats.
A pattern can then be rolled into the painted strip surface, so that the resulting indentations in the strip surfacejjjve it a fabric-like appearance. An example of a process and apparatus for providing such a pattern in a painted strip surface for foldable metal drape panels for vertical blinds is described in US patent 4,362,039 (Toti). In the process of his patent, a rotary die is used to produce continuous patterns of scribe lines in painted surfaces of stripsyThe scribe lines assist in subsequently forming a preselected cross-sectional profile of the metal drape panels. Another rotary die is used for subsequently forming patterns of embossments in the strips between the scribe lines, in order to begin to stretch and work the metal between the scribe lines, so as to make it easier thereafter to form a weave pattern. Two additional rotary cutting die stations then cut the male and female hinges of the drape panel, and then, a rotary weave die station

produces weave patterns between the scribe lines. The weave patterns comprise relatively deep cuts which slice through the metal at the edges of the pattern and provide a raised area which imitates the ins and outs of woven threads of cloth. Unfortunately, these cuts tend to damage the paint on the strip surface and can result in premature corrosion of the metal.
US patent 4,499,938 (Toti) also describes a process and apparatus for making a metal blind slat by providing a relatively deeply embossed rib pattern in a painted strip material. The depth of the pattern is described as 0.015 inch ( 0.381 mm) in a strip of 0.008 - 0.010 inch (0.20 - 0.254 mm) thickness. This means that the depth of the pattern is more than the thickness of the strip., and so, the strip has been corrugated. Unfortunately, such an embossed pattern also inevitably tends to damage the paint on the strip and produce premature corrosion of the metal.
In accordance with this invention, a decorative roll-patterned metal strip or sheet, preferably an aluminium strip or sheet, is provided that has a thickness of about 0.05 -1.0 mm, preferably about 0.1 - 0.8 mm, with a surface having a plurality of indentations of a depth of about 0.00l - 0.05 mm, preferably about 0.02 - 0.035 mm, and optionally having a layer of a paint of a thickness of about 3-30 microns, preferably about 10-15

microns, on the surface and within its indentations; the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of about 1: 5 to about 1: 100. Preferably, the indentations form a pattern which covers substantially the entire surface of the strip or sheet and which is visible to the naked eye, even though the paint is within and atop the indentations.
Also in accordance with this invention, a process is provided for making the desesafc^e roll-patterned metal strip, comprising the steps of: - cold-rolling a metal strip or sheet, preferably an aluminum strip or sheet, at a temperature of about 40 - 175*C to reduce the thickness of the strip or sheet by about 15-40 %, preferably about 20 - 30 %, to about 0.05 - 1.0 mm, preferably about 0.1 - 0.8 mm, using a milling roll with a surface pattern thereon, to form a roll-patterned strip or sheet having, in a surface, a plurality of indentations corresponding to the surface pattern of the milling roll and with a depth of aboutO.OOl - 0.05 mm, preferably 0.02 -0.035 mm; the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of about

1: 5 to about 1: 100; and then optionally - painting the surface of the roll-patterned strip or sheet with a thickness of about 3-30 microns, preferably about 10-15 microns, of paint on the surface and within its indentations. Preferably, the cold-rolling step using the milling roll with the surface pattern is carried out in a last stand of a multi-stand cold-roll mill, and only the last stand has at least one of its milling rolls with the surface pattern. Subsequent painting of the strip or sheet is preferably carried out in a separate machine for coil-coating.
Further in accordance with this invention are provided vanes and head and bottom rails for window covering assemblies, such as Venetian blinds, and architectural panels for ceilings or wall coverings made from the decorative roll-patterned strip or sheet of the invention.

Therefore, the present invention relates to a roll-patterned metal strip or sheet for use in window covering assemblies, having: a thickness of 0.05 -1.0 mm, with a surface having a plurality of indentations of a depth of 0.001 -0.05 mm, and optionally having a layer of a paint of a thickness of 3 - 30 microns, on the surface and within its indentations; the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of 1: 5 to 1: 100.
The invention further relates to a process for making the strip as described hereinabove, comprising the steps of:
cold-rolling a metal strip or sheet, preferably an aluminum strip or sheet, at a temperature of 40 - 175°C to reduce the thickness of the strip or sheet by 15 -40 %, preferably 20-30 %, to 0.05-1.0 mm, preferably 0.1 -0.8 mm, using a milling roll with a surface pattern thereon, to form a roll-patterned strip or sheet having, in a surface, a plurality of indentations corresponding to the surface pattern of the milling roll and with a depth of 0.001-0.05 mm, preferably 0.02-0.035 mm; the ratio of the depth of the indentations to the thickness of the strip or sheet being in the range of 1: 5 to 1: 100; and then optionally painting the surface of the roll-patterned strip or sheet with a thickness of 3 -30 microns, preferably 10-15 microns, of paint on the surface and within its indentations.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS Further aspects of the invention will be apparent from the detailed description below of particular embodiments and the drawings thereof, in which:
Figure 1 shows a multi-stand cold roll mill, in which the last mill stand is a cold pattern-rolling mill stand in accordance with the invention.

-Figure 2 is a schematic top view of the rolling mill of
Figure 1, showing the roll-patterned strip leaving the last
mill stand.
-Figures 3 A - 3C are schematic views of the last two stands
of the rolling mill of Figure 1, showing the use of different
patterning roll(s) at the last mill stand.
- Figure 4 is a schematic cross-section of a strip of the
invention, which is roll-patterned on both sides.
-Figures 5 A - 5E show different examples of roll-patterns of
the invention.
Figure 1 shows a five-stand cold roll reducing mill 1 for milling and roll-patterning a strip or sheet, such as an aluminium strip 2, in accordance with this invention. The strip 2 enters the mill 1 still in a ductile state following conventional heating and quenching steps. The five stands 3,5, 7, 9 and 11 of the mill 1 sequentially reduce the thickness of the aluminium strip 2 in a conventional manner by simultaneously pressing with opposed top and bottom, steel, milling or working rolls, generally 13 and 15, on the top and bottom surfaces 17 and 19 of the strip 2. However, the last stand 11 has one or both of its top and bottom, milling rolls 13A and 15A with

patterned surfaces in contact with the strip 2 to provide roll-patterned indentations 21 in one or both of the adjacent surfaces 17 and 19 of the strip 2. During the cold rolling steps in stands 3-11, the temperature of the strip 2 is generally 40 -175ºC, preferably 75 - 120ºC.
The thickness of the strip 2 is preferably reduced in the last stand 11 by 15 - 40 %, preferably 20 -30%, to a thickness of 0.05 -1.0 mm, preferably 0.1 - 0.8 mm., especially 0.1 - 0.3 mm for making slats and 0.4 -0.7 for making head or bottom rails. At the same time, the top surface 17, the bottom surface 19 or both of the strip 2 are roll-patterned by the patterned surface of the adjacent top and/or bottom, milling rolls 13A and 15A of the last stand 11 as shown in Figures 3A -3C.
Preferably, the strip 2 is still in a ductile state when it reaches the last cold roll stand 11 so that it is easier to roll-pattern the surface of the strip to provide a plurality of indentations 21 therein to a depth of OOl -0.05mm, preferably 0.02 - 0.035 mm, with the ratio of the depth of the indentations 21 to the thickness of the strip 2 being in the range of 1: 5 to 1: 100. By the term "depth of indentations" is meant the depth of the indentations 21 in the strip 2 relative to the mean thickness of the strip 2 after roll-pressing in accordance with this invention. Preferably, the ratio of the depth of the

indentations 21 to the thickness of the roll-patterned strip 2 is no more than 1:10, particularly no more than 1: 16, and no less than 1: 50, particularly no less than 1 : 40. The roll-patterning of this invention does not corrugate the strip 2 but takes place only on its surface, so that the so-formed indentations 21 are accommodated entirely within the thickness of the strip. In accordance with the invention, a pattern C on the surface of either the top or bottom, milling roll ISA or ISA of the last stand 11 can be rolled only into the adjacent top or bottom surface 17 or 19 of the strip 2 (Figure 3A). This is often preferred for a strip 2 that is later to be roll-formed in a conventional manner into head or bottom rails for window covering assemblies or into architectural panels. Likewise, a pattern C on the surface of both the top and bottom, milling rolls 13A and 15A of the last stand 11 can be rolled simultaneously into both the adjacent top and bottom surfaces 17 and 19 of the strip 2 (Figure 3B). This is often preferred for a strip 2 that is later to be roll-formed into horizontal or vertical slats for window covering assemblies which have both sides visible in use. Similarly, a pattern C on the surface of top milling roll 13A of the last stand 11 can be rolled into the adjacent top surface 17 of the strip 2, and a different pattern D on the surface of the bottom milling roll ISA of

the last stand 11 can simultaneously be rolled into the adjacent bottom surface 19 of the strip 2 (Figure 3C).
Figure 2 shows the five-stand cold roll reducing mill 1 from above. The strip 2 enters at stand 3 and is milled through stands 3-11. The last stand 11 is the cold mill stand with one or two patterned milling rolls 13A and/or 15A. Strip 2 exits stand 11 with pattern C from the patterned rolls on its surface and is then led to roll-up stand 23.
Figure 3 A shows cold mill stand 9 and its pair of conventional milling rolls 13 and 15 and cold mill stand 11 and its pair of a top milling roll 13A with pattern C on its surface and a conventional bottom milling roll 15. The thickness of strip 2 is reduced in stand 11, and it exits stand 11 with the pattern C on its top surface 17.
Likewise, Figure 3B shows cold mill stand 9 and its pair of conventional milling rolls 13 and 15 and cold mill stand 11 and its pair of a top milling roll 13A and bottom milling roll 15A, both with pattern C on their surfaces. The thickness of strip 2 is reduced in stand 11, and it exits stand 11 with the pattern C on its top and bottom surfaces 17 and 19.
Likewise, Figure 3C shows cold mill stand 9 and its pair of conventional milling rolls 13 and 15 and cold mill stand 11 and its pair of

a top milling roll 13A with pattern C on its surface and a bottom milling roll 15A with pattern D on its surface. The thickness of strip 2 is reduced in stand 11, and it exits stand 11 with the pattern C on its top surface 17 and the pattern D on its bottom surface 19.
Figure 4 is a cross-section of a roll-patterned strip 2 of this invention as made, for example, in the mill stand 11 of Figure 3 A. Figure 4 shows that the cold roll-patterning process, carried out in mill stand 11, does not corrugate the strip 2. Strip 2, has pattern C on the top surface 17 and a different pattern D on the bottom surface 19. The depth of the indentations 21 of each roll-pattern C and D is between 0.001 and 0.05 mm and preferably between 0.02 and 0.035 mm. As a result, each surface 17 and 19 can be painted, using conventional coating rollers and heat-curing techniques of coil-coating processes, without losing the appearance of its roll-pattern C or D.
Figures 5 A -5E show examples of some of the different roll-patterns that can be provided on the surface(s) of strip 2. In fact, there is an endless variety of possible patterns. Changing the pattern simply entails putting in a differently patterned milling roll 13A or 15A in the last stand 11 of the cold rolling multi-stand mill 1. Figure 5A shows a lattice-like pattern.

Figure 5B shows a fish-grate wavy like pattern. Figures 5C and 5E show lettering patterns. Figure 5D shows a figurine-like pattern.
After roll-patterning, the strip 2 can be rolled up in a conventional manner on roll 23 and allowed to cool. The roll-patterned surface(s) 17 and or 19 of the strip 2 can then be painted in a conventional manner with a thickness of 3 - 30 microns, preferably 10-15 microns, of paint on the surface(s) and within the indentations 21. In this regard, each roll-patterned surface 17 and/or 19 of the strip 2 can be passed over a conventional paint applicator roller as described in the patent publications: EP 0070 705 and U.S. 3068119.
Finally, the painted strip 2 can be roll-formed in a conventional manner to form elongated horizontal or vertical slats or head or bottom rails for window covering assemblies, such as Venetian blinds, or to form architectural panels for ceilings or wall coverings. In this regard, the painted and roll-patterned 2 can be passed between conventional forming rolls as described in the patent publications: U.S. 4 173 879, U.S. 4 145 905, U.S. 3 26724, U.S. 2 692 003, U.S. 2518 846, U.S. 2 471 490, U.S. 2 346 990 and, U.S.2313 111.
This invention is, of course, not limited to the above-described

embodiments which may be modified without departing from the scope of the invention or sacrificing all of its advantages. In this regard, the terms in the foregoing description and the following claims, such as "horizontal", "vertical", "top" and "bottom", have been used only as relative terms to describe the relationships of the various elements of the cold roll reducing mill 1 of the invention.

WE CLAIM:
1. A roll-patterned metal strip or sheet for use in window covering
assemblies, having: a thickness of 0.05 -1.0 mm, with a surface
having a plurality of indentations of a depth of 0.001 -0.05 mm, and
optionally having a layer of a paint of a thickness of 3 - 30 microns,
on the surface and within its indentations; the ratio of the depth of
the indentations to the thickness of the strip or sheet being in the
range of 1: 5 to 1: 100.
2. The strip or sheet as claimed in claim 1, wherein the indentations
form a pattern which covers the entire surface of the strip or sheet.
3. A roll-patterned metal strip or sheet substantially as herein described
with reference to the accompanying drawings.

Documents:

719-del-1999-abstract.pdf

719-del-1999-claims.pdf

719-del-1999-correspondence-others.pdf

719-del-1999-correspondence-po.pdf

719-del-1999-description (complete).pdf

719-del-1999-drawings.pdf

719-del-1999-form-1.pdf

719-del-1999-form-13.pdf

719-del-1999-form-19.pdf

719-del-1999-form-2.pdf

719-del-1999-form-3.pdf

719-del-1999-form-4.pdf

719-del-1999-gpa.pdf

719-del-1999-petition-137.pdf

719-del-1999-petition-138.pdf

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Patent Number

216938

Indian Patent Application Number

719/DEL/1999

PG Journal Number

13/2008

Publication Date

31-Mar-2008

Grant Date

20-Mar-2008

Date of Filing

12-May-1999

Name of Patentee

HUNTER DOUGLAS INTERNATIONAL N.V.,

Applicant Address

P O BOX 3623, CARACASBAAIWEG 40, CURACAO, NETHERLANDS ANTILLES.

Inventors:

#	Inventor's Name	Inventor's Address
1	FRANS R ESCHAUZIER	SUITE 24, 3335 EB ZWIJNDRECHT, NETHERLAND.

PCT International Classification Number

B32B 3/00

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1			NA