Patent Grant
10889920
This patent application is the national phase of PCT/EP2018/068369, filed Jul. 6, 2018, which claims the benefit of European Patent Application 17180271.3, filed Jul. 7, 2017.
The invention relates to a reed and a method for producing a reed. A reed comprises a plurality of dents arranged parallel to each other. Two directly adjacent dents limit an interspace respectively through which one warp thread is guided respectively. The dents serve to keep the warp threads at a defined distance relative to each other. In order to be able to manufacture a regular woven textile, it is necessary that all directly adjacent dents have the same distance to each other.
In order to predefine the distance of dents of a reed during assembly, it is known from FR 1 146 831 A to bend the dent in its two end sections a plurality of times, such that a serration-shaped dent section is created. The serration-shaped sections of adjacent dents are offset from each other in a longitudinal direction in which the dent extends. An adjacent dent abuts at a serration of a dent, such that the distance or the width of the interspace between two dents is defined.
Dents of a reed formed like this are also disclosed in U.S. Pat. No. 2,152,430 A. Additionally, a further embodiment of dents is shown there in which an end section is bent about 180° and the bent portion is shaped to a projection at which the respective adjacent dent abuts.
U.S. Pat. No. 2,147,258 A describes dents of a reed that are provided with two parallel slits in an end section in its extension direction, such that three webs are created in this way. The middle web is formed to project in one direction and the two outer webs are formed to project in the other direction from the plane of the dent. In doing so, spacer projections are formed at which directly adjacent dents are in contact. Such dents are also known from DE 2 508 575 A.
EP 0 943 712 A1 and U.S. Pat. No. 4,529,014 describe a reed in which the end sections of the dents are configured with increased thickness compared with the middle working section of the dents and abut each other. In doing so, a defined distance between the working sections of the dents is achieved.
The dents of a reed known from DE 1 535 830 A are provided with a through-hole through which a string rail extends. The dents are bent about 180° adjoining the through-hole. The thickness of the bent areas defines the distance between two directly adjacent dents that abut each other.
GB 1 245 872 A describes an embodiment of a reed with the goal to increase the distance between two parallel planes that contact a dent on opposite sides without the need to increase the width of the dent. This shall be achieved by configuring the cross-section profile of the dent in a curved or bent manner. One plane abuts at a middle area of the convex side, whereas the other plane abuts at the two outer areas of the cross-section of the dent at the concave side. The larger the bend or the curvature of the cross-section profile is, the larger the distance becomes between these two planes.
Starting from the prior art it can be considered as object of the present invention to provide a reed that guarantees a constant distance between adjacent warp threads.
This object is solved by a reed as well as a method for producing the reed as disclosed herein.
The inventive reed comprises multiple dents that extend in a longitudinal direction between a first end and an opposite second end. Each dent has an end section directly adjoining the first end as well as directly adjoining the second end respectively. The two end sections limit a working section that extends between the end sections. The working section of the reed serves for guiding the warp threads, whereas the end section is configured to fix the dents with each other or at a carrier of the reed respectively. The working section of each dent comprises two opposite dent outer surfaces. Each dent outer surface extends in a plane that is spanned by the longitudinal direction and a transverse direction that is orientated orthogonal to the longitudinal direction. The warp threads extend between two dent outer surfaces of two directly adjacent dents through the reed. Depending on the position of the weaving shaft, a warp thread can extend in transverse direction or inclined to the transverse direction.
Thus, each dent has a first dent outer surface that extends in a first plane and a second dent outer surface that extends in a second plane. The two planes are orientated parallel to each other and define the thickness of the dent in the working section. The dent outer surfaces are preferably rectangularly shaped and extend in length direction between the two end sections and in transverse direction between a front edge and a back edge of the dent.
In at least one end section of multiple and preferably all dents, a plurality of spacer studs is present. The spacer studs are particularly produced by an embossing process. It is preferred, if the dent comprises spacer studs in both end sections. The spacer studs are deepened at a first side relative to the first plane and are raised at the opposite second side relative to the second plane. Thus, each spacer stud forms a depression at the first side relative to the first plane and a projection at the second side relative to the second plane. The spacer studs are distributed in an end section and preferably arranged with distance to each other. The arrangement of the spacer studs in an end section is preferably carried out according to a regular pattern.
At the first side the spacer studs have a stud inner surface that adjoins the first plane and that forms a concave depression relative to the first plane. At the second side the studs have a stud outer surface that adjoins the second plane and that forms a convex projection relative to the second plane. The sum of all stud outer surfaces of all of the spacer studs that are arranged in a common end section has an amount of at most 15%, preferably at most 10% and further preferably at most 8% of the total end section surface in this end section. The total end section surface is defined by the sum of a surface area ratio of the end section that extends in the second plane in addition to the sum of all stud outer surfaces. Thus, the surface area section of the end section surface that extends in the second plane has an amount of at least 85%, preferably at least 90% and further preferably at least 92% of the total end section surface.
The spacer studs are configured to define a minimum distance between two adjacent dents in the reed. If a dent abuts against the spacer studs of the adjacent dent, the minimum distance between the working sections of the dents corresponds to the height of the spacer dent at the second side relative to the second plane. If the dents are glued to each other during the production of the reed, adhesive is inserted between the end section of the dents arranged adjacent to each other. Due to capillary forces, deformations of the end sections or the dent can occur. Because not all interspaces between end sections can be simultaneously filled with adhesive, irregular distances between the dents can be created due to the capillary forces or deformations of the dents can occur. Such deformations of the dents are limited by means of the spacer studs. Additionally, the spacer studs provide a minimum distance between two dents. Due to the fact that the spacer studs comprise a sufficiently small portion of the total stud outer surface relative to the total end section area, the capillary effect is not additionally enhanced. It has shown that due to spacer studs having a sufficiently small area proportion within the respective end section, an improved regularity of the dent distances compared with previous solutions can be achieved. The spacer studs can be simply and efficiently created due to an embossing process when producing the reed.
It is advantageous, if the percentage of the total stud inner surface of all spacer studs in a common end section at its first side has an amount of at most 15%, preferably at most 10% and further preferably at most 8% of the total end section area at this side. The total end section area at the first side is equal to the sum of the surface area section of the end section that extends in the first plane as well as the sum of all stud inner surfaces of the present spacer studs.
The spacer studs are preferably free of through-holes. They are, for example, created by means of a forming process. A separation process, like cutting or punching is not envisaged. It is also preferred, if the end sections in total are configured in a manner to be free of through-holes.
The reed comprises two lateral outer dents and a plurality of intermediate dents that are arranged between the lateral outer dents in a width direction, orthogonal to the first plane and the second plane, in which the dents are arranged in a row side by side. It is preferred, if at least all intermediate dents comprise spacer studs in one or both end sections respectively. Preferably at least one of the two lateral outer dents comprises spacer studs in at least one end section as well. In one embodiment it is provided that all of the dents comprise a plurality of spacer studs in one or both end sections respectively. In this embodiment all of the dents can be identically configured.
In a preferred embodiment at least three, preferably at least five to ten spacer studs are provided in one end section.
In a preferred embodiment each spacer stud has a central stud portion. The central stud portion is preferably rotationally symmetrically configured and can, e.g. have a cylindrical or truncated conically or ball scraper shaped form. Additionally, each spacer stud can comprise an outer stud portion that completely surrounds the central stud portion. In one embodiment the outer stud portion can be conically configured. The cone angle relative to the first or second plane is acute and has an amount of at most 10° or at most 5° or at most 3°.
The spacer studs of directly adjacently arranged end sections of the dents can be aligned with each other in one embodiment, i.e. all of the spacer studs of adjacent end sections are arranged along multiple straight lines that extend orthogonal to the first or second plane. Alternatively hereto the spacer studs of directly adjacent end sections respectively can also be arranged offset parallel to the first plane or the second plane, such that they are not aligned.
The spacer studs have a height or maximum height from the second plane that is preferably substantially equal to the distance between the first plane and the second plane, this means equal to the thickness or width of the dent. The height can have an amount of 0.8 multiple to the 1.2 multiple of the thickness of the dent.
In one embodiment the spacer studs have a diameter that is 5-10 times as large as the height.
It is preferred, if all of the spacer studs have the same diameter and the same height. It is further preferred, if all of the spacer studs have the same form or outer shape respectively.
In the arrangement in the reed directly adjacent dents have a dent spacing from each other that corresponds at least to the height of the spacer studs and is preferably at most 5% or at most 2% larger than the height of the spacer studs. Directly adjacent dents can abut with each other at the spacer studs or can be arranged without contact side by side.
For producing the reed the dents are subsequently supplied to an assembly station. Before the assembly station is reached at least one or multiple and preferably all of the dents are embossed in the end sections in order to create the spacer studs. It is also possible to emboss the dents in a separate embossment station and to supply them to a separate assembly station subsequently. In the assembly device or assembly station all of the dents are positioned with defined distance to each other, wherein the distance corresponds at least to the height of the spacer studs. In doing so, the dents can be preliminarily attached to each other in the desired relative position by means of a wire. Subsequently an adhesive bond between the respective adjacent end sections of the dents is created. For example, the dents can be glued with each other and with a carrier of the reed. The wire for preliminary fixing of the dents can be removed after curing of the adhesive bond.
Preferred embodiments of the invention are derived from the dependent claims, the description as well as the drawings. In the following preferred embodiments of the invention are explained in detail with reference to the attached drawings. The drawings show:
A reed 15 is schematically illustrated in
Each of the dents 16 has a first dent outer surface A1 in the working section 20 and on the opposite side in the working section 20 a second dent outer surface A2 (
The dents 16 of the reed 15 are arranged in a width direction B involving the formation of defined interspaces 25 between the working sections 20 of directly adjacent dents 16. In the width direction B the interspaces 25 have the same size. The interspaces 25 serve to guide warp threads 26 in the width direction B and to preset the distance between the warp threads 26 in width direction B and to keep it constant. As shown in
An ideal desired orientation of the dents 16 is schematically illustrated in
In order to counteract this, some or preferably all dents 16 have multiple spacer studs 30 in one and according to the example in both end sections 19 respectively. According to the example, in one end section 19 at least three and preferably five to ten spacer studs 30 are present. The working section 20 is free of spacer studs 30 and other depressions or elevations at the dent 16. The end section 19 adjoining the first end 17 ends at the location at which a spacer stud 30 is located that has the largest distance to the first end 17. The end section 19 adjoining the second end 18 ends at the location at which a spacer stud 30 is located that has the largest distance to the second end 18. At this location with the largest distance of a spacer stud from the first end 17 or the second end 18 a straight line G is drawn in transverse direction Q parallel to the respective edge of the first end 17 or the second end 18 respectively that forms the end of the respective end section 19 (
In the preferred embodiment the spacer studs 30 are created by embossing. They are deepened relative to the first plane E1 at a first side S1 and are elevated at an opposite second side S2 relative to the second plane E2. A preferred embodiment of the spacer studs 30 is shown in cross-section in
The second side S2 of the spacer studs 30 is located at the side of the dent 16 at which the second dent outer surface A2 adjoins in the working section 20. Accordingly, the first side S1 of the spacer studs 30 is located at the side of the dent 16 at which the working section 20 has its first dent outer surface A1 (
The number and size of the spacer studs 30 in one single end section 19 is selected, such that the sum of all stud outer surfaces F compared with the total end section area of this end section 19 on the second side S2 has an amount of at most 15% or at most 10% or at most 8%. The total end section area on the second side S2 is the area that is formed by the surface area section of the end section extending in the second plane E2 in addition to the sum of the stud outer surfaces F. Additionally or alternatively, the percentage of the sum of all stud inner surfaces I in one common end section 19 has an amount of at most 15% or at most 10% or at most 8% of the total end section area on the first side S1. The total end section area on the first side S1 is the area of the end section 19 resulting from the sum of all of the stud inner surfaces I of all of the spacer studs 30 in this end section 19 in addition to the surface area section of the end section 19 that extends in the first plane E1.
In the herein preferred embodiment all of the spacer studs 30 of a common end section 19 or a dent 16 and preferably all of the dents 16 are configured identically. In doing so, the production of the spacer studs 30 or the dents 16 is simplified.
As it is apparent in
In the embodiment illustrated herein the central stud portion 31 has a central wall section 33 that extends substantially parallel to the second plane E2. This central wall section 33 can also be configured in a convex curved manner with view from the second side S2 onto the spacer stud 30. The central wall section 33 is, e.g. circular and connected with the outer stud portion 32 by a connection wall section 34. The connection wall section 34 has a conical shape and forms a hollow truncated cone. The connection wall section 34 extends the diameter of the central stud portion 31 from the central wall section 33 toward the outer stud portion 32. If the central wall section 33 has the shape of a ball scraper or another convex curved form, the connection wall section 34 can also be omitted.
The outer stud portion 32 is optional and can be omitted in a non-illustrated embodiment. In the preferred embodiment it serves to provide a spring effect to the spacer stud 30. For this the outer stud portion 32 has a conical shape and forms a hollow truncated cone. A cone angle α of the outer stud portion 32 measured between the first plane E1 and the stud inner surface I is very small and has an amount of less than 5° or less than 3° in the preferred embodiment. A cone angle of the connection wall section 34 is, however, larger and has an amount of preferably at least 30° or at least 40°.
As it is illustrated in
Starting from the second plane E2 the spacer stud 30 has a height H that defines the location with the largest distance to the second plane E2. In the embodiment described herein the height H is defined by that portion of the stud outer surface F that is located at the central wall section 33. This height H of the spacer stud 30 defines the minimum distance that two directly adjacent dents have in the area of their working sections 20. The height H corresponds preferably substantially to the thickness or width S of the dent 16. The width S of the dent 16 is defined by the distance between the first plane E1 and the second plane E2. In the embodiment described herein the diameter D of the spacer stud 30 has an amount of about 8 to 12 times and preferably 10 times of the height H. If the outer stud portion 32 is omitted in a not illustrated embodiment, the diameter D of the spacer stud 30 has an amount of about 4 times to 6 times and preferably 5 times of the height H.
As explained above, all of the dents 16 can comprise spacer studs 30 in both end sections 19 respectively. In order to guarantee the minimum distance between the dents 16 the provision of spacer studs 30 at all of the dents 16 is not necessarily required. As illustrated in
The number and position of the spacer studs 30 in an end section 19 can vary. Only by way of example two possibilities of arrangement are illustrated in
Method steps for producing the reed 15 are schematically illustrated in
Subsequently the embossed dents 16 are positioned and orientated relative to each other in an assembly station 43. In doing so, a dent spacing x is adjusted between directly adjacent dents 16 or their working sections 20 that is preferably slightly larger than the height H of the spacer studs. For example the height H of a spacer stud can have an amount of about 0.015 mm to 0.025 mm and the dent spacing x can be at most 10% or at most 5% larger than the height H of the spacer studs. In the non-aligned orientation of the spacer studs (
In the assembly station 43 the positioned and aligned dents 16 can be preliminarily attached to each other by means of a preferably flexible or bendable fixing means, such as a wire 44. In this preliminarily fixed condition the adhesive bond between the end sections 19 of the dents 16 arranged side by side to each other in width direction B and assigned to a common carrier 27 is created. In doing so, adhesive 28 flows in the gap between the adjacent end sections 19 and thus creates an adhesive bond. Because of the small spacer studs 30 in terms of their area, it is guaranteed that on one hand a minimum distance between the dents 16 is guaranteed and on the other hand capillary forces are kept sufficiently small. During the creation of the adhesive bond between the dents 16 also an adhesive bond is created with the respective carriers 27.
The embossing station 40 and the assembly station 43 can form part of a common device or machine. The manufacturing process can be carried out in an automated manner. The dent spacing x is preferably adjusted in the assembly station 43 by a highly precise machine axis.
The invention refers to a reed 15 and a method for producing the same. The reed 15 comprises a plurality of dents 16 that are arranged in a width direction B at a dent spacing x respectively, thereby forming interspaces 25. Each dent 16 has two opposite end sections 19 at which it is connected with a carrier 27 and with the directly adjacent dent or dents 16 by means of an adhesive bond respectively. In at least one or in both end sections 19 the dent 16 has a plurality of spacer studs 30 that are preferably created by embossing. The spacer studs 30 form a depression on the one first side S1 and on the opposite second side S2 a projection with a stud outer surface F. The sum of all stud outer surfaces F of the spacer studs 30 of one single end section 19 of a dent 16 has a percentage of at most 15% or at most 10% or at most 8% of the total end section area on this second side S2.
| Number | Date | Country | Kind |
|---|---|---|---|
| 17180271 | Jul 2017 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2018/068369 | 7/6/2018 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2019/008138 | 1/10/2019 | WO | A |
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|---|---|---|---|
| 2147258 | Kaufmann | Feb 1939 | A |
| 2152430 | Hassold | Mar 1939 | A |
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| 3965940 | Marty | Jun 1976 | A |
| 4071052 | Vasek | Jan 1978 | A |
| 4290458 | Steiner | Sep 1981 | A |
| 4328842 | Scheffel | May 1982 | A |
| 4529014 | Rast | Jul 1985 | A |
| 4694867 | Gendelman | Sep 1987 | A |
| 4844131 | Anderson | Jul 1989 | A |
| 4887650 | McGinley | Dec 1989 | A |
| 5029617 | Anderson | Jul 1991 | A |
| 5046533 | Corain | Sep 1991 | A |
| 5158116 | Kazuo | Oct 1992 | A |
| 5289852 | Migliorini | Mar 1994 | A |
| 5421373 | Hacker | Jun 1995 | A |
| 5465762 | Farley | Nov 1995 | A |
| 5570725 | Musha | Nov 1996 | A |
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| 6039087 | Thompson, III | Mar 2000 | A |
| 6575201 | Buesgen | Jun 2003 | B2 |
| 7467646 | Mettler | Dec 2008 | B2 |
| 9145625 | Zhang | Sep 2015 | B2 |
| 9200385 | Dambrine | Dec 2015 | B2 |
| 10626527 | Bruske | Apr 2020 | B2 |
| 20150114511 | Dambrine | Apr 2015 | A1 |
| 20180057980 | Bruske | Mar 2018 | A1 |
| Number | Date | Country |
|---|---|---|
| 1535830 | Jul 1970 | DE |
| 2508575 | Sep 1975 | DE |
| 0943712 | Sep 1999 | EP |
| 3067451 | Sep 2016 | EP |
| 1146831 | Nov 1957 | FR |
| 1245872 | Sep 1971 | GB |
| Entry |
|---|
| Extended European Search Report dated Jan. 9, 2018, in corresponding European Application No. 17180271.3 (8 pages). |
| International Search Report dated Oct. 2, 2018 and Written Opinion dated Sep. 24, 2018, in corresponding International Application No. PCT/EP2018/068369, with machine English translation (15 pages). |
| International Report on Patentability dated Jun. 24, 2019, in corresponding International Application No. PCT/EP2018/068369, with machine English translation (25 pages). |
| Number | Date | Country | |
|---|---|---|---|
| 20200299874 A1 | Sep 2020 | US |
